Login In
2024 Volume 35 Issue 5
2024, 35(5): 108240
doi: 10.1016/j.cclet.2023.108240
Abstract:
Commercial V2O5-based catalysts have been successfully applied in NH3 selective catalytic reduction (NH3-SCR) of NOx from power stations, but their poor alkali-resistance restrains the wider application in nonelectrical industries. In this study, NOx reduction against alkali poisoning over V2O5/TiO2 is greatly improved via Ce(SO4)2 modification. It has been originally demonstrated that Ce4+–SO42− pair sites play crucial roles in improving NOx reduction against alkali poisoning over V2O5/TiO2 catalysts. The strong interaction between V species and Ce sites of Ce4+–SO42− pairs triggers the reaction between NH4+species and gaseous NO via Eley-Rideal (E-R) reaction pathway. After K-poisoning, the SO42− sites of Ce4+–SO42− pairs as protective sites strongly bond with K and thus maintain the high reaction efficiency via the E-R reaction pathway. This work demonstrates an effective strategy to enhance NOx reduction against alkali poisoning over catalysts via constructing Ce4+–SO42− pair sites, contributing to developing alkali-resistant SCR catalysts for practical application in nonelectrical industries.
Commercial V2O5-based catalysts have been successfully applied in NH3 selective catalytic reduction (NH3-SCR) of NOx from power stations, but their poor alkali-resistance restrains the wider application in nonelectrical industries. In this study, NOx reduction against alkali poisoning over V2O5/TiO2 is greatly improved via Ce(SO4)2 modification. It has been originally demonstrated that Ce4+–SO42− pair sites play crucial roles in improving NOx reduction against alkali poisoning over V2O5/TiO2 catalysts. The strong interaction between V species and Ce sites of Ce4+–SO42− pairs triggers the reaction between NH4+species and gaseous NO via Eley-Rideal (E-R) reaction pathway. After K-poisoning, the SO42− sites of Ce4+–SO42− pairs as protective sites strongly bond with K and thus maintain the high reaction efficiency via the E-R reaction pathway. This work demonstrates an effective strategy to enhance NOx reduction against alkali poisoning over catalysts via constructing Ce4+–SO42− pair sites, contributing to developing alkali-resistant SCR catalysts for practical application in nonelectrical industries.
2024, 35(5): 108473
doi: 10.1016/j.cclet.2023.108473
Abstract:
The detrimental "shuttle effect" of lithium polysulfides (LiPSs) together with sluggish multi-order reaction kinetics are the main drawbacks hindering lithium-sulfur (Li-S) batteries from commercial success. Here, we first propose the implementability of layered rare-earth hydroxides (LREHs) in Li-S batteries to optimize electrochemical performance. In this work, a two-dimensional (2D) rare-earth-based composite constructed by the layered gadolinium hydroxy chloride [Gd2(OH)5(H2O)]Cl nanoplates (LGdH NPs) and graphene oxide (GO) was designed as a sulfur immobilizer for Li-S batteries. Combining the experimental results and density functional theory (DFT) calculations, it is revealed that the LGdH@GO composite not only provides a strong anchoring of the intermediates during cycling, but also acts as an effective catalyst to accelerate the liquid-solid conversion of polysulfides. The Li-S batteries assembled by LGdH@GO modified separators delivered a superior rate performance with a specific capacity of 605.34 mAh/g at 5 C, as well as excellent cycle stability with a decay rate of 0.087% over 500 cycles at 2 C. This study provided a deep understanding of the mechanism to suppress the "shuttle effect" by the LREHs, and a guide to design effective functional interlayers for high-performance Li-S batteries with excellent electrocatalytic activity.
The detrimental "shuttle effect" of lithium polysulfides (LiPSs) together with sluggish multi-order reaction kinetics are the main drawbacks hindering lithium-sulfur (Li-S) batteries from commercial success. Here, we first propose the implementability of layered rare-earth hydroxides (LREHs) in Li-S batteries to optimize electrochemical performance. In this work, a two-dimensional (2D) rare-earth-based composite constructed by the layered gadolinium hydroxy chloride [Gd2(OH)5(H2O)]Cl nanoplates (LGdH NPs) and graphene oxide (GO) was designed as a sulfur immobilizer for Li-S batteries. Combining the experimental results and density functional theory (DFT) calculations, it is revealed that the LGdH@GO composite not only provides a strong anchoring of the intermediates during cycling, but also acts as an effective catalyst to accelerate the liquid-solid conversion of polysulfides. The Li-S batteries assembled by LGdH@GO modified separators delivered a superior rate performance with a specific capacity of 605.34 mAh/g at 5 C, as well as excellent cycle stability with a decay rate of 0.087% over 500 cycles at 2 C. This study provided a deep understanding of the mechanism to suppress the "shuttle effect" by the LREHs, and a guide to design effective functional interlayers for high-performance Li-S batteries with excellent electrocatalytic activity.
2024, 35(5): 108603
doi: 10.1016/j.cclet.2023.108603
Abstract:
Copper phthalocyanine (CuPc) is adopted as an electrolyte additive to stabilize lithium anode for lithium-sulfur (Li-S) batteries. CuPc with a planar molecular structure and lithiophilic N-containing group, is likely to be adsorbed on the surface of Li anode to form a coating layer, which can restrict the direct contact between Li anode and solvents, and guide the uniform deposition of Li+ ions. The Li||Li symmetric cells demonstrate a stable cycle performance, and Li||Cu cells show high Coulombic efficiencies. In Li-S batteries, the formed stable solid-electrolyte interface (SEI) film containing copper sulfides can protect Li anode from the polysulfide corrosion and side reactions with the electrolyte, leading to the compact and smooth surface morphology of Li anode. Therefore, the Li-S batteries with CuPc additive deliver much higher capacity, better cycle performance and rate capability as compared to the one without CuPc additive.
Copper phthalocyanine (CuPc) is adopted as an electrolyte additive to stabilize lithium anode for lithium-sulfur (Li-S) batteries. CuPc with a planar molecular structure and lithiophilic N-containing group, is likely to be adsorbed on the surface of Li anode to form a coating layer, which can restrict the direct contact between Li anode and solvents, and guide the uniform deposition of Li+ ions. The Li||Li symmetric cells demonstrate a stable cycle performance, and Li||Cu cells show high Coulombic efficiencies. In Li-S batteries, the formed stable solid-electrolyte interface (SEI) film containing copper sulfides can protect Li anode from the polysulfide corrosion and side reactions with the electrolyte, leading to the compact and smooth surface morphology of Li anode. Therefore, the Li-S batteries with CuPc additive deliver much higher capacity, better cycle performance and rate capability as compared to the one without CuPc additive.
2024, 35(5): 108605
doi: 10.1016/j.cclet.2023.108605
Abstract:
Due to its high operational voltage and energy density, P2-type Na0.67Ni0.3Mn0.7O2 has become a leading cathode material for sodium-ion batteries (SIBs), which is an ideal option for large-scale energy storage. However, the practical application of P2-type Na0.67Ni0.3Mn0.7O2 is limited by the capacity constraints and unwanted phase transitions, presenting significant challenges to the widespread application of SIBs. To address these challenges and optimize the electrochemical properties of the P2 phase cathode material, this study proposes a Cu and Zn co-doped strategy to improve the electrochemical performance. The incorporation of Cu/Zn can stabilize the P2-phase structure against P2-O2 phase transitions, thus enhancing its electrochemical properties. The as-obtained P2-type Na0.67[Ni0.3Mn0.58Cu0.09Zn0.03]O2 cathode material shows an impressive cycling stability, maintaining 80% capacity retention after 1000 cycles at 2 C. The cyclic voltammetry (CV) tests show that the Cu2+/Cu3+ redox reaction is also involved in charge compensation during the charge/discharge process.
Due to its high operational voltage and energy density, P2-type Na0.67Ni0.3Mn0.7O2 has become a leading cathode material for sodium-ion batteries (SIBs), which is an ideal option for large-scale energy storage. However, the practical application of P2-type Na0.67Ni0.3Mn0.7O2 is limited by the capacity constraints and unwanted phase transitions, presenting significant challenges to the widespread application of SIBs. To address these challenges and optimize the electrochemical properties of the P2 phase cathode material, this study proposes a Cu and Zn co-doped strategy to improve the electrochemical performance. The incorporation of Cu/Zn can stabilize the P2-phase structure against P2-O2 phase transitions, thus enhancing its electrochemical properties. The as-obtained P2-type Na0.67[Ni0.3Mn0.58Cu0.09Zn0.03]O2 cathode material shows an impressive cycling stability, maintaining 80% capacity retention after 1000 cycles at 2 C. The cyclic voltammetry (CV) tests show that the Cu2+/Cu3+ redox reaction is also involved in charge compensation during the charge/discharge process.
2024, 35(5): 108606
doi: 10.1016/j.cclet.2023.108606
Abstract:
O3-type layered oxide cathodes have been widely investigated due to their high reversible capacities and sufficient Na+ reservoirs. However, such materials usually suffer from complex multistep phase transitions along with drastic volume changes, leading to the unsatisfied cycle performance. Herein, we report a Mg/Ti co-doped O3-type NaNi0.5Mn0.5O2, which can effectively suppress the complex multistep phase transition and realize a solid-solution reaction within a wide voltage range. It is confirmed that, the Mg/Ti co-doping is beneficial to enhance the structural stability and integrity by absorbing micro-strain and distortions. Thus, the as obtained sample delivers an outstanding cyclic performance (82.3% after 200 cycles at 1 C) in the voltage range of 2.0–4.0 V, and a high discharge capacity of 86.6 mAh/g after 100 cycles within the wide voltage range (2.0–4.5 V), which outperform the existing literatures. This co-doping strategy offers new insights into high performance O3-type cathode for sodium ion batteries.
O3-type layered oxide cathodes have been widely investigated due to their high reversible capacities and sufficient Na+ reservoirs. However, such materials usually suffer from complex multistep phase transitions along with drastic volume changes, leading to the unsatisfied cycle performance. Herein, we report a Mg/Ti co-doped O3-type NaNi0.5Mn0.5O2, which can effectively suppress the complex multistep phase transition and realize a solid-solution reaction within a wide voltage range. It is confirmed that, the Mg/Ti co-doping is beneficial to enhance the structural stability and integrity by absorbing micro-strain and distortions. Thus, the as obtained sample delivers an outstanding cyclic performance (82.3% after 200 cycles at 1 C) in the voltage range of 2.0–4.0 V, and a high discharge capacity of 86.6 mAh/g after 100 cycles within the wide voltage range (2.0–4.5 V), which outperform the existing literatures. This co-doping strategy offers new insights into high performance O3-type cathode for sodium ion batteries.
2024, 35(5): 108622
doi: 10.1016/j.cclet.2023.108622
Abstract:
Sulfurized polyacrylonitrile (SPAN) is proposed as a promising cathode material for lithium sulfur batteries. However, the continuous side reactions at the electrolyte-electrode interfaces as well as the slow redox kinetics of SPAN cathode deteriorate the electrochemical performance. In this study, an electrolyte with dual-additives comprising 2-fluoropyridine (2-FP) and lithium difluorobis (oxalato) phosphate (LiDFBOP) was used to improve the performance of Li||SPAN cells. 2-FP has a lower lowest occupied molecular orbital energy than that of the solvents in the electrolyte, leading to its prior reduction. A LiF-rich film can be formed on the electrode, effectively improving the stability of the electrolyte-electrode interfaces and prolonging the life. Simultaneously, LiDFBOP could form an electrolyte-electrode interface film containing a large amount of LixPOyFz species, compensating for the kinetic deterioration caused by the lower ionic conductive of LiF formed at the electrolyte-electrode interface. Hence, an electrode-interface film with good chemical stability and high Li+ transport was established by LiF and LixPOyFz-rich species. The Li||SPAN cell with the electrolyte containing dual-additives demonstrates an excellent capacity retention of 97.5% after 200 cycles at 1.0 C, 25 ℃, comparing to 56.2% capacity retention without additives. Moreover, the rate capacities of cells with dual-additives can reach 1128.1 mAh/g at 5 C, comparing to only 813.5 mAh/g using electrolyte without additives. Our results shown that the dual-additives in electrolyte provide a promising strategy for practical application of lithium sulfur batteries with SPAN cathodes.
Sulfurized polyacrylonitrile (SPAN) is proposed as a promising cathode material for lithium sulfur batteries. However, the continuous side reactions at the electrolyte-electrode interfaces as well as the slow redox kinetics of SPAN cathode deteriorate the electrochemical performance. In this study, an electrolyte with dual-additives comprising 2-fluoropyridine (2-FP) and lithium difluorobis (oxalato) phosphate (LiDFBOP) was used to improve the performance of Li||SPAN cells. 2-FP has a lower lowest occupied molecular orbital energy than that of the solvents in the electrolyte, leading to its prior reduction. A LiF-rich film can be formed on the electrode, effectively improving the stability of the electrolyte-electrode interfaces and prolonging the life. Simultaneously, LiDFBOP could form an electrolyte-electrode interface film containing a large amount of LixPOyFz species, compensating for the kinetic deterioration caused by the lower ionic conductive of LiF formed at the electrolyte-electrode interface. Hence, an electrode-interface film with good chemical stability and high Li+ transport was established by LiF and LixPOyFz-rich species. The Li||SPAN cell with the electrolyte containing dual-additives demonstrates an excellent capacity retention of 97.5% after 200 cycles at 1.0 C, 25 ℃, comparing to 56.2% capacity retention without additives. Moreover, the rate capacities of cells with dual-additives can reach 1128.1 mAh/g at 5 C, comparing to only 813.5 mAh/g using electrolyte without additives. Our results shown that the dual-additives in electrolyte provide a promising strategy for practical application of lithium sulfur batteries with SPAN cathodes.
2024, 35(5): 108623
doi: 10.1016/j.cclet.2023.108623
Abstract:
In persulfate-based advanced oxidation process (PS-AOPs), fixing nanosized metal oxide on processable substrates is highly desirable to avoid the aggregation and loss of nanocatalysts during the practical application. However, it is still challenging to develop a versatile strategy for the deposition of metal oxide nanocatalysts on various substrates with different physicochemical properties. Herein, polyphenols are utilized as a "molecular glue" and reductant to mediate the interfacial deposition of MnO2 nanocatalysts on different substrates. MnO2 nanocatalysts were in-situ grown on macroscope mineral substrates (e.g., airstone) via an interfacial redox strategy between tannic acid (TA) and oxidized KMnO4, and then employed as a fixed catalyst of peroxymonosulfate (PMS) activation for treating pharmaceutical and personal care products (PPCPs) in water. The fixed MnO2 exhibited superior catalytic performance toward different PPCPS via a singlet oxygen (1O2)-dominated nonradical oxidation pathway. PPCPs in the secondary effluent of wastewater treatment plants could be effectively removed by a fixed-bed column of the fixed MnO2 with long term stability. Redox cycle of Mn4+/Mn3+ and surface hydroxyl group of the fixed MnO2 was proved to be responsible for the activation of PMS. This work provides a new avenue for developing fixed metal oxides for sustainable water treatment.
In persulfate-based advanced oxidation process (PS-AOPs), fixing nanosized metal oxide on processable substrates is highly desirable to avoid the aggregation and loss of nanocatalysts during the practical application. However, it is still challenging to develop a versatile strategy for the deposition of metal oxide nanocatalysts on various substrates with different physicochemical properties. Herein, polyphenols are utilized as a "molecular glue" and reductant to mediate the interfacial deposition of MnO2 nanocatalysts on different substrates. MnO2 nanocatalysts were in-situ grown on macroscope mineral substrates (e.g., airstone) via an interfacial redox strategy between tannic acid (TA) and oxidized KMnO4, and then employed as a fixed catalyst of peroxymonosulfate (PMS) activation for treating pharmaceutical and personal care products (PPCPs) in water. The fixed MnO2 exhibited superior catalytic performance toward different PPCPS via a singlet oxygen (1O2)-dominated nonradical oxidation pathway. PPCPs in the secondary effluent of wastewater treatment plants could be effectively removed by a fixed-bed column of the fixed MnO2 with long term stability. Redox cycle of Mn4+/Mn3+ and surface hydroxyl group of the fixed MnO2 was proved to be responsible for the activation of PMS. This work provides a new avenue for developing fixed metal oxides for sustainable water treatment.
2024, 35(5): 108624
doi: 10.1016/j.cclet.2023.108624
Abstract:
The development of highly efficient catalysts in the cathodes of rechargeable Li-O2 batteries is a considerable challenge. To enhance the electrochemical performance of the Li-O2 battery, it is essential to choose a suitable catalyst material. Copper selenide (CuSe) is considered as a more promising cathode catalyst material for Li-O2 battery due to its better conductivity and rich electrochemical active sites. However, its electrochemical reaction and fundamental catalytic mechanism remain unclear till now. Herein, in-situ environmental transmission electron microscopy technique was used to study the catalysis mechanism of the CuSe nanosheets in Li-O2 batteries during discharge and charge processes. It is found that Li2O was formed and decomposed around the ultrafine-grained Cu during the discharge and charge processes, respectively, demonstrating excellent cycling. This indicate that the freshly formed ultrafine-grained Cu in the conversion reaction catalyzed the latter four-electron-transfer oxygen reduction reaction, leading to the formation of Li2O. Our study provides important understanding of the electrochemistry of the Li-O2 nanobatteries, which will aid the development of high-performance Li-O2 batteries for energy storage applications.
The development of highly efficient catalysts in the cathodes of rechargeable Li-O2 batteries is a considerable challenge. To enhance the electrochemical performance of the Li-O2 battery, it is essential to choose a suitable catalyst material. Copper selenide (CuSe) is considered as a more promising cathode catalyst material for Li-O2 battery due to its better conductivity and rich electrochemical active sites. However, its electrochemical reaction and fundamental catalytic mechanism remain unclear till now. Herein, in-situ environmental transmission electron microscopy technique was used to study the catalysis mechanism of the CuSe nanosheets in Li-O2 batteries during discharge and charge processes. It is found that Li2O was formed and decomposed around the ultrafine-grained Cu during the discharge and charge processes, respectively, demonstrating excellent cycling. This indicate that the freshly formed ultrafine-grained Cu in the conversion reaction catalyzed the latter four-electron-transfer oxygen reduction reaction, leading to the formation of Li2O. Our study provides important understanding of the electrochemistry of the Li-O2 nanobatteries, which will aid the development of high-performance Li-O2 batteries for energy storage applications.
2024, 35(5): 108638
doi: 10.1016/j.cclet.2023.108638
Abstract:
Ultra-high nickel material is considered to be a promising cathode material. However, with the increase of nickel content, the interfacial side reactions between the cathode and electrolyte become increasingly serious. Herein, an atomically controllable ionic conductor Li3PO4 (LPO) coating is deposited on the LiNi0.90Co0.06Mn0.04O2 (NCM9064) based electrode by the atomic layer deposition method. The results shows that the LPO coating is uniformly and densely covered on the surface of secondary particles of NCM9064, helping to prevent the direct contact between the electrolyte and cathode during the charging-discharging process. In addition, the coating layer is electrochemically stable. As a result, the interfacial side reactions during the long cycle are effectively suppressed, and the solid electrolyte interphase layer at the interface is stabilized. The electrode with 20 layers of LPO deposition (ALD-LPO-20) exhibits an excellent capacity retention of 81% after 200 cycles in 2.8-4.3 V at 25 ℃, which is 18% higher than the unmodified material (ALD-LPO-0). Besides, the moderate LPO coating improves the rate capability and high temperature cycling performance of NCM9064. This study provides a method for the modification of ultra-high nickel cathode materials and corresponding electrodes.
Ultra-high nickel material is considered to be a promising cathode material. However, with the increase of nickel content, the interfacial side reactions between the cathode and electrolyte become increasingly serious. Herein, an atomically controllable ionic conductor Li3PO4 (LPO) coating is deposited on the LiNi0.90Co0.06Mn0.04O2 (NCM9064) based electrode by the atomic layer deposition method. The results shows that the LPO coating is uniformly and densely covered on the surface of secondary particles of NCM9064, helping to prevent the direct contact between the electrolyte and cathode during the charging-discharging process. In addition, the coating layer is electrochemically stable. As a result, the interfacial side reactions during the long cycle are effectively suppressed, and the solid electrolyte interphase layer at the interface is stabilized. The electrode with 20 layers of LPO deposition (ALD-LPO-20) exhibits an excellent capacity retention of 81% after 200 cycles in 2.8-4.3 V at 25 ℃, which is 18% higher than the unmodified material (ALD-LPO-0). Besides, the moderate LPO coating improves the rate capability and high temperature cycling performance of NCM9064. This study provides a method for the modification of ultra-high nickel cathode materials and corresponding electrodes.
2024, 35(5): 108641
doi: 10.1016/j.cclet.2023.108641
Abstract:
A new bismuth-based halide double perovskite Cs2KBiCl6 was isolated successfully through solid-state reactions and investigated using X-ray and neutron diffraction. Rather than an ordered structure, the crystal structure consists of shifted Cs, K, Bi, and Cl sites from the ideal positions with fractional occupancy in compensation, leading to variable local coordination of Cs+ ions, as revealed by 133Cs solid-state nuclear magnetic resonance spectroscopy. Cs2KBiCl6 displays volume hysteresis at 5–298 K range upon heating and cooling. The Cs2KBiCl6 has a direct bandgap of 3.35(2) eV and red-shift luminescence of around 600 nm upon Mn doping compared with the Na analogue. The stabilization of disordered structure in Cs2KBiCl6 is related to two factors including the large-sized K+ cation which prefers to coordinate with more than six Cl−, and the Bi3+ with 6s2 lone pair which has a preference for a local asymmetric environment. These findings could have general application and help to understand the structure and property of halide perovskites.
A new bismuth-based halide double perovskite Cs2KBiCl6 was isolated successfully through solid-state reactions and investigated using X-ray and neutron diffraction. Rather than an ordered structure, the crystal structure consists of shifted Cs, K, Bi, and Cl sites from the ideal positions with fractional occupancy in compensation, leading to variable local coordination of Cs+ ions, as revealed by 133Cs solid-state nuclear magnetic resonance spectroscopy. Cs2KBiCl6 displays volume hysteresis at 5–298 K range upon heating and cooling. The Cs2KBiCl6 has a direct bandgap of 3.35(2) eV and red-shift luminescence of around 600 nm upon Mn doping compared with the Na analogue. The stabilization of disordered structure in Cs2KBiCl6 is related to two factors including the large-sized K+ cation which prefers to coordinate with more than six Cl−, and the Bi3+ with 6s2 lone pair which has a preference for a local asymmetric environment. These findings could have general application and help to understand the structure and property of halide perovskites.
2024, 35(5): 108654
doi: 10.1016/j.cclet.2023.108654
Abstract:
Electrocatalytic nitrogen reduction reaction (NRR) is considered as an attractive approach for ammonia synthesis under mild conditions. A bottleneck of NRR is the exploration of efficient catalysts for accelerating reaction kinetics, among which heterogeneous structures possessing distinct atomic arrangement could modify electronic structure, and therefore altering their NRR activity. Here, we report a facile strategy for fabricating hetero-phase metal oxides derived from metal organic framework that are further integrated with Au nanoparticles as NRR catalysts. The phase composition of zirconia can be easily adjusted by simply changing the reaction temperature, where the monoclinic and tetragonal phases with the roughly close proportions have a distinct interface, leading to a strong interaction between Au and ZrO2. The enhanced interaction renders Au to be more electropositive and facilitates stronger binding to N2. As a result, a remarkable ammonia yield of 22.32 µg h−1 mgcat.−1 and a Faradaic efficiency of 31.92% can be achieved at low overpotential. This work is expected to pave the way for the design of heterogeneous structures and the exploration of hetero-phase nanostructures in boosting the electrocatalytic NRR.
Electrocatalytic nitrogen reduction reaction (NRR) is considered as an attractive approach for ammonia synthesis under mild conditions. A bottleneck of NRR is the exploration of efficient catalysts for accelerating reaction kinetics, among which heterogeneous structures possessing distinct atomic arrangement could modify electronic structure, and therefore altering their NRR activity. Here, we report a facile strategy for fabricating hetero-phase metal oxides derived from metal organic framework that are further integrated with Au nanoparticles as NRR catalysts. The phase composition of zirconia can be easily adjusted by simply changing the reaction temperature, where the monoclinic and tetragonal phases with the roughly close proportions have a distinct interface, leading to a strong interaction between Au and ZrO2. The enhanced interaction renders Au to be more electropositive and facilitates stronger binding to N2. As a result, a remarkable ammonia yield of 22.32 µg h−1 mgcat.−1 and a Faradaic efficiency of 31.92% can be achieved at low overpotential. This work is expected to pave the way for the design of heterogeneous structures and the exploration of hetero-phase nanostructures in boosting the electrocatalytic NRR.
2024, 35(5): 108655
doi: 10.1016/j.cclet.2023.108655
Abstract:
Single crystallization is an important strategy to resolve intergranular cracks and unnecessary side reactions with electrolytes in layered transition metal oxide cathodes LiNi0.8Mn0.1Co0.1O2 (NMC811). Due to the limitations of high-temperature sintering and multi-step calcination, single crystal NMC811 generally shows irregular particles with a size of 2–3 µm. However, the prolonged Li-ion diffusion pathway and the stress generated by the uneven de-/intercalation sluggish Li-ion diffusion kinetics, what is more, cause structural damage such as intragranular cracks. A slow Li extraction rate or particle size reduction will ameliorate the structural damage and improve the cycling stability. As the most promising cathodes for next-generation power batteries, NMC811 required fast charge performance and cycle stability. Particle size reduction appears to be the displacement option. Nanonization is an effective strategy to mitigate intragranular cracks of single crystal NMC811. However, the serious aggregation and increased specific surface area become new challenges. In this article, we synthesized monodisperse nanoscale single crystal NMC811 by molten salt method and modified the surface by LiNbO3 coating. The electrochemical performance shows that nanoscale single crystal NMC811 has faster kinetic and higher capacity retention, so the strategy of combining nanonization and surface coating is an alternative way to prepare high specific capacity and cycle stable single crystal NMC811.
Single crystallization is an important strategy to resolve intergranular cracks and unnecessary side reactions with electrolytes in layered transition metal oxide cathodes LiNi0.8Mn0.1Co0.1O2 (NMC811). Due to the limitations of high-temperature sintering and multi-step calcination, single crystal NMC811 generally shows irregular particles with a size of 2–3 µm. However, the prolonged Li-ion diffusion pathway and the stress generated by the uneven de-/intercalation sluggish Li-ion diffusion kinetics, what is more, cause structural damage such as intragranular cracks. A slow Li extraction rate or particle size reduction will ameliorate the structural damage and improve the cycling stability. As the most promising cathodes for next-generation power batteries, NMC811 required fast charge performance and cycle stability. Particle size reduction appears to be the displacement option. Nanonization is an effective strategy to mitigate intragranular cracks of single crystal NMC811. However, the serious aggregation and increased specific surface area become new challenges. In this article, we synthesized monodisperse nanoscale single crystal NMC811 by molten salt method and modified the surface by LiNbO3 coating. The electrochemical performance shows that nanoscale single crystal NMC811 has faster kinetic and higher capacity retention, so the strategy of combining nanonization and surface coating is an alternative way to prepare high specific capacity and cycle stable single crystal NMC811.
2024, 35(5): 108661
doi: 10.1016/j.cclet.2023.108661
Abstract:
Photosensitization related to energy/electron transfer process is of great importance to natural photosynthesis. Herein, we proposed a promising strategy to improve the sensitizing ability of the typical photoactive MOFs (UiO-Ir) by engineering its metal coordination center with NBI (1, 8-naphthalenebenzimidizole) chromophore. The resulting MOFs (UiO-Ir-NBI) exhibited a strong sensitizing ability for significantly boosting photosynthesis. Impressively, the catalytic yield of 2-chloroethyl ethyl sulfoxide with UiO-Ir-NBI can reach 99%, over 6 times higher than that with UiO-Ir (16.4%). Moreover, UiO-Ir-NBI exhibited an excellent catalytic stability and a broad substrate tolerance, highlighting its great application prospect. Systematic investigations revealed that the strong visible light absorption, long excited state lifetime and efficient electron-hole separation of UiO-Ir-NBI greatly contributed to harvesting visible light and facilitating interface electron/energy transfer for efficient solar energy utilization. This work provides a new horizon to boost photosythesis of MOFs by engineering their metal sensitizing centers at a molecular level.
Photosensitization related to energy/electron transfer process is of great importance to natural photosynthesis. Herein, we proposed a promising strategy to improve the sensitizing ability of the typical photoactive MOFs (UiO-Ir) by engineering its metal coordination center with NBI (1, 8-naphthalenebenzimidizole) chromophore. The resulting MOFs (UiO-Ir-NBI) exhibited a strong sensitizing ability for significantly boosting photosynthesis. Impressively, the catalytic yield of 2-chloroethyl ethyl sulfoxide with UiO-Ir-NBI can reach 99%, over 6 times higher than that with UiO-Ir (16.4%). Moreover, UiO-Ir-NBI exhibited an excellent catalytic stability and a broad substrate tolerance, highlighting its great application prospect. Systematic investigations revealed that the strong visible light absorption, long excited state lifetime and efficient electron-hole separation of UiO-Ir-NBI greatly contributed to harvesting visible light and facilitating interface electron/energy transfer for efficient solar energy utilization. This work provides a new horizon to boost photosythesis of MOFs by engineering their metal sensitizing centers at a molecular level.
2024, 35(5): 108692
doi: 10.1016/j.cclet.2023.108692
Abstract:
Conversion of CO2 into high-value products using electrochemical CO2 reduction (ECR) technology is an effective way to alleviate global warming and reach carbon neutrality. The oxygen vacancies in heterogenous catalysis are generally considered as a powerful method to enhance the performance of ECR by promoting CO2 adsorption and activation. However, the extent of defects in oxygen vacancies-activity relation has rarely been studied. Herein, we prepared Cu–Cd bimetallic catalysts with adjustable oxygen defect degree by controlling the amount of cadmium addition. Fourier transform infrared spectroscopy characterization results reveal that the formation of oxygen vacancies is attributed to the asymmetric stretching of Cu–O by the addition of cadmium. Electrochemical results show that the oxygen defect degree can modulate the selectivity of ECR products. A low degree of oxygen defects (CuO) is generally associated with lower product Faraday efficiency (FEC2/FEC1 ≈ 114%), but overabundant oxygen vacancies (CuO2.625–CdO0.375) are not entirely favorable to improving ECR activity (FEC2/FEC1 ≈ 125%) and single selectivity, while an appropriate degree of oxygen vacancies (CuO2.75–CdO0.25) can facilitate the ECR process toward single product selective production (FEC2/FEC1 ≈ 296%). The theoretical calculation showed that the O vacancy formed on CuO and the interface between CdO and CuO were conducive to enhancing the formation of *COOH intermediate and promoting the generation of ethylene products. This study provides a new approach and insight into the selective production of single products for future industrial applications of ECR.
Conversion of CO2 into high-value products using electrochemical CO2 reduction (ECR) technology is an effective way to alleviate global warming and reach carbon neutrality. The oxygen vacancies in heterogenous catalysis are generally considered as a powerful method to enhance the performance of ECR by promoting CO2 adsorption and activation. However, the extent of defects in oxygen vacancies-activity relation has rarely been studied. Herein, we prepared Cu–Cd bimetallic catalysts with adjustable oxygen defect degree by controlling the amount of cadmium addition. Fourier transform infrared spectroscopy characterization results reveal that the formation of oxygen vacancies is attributed to the asymmetric stretching of Cu–O by the addition of cadmium. Electrochemical results show that the oxygen defect degree can modulate the selectivity of ECR products. A low degree of oxygen defects (CuO) is generally associated with lower product Faraday efficiency (FEC2/FEC1 ≈ 114%), but overabundant oxygen vacancies (CuO2.625–CdO0.375) are not entirely favorable to improving ECR activity (FEC2/FEC1 ≈ 125%) and single selectivity, while an appropriate degree of oxygen vacancies (CuO2.75–CdO0.25) can facilitate the ECR process toward single product selective production (FEC2/FEC1 ≈ 296%). The theoretical calculation showed that the O vacancy formed on CuO and the interface between CdO and CuO were conducive to enhancing the formation of *COOH intermediate and promoting the generation of ethylene products. This study provides a new approach and insight into the selective production of single products for future industrial applications of ECR.
2024, 35(5): 108693
doi: 10.1016/j.cclet.2023.108693
Abstract:
Increasing use of silver in various fields has caused Ag+ pollution in water environment, taking great threats to people's health. As a consequence, establishing rapid and reliable methods for sensitive determination of Ag+ is of great significance. Fluorescent (FL) sensors based on carbon dots (CDs), an excellent carbonaceous nanomaterial with strong and stable fluorescence, have absorbed extensive attentions in analysis of pollutants due to its advantages of carbon sources being readily available, low cost, easy operation and fast response. Moreover, ion-imprinting is a better way to increase the selectivity of the proposed method. Present work described an effective method for the sensitive measurement of silver ion in water samples in combination with magnetic ion-imprinted solid phase extraction and CDs based fluorescent sensor, which took full advantages of easy separation and high enrichment of magnetic solid phase extraction, high selectivity of ion-imprinting technology, and sensitivity and rapid response of fluorescent sensor from CDs. Sulfur-doped CDs derived from dithizone and magnetic ion-imprinted nanomaterial were prepared, and characterized with Fourier transform infrared spectroscopy and transmission electron microscope, etc. Magnetic Ag+ imprinted nanomaterial based solid phase extraction was employed for separating and enriching Ag+ from water samples. The significant parameters were optimized in detail. Under the optimal conditions, the proposed method provided good linearity in the range of 0.01–0.4 µmol/L and low detection limit of 3 nmol/L. The reliability of the proposed method was validated with real water samples, and the results demonstrated that the proposed method was simple, robust, selective and sensitive detection tool for Ag+ in real water samples.
Increasing use of silver in various fields has caused Ag+ pollution in water environment, taking great threats to people's health. As a consequence, establishing rapid and reliable methods for sensitive determination of Ag+ is of great significance. Fluorescent (FL) sensors based on carbon dots (CDs), an excellent carbonaceous nanomaterial with strong and stable fluorescence, have absorbed extensive attentions in analysis of pollutants due to its advantages of carbon sources being readily available, low cost, easy operation and fast response. Moreover, ion-imprinting is a better way to increase the selectivity of the proposed method. Present work described an effective method for the sensitive measurement of silver ion in water samples in combination with magnetic ion-imprinted solid phase extraction and CDs based fluorescent sensor, which took full advantages of easy separation and high enrichment of magnetic solid phase extraction, high selectivity of ion-imprinting technology, and sensitivity and rapid response of fluorescent sensor from CDs. Sulfur-doped CDs derived from dithizone and magnetic ion-imprinted nanomaterial were prepared, and characterized with Fourier transform infrared spectroscopy and transmission electron microscope, etc. Magnetic Ag+ imprinted nanomaterial based solid phase extraction was employed for separating and enriching Ag+ from water samples. The significant parameters were optimized in detail. Under the optimal conditions, the proposed method provided good linearity in the range of 0.01–0.4 µmol/L and low detection limit of 3 nmol/L. The reliability of the proposed method was validated with real water samples, and the results demonstrated that the proposed method was simple, robust, selective and sensitive detection tool for Ag+ in real water samples.
2024, 35(5): 108696
doi: 10.1016/j.cclet.2023.108696
Abstract:
Ferroelastic hybrid perovskite materials have been revealed the significance in the applications of switches, sensors, actuators, etc. However, it remains a challenge to design high-temperature ferroelastic to meet the requirements for the practical applications. Herein, we reported an one-dimensional organic-inorganic hybrid perovskites (OIHP) (3-methylpyrazolium)CdCl3 (3-MBCC), which possesses a mmmF2/m ferroelastic phase transition at 263 K. Moreover, utilizing crystal engineering, we replace –CH3 with –NH2 and –H, which increases the intermolecular force between organic cations and inorganic frameworks. The phase transition temperature of (3-aminopyrazolium)CdCl3 (3-ABCC), and (pyrazolium)CdCl3 (BCC) increased by 73 K and 10 K, respectively. Particularly, BCC undergoes an unconventional inverse temperature symmetry breaking (ISTB) ferroelastic phase transition around 273 K. Differently, it transforms from a high symmetry low-temperature paraelastic phase (point group 2/m) to a low symmetry high-temperature ferroelastic phase (point group 1) originating from the rare mechanism of displacement of organic cations phase transition. It means that crystal BCC retains in ferroelastic phase above 273 K until melting point (446 K). Furthermore, characteristic ferroelastic domain patterns on crystal BCC are confirmed with polarized optical microscopy. Our study enriches the molecular mechanism of ferroelastics in the family of organic-inorganic hybrids and opens up a new avenue for exploring high-temperature ferroic materials.
Ferroelastic hybrid perovskite materials have been revealed the significance in the applications of switches, sensors, actuators, etc. However, it remains a challenge to design high-temperature ferroelastic to meet the requirements for the practical applications. Herein, we reported an one-dimensional organic-inorganic hybrid perovskites (OIHP) (3-methylpyrazolium)CdCl3 (3-MBCC), which possesses a mmmF2/m ferroelastic phase transition at 263 K. Moreover, utilizing crystal engineering, we replace –CH3 with –NH2 and –H, which increases the intermolecular force between organic cations and inorganic frameworks. The phase transition temperature of (3-aminopyrazolium)CdCl3 (3-ABCC), and (pyrazolium)CdCl3 (BCC) increased by 73 K and 10 K, respectively. Particularly, BCC undergoes an unconventional inverse temperature symmetry breaking (ISTB) ferroelastic phase transition around 273 K. Differently, it transforms from a high symmetry low-temperature paraelastic phase (point group 2/m) to a low symmetry high-temperature ferroelastic phase (point group 1) originating from the rare mechanism of displacement of organic cations phase transition. It means that crystal BCC retains in ferroelastic phase above 273 K until melting point (446 K). Furthermore, characteristic ferroelastic domain patterns on crystal BCC are confirmed with polarized optical microscopy. Our study enriches the molecular mechanism of ferroelastics in the family of organic-inorganic hybrids and opens up a new avenue for exploring high-temperature ferroic materials.
2024, 35(5): 108697
doi: 10.1016/j.cclet.2023.108697
Abstract:
The relationship mechanism between the material pore structures and cathodic iodine chemistry plays a vital role in efficient Zn-I2 batteries, but is unclear, retarding further advances. This work innovatively indicates a great contribution of ~2.5 nm pore structure of nanocarbons to efficient iodine adsorption, rapid I− ↔ I2 conversion, and polyiodide inhibition, via scrupulously designing catalysts with controllable pore sizes systematically. The I2-loading within the designed nitrogen-doped nanocarbons can reach up to as high as 60.8 wt%. The batteries based on the cathode deliver impressive performances with a large capacity of 178.8 mAh/g and long-term cycling stability more than 4000 h at 5.0 C. Notably, these is no polyiodide such as I3− and I5− detected during the charge-discharge processes from comprehensive electrochemical cyclic voltammetry, X-ray photoelectron spectroscopy, and Raman technique. This work provides a novel knowledge-guided concept for rational pore design, promising better Zn-I2 batteries, which is also hoped to benefit other advanced energy technologies, such as Li–S, Li-ion, and Al–I2 batteries.
The relationship mechanism between the material pore structures and cathodic iodine chemistry plays a vital role in efficient Zn-I2 batteries, but is unclear, retarding further advances. This work innovatively indicates a great contribution of ~2.5 nm pore structure of nanocarbons to efficient iodine adsorption, rapid I− ↔ I2 conversion, and polyiodide inhibition, via scrupulously designing catalysts with controllable pore sizes systematically. The I2-loading within the designed nitrogen-doped nanocarbons can reach up to as high as 60.8 wt%. The batteries based on the cathode deliver impressive performances with a large capacity of 178.8 mAh/g and long-term cycling stability more than 4000 h at 5.0 C. Notably, these is no polyiodide such as I3− and I5− detected during the charge-discharge processes from comprehensive electrochemical cyclic voltammetry, X-ray photoelectron spectroscopy, and Raman technique. This work provides a novel knowledge-guided concept for rational pore design, promising better Zn-I2 batteries, which is also hoped to benefit other advanced energy technologies, such as Li–S, Li-ion, and Al–I2 batteries.
2024, 35(5): 108698
doi: 10.1016/j.cclet.2023.108698
Abstract:
In the face of multiple challenges brought by the changes of global climate and environment, developing clean energy and updating green energy storage equipment are important ways to achieve carbon peak and carbon neutrality. Aqueous batteries have become a research hotspot due to their advantages of using the multivalent charge carrier, high ionic conductivity, environmental friendliness and cost effectiveness. In this work, the Cu2Se@C (Cu2Se coated on carbon clothes) thin film with a three-dimensional braided structure is fabricated by a simple electrochemical deposition method for Cu2+ storage for the first time. Compared with the commercial Cu2Se powder, the well-designed Cu2Se@C film shows enhanced specific capacity (640 mAh/g at 0.5 A/g) and rate performance (542 mAh/g at 5 A/g) as well as superior cycling stability (82.7% capacity retention after 1000 cycles at 1 A/g). The Cu2+ storage mechanism of the Cu2Se@C electrode is based on a reversible phase transition process of Cu2Se ↔ Cu2-xSe ↔ CuSe ↔ CuSe2. In kinetic characteristic analysis, the Cu2Se@C electrode demonstrates faster Cu2+ diffusion in discharge process than charge process resulting from the phase transition and the variation of interplanar spacing. This work highlights a facile one-piece design strategy and opens a new gateway for the exploration of advanced aqueous energy storage systems.
In the face of multiple challenges brought by the changes of global climate and environment, developing clean energy and updating green energy storage equipment are important ways to achieve carbon peak and carbon neutrality. Aqueous batteries have become a research hotspot due to their advantages of using the multivalent charge carrier, high ionic conductivity, environmental friendliness and cost effectiveness. In this work, the Cu2Se@C (Cu2Se coated on carbon clothes) thin film with a three-dimensional braided structure is fabricated by a simple electrochemical deposition method for Cu2+ storage for the first time. Compared with the commercial Cu2Se powder, the well-designed Cu2Se@C film shows enhanced specific capacity (640 mAh/g at 0.5 A/g) and rate performance (542 mAh/g at 5 A/g) as well as superior cycling stability (82.7% capacity retention after 1000 cycles at 1 A/g). The Cu2+ storage mechanism of the Cu2Se@C electrode is based on a reversible phase transition process of Cu2Se ↔ Cu2-xSe ↔ CuSe ↔ CuSe2. In kinetic characteristic analysis, the Cu2Se@C electrode demonstrates faster Cu2+ diffusion in discharge process than charge process resulting from the phase transition and the variation of interplanar spacing. This work highlights a facile one-piece design strategy and opens a new gateway for the exploration of advanced aqueous energy storage systems.
2024, 35(5): 108718
doi: 10.1016/j.cclet.2023.108718
Abstract:
Nanoplastics (NPs) in aqueous environment have become a category of emerging pollutants on account of their potential risks to both human health and environment. The detection of NPs is a great challenge due to the lack of sensitive and selective sensing materials with fast response time and wide sensing range of particle sizes. Herein, a Tb-based coordination polymer has been synthesized for luminescent detection of nanopolystyrene with different particle sizes in aqueous solutions, showing a low limit of detection, fast response time within 10 s and high selectivity in the presence of other plastics. The “turn-on” sensing mechanism is studied in detail. This work provides a facile method for the fast detection of NPs.
Nanoplastics (NPs) in aqueous environment have become a category of emerging pollutants on account of their potential risks to both human health and environment. The detection of NPs is a great challenge due to the lack of sensitive and selective sensing materials with fast response time and wide sensing range of particle sizes. Herein, a Tb-based coordination polymer has been synthesized for luminescent detection of nanopolystyrene with different particle sizes in aqueous solutions, showing a low limit of detection, fast response time within 10 s and high selectivity in the presence of other plastics. The “turn-on” sensing mechanism is studied in detail. This work provides a facile method for the fast detection of NPs.
2024, 35(5): 108748
doi: 10.1016/j.cclet.2023.108748
Abstract:
Porphyrins and their derivatives are excellent photosensitizers in photodynamic therapy (PDT). The modification of porphyrin molecules into metal-organic cages (MOCs) is a viable strategy to improve their bioavailability. In this work, MOC C66 based on porphyrin was synthesised by a one-pot self-assembly method. The three-dimensional structure of the metal-organic cage ameliorated the aggregation and self-quenching of porphyrins and increased the molar absorption coefficient in the visible light region, which enhanced the reactive oxygen species (ROS) yield of porphyrins and effectively improved the efficiency of photodynamic therapy. ROS generation ability tests in solution confirmed the improved reactive oxygen capacity of the cage, which showed greater phototoxicity to HeLa and MCF-7 cells in vitro, suggesting a new strategy for future modifications of the simple synthesis of porphyrins as photosensitizers.
Porphyrins and their derivatives are excellent photosensitizers in photodynamic therapy (PDT). The modification of porphyrin molecules into metal-organic cages (MOCs) is a viable strategy to improve their bioavailability. In this work, MOC C66 based on porphyrin was synthesised by a one-pot self-assembly method. The three-dimensional structure of the metal-organic cage ameliorated the aggregation and self-quenching of porphyrins and increased the molar absorption coefficient in the visible light region, which enhanced the reactive oxygen species (ROS) yield of porphyrins and effectively improved the efficiency of photodynamic therapy. ROS generation ability tests in solution confirmed the improved reactive oxygen capacity of the cage, which showed greater phototoxicity to HeLa and MCF-7 cells in vitro, suggesting a new strategy for future modifications of the simple synthesis of porphyrins as photosensitizers.
2024, 35(5): 108752
doi: 10.1016/j.cclet.2023.108752
Abstract:
Multifunctional drug delivery systems (DDSs) have shown great prospects in overcoming the heterogeneous barrier of delivery drugs to the complex tumor microenvironment (TME). In this study, multifunctional AS/Ge-pNAB microgels with dual-active targeting, triple environment responsiveness, and fluorescence imaging capability were prepared through a straightforward procedure. This was aimed to improve the antitumor therapeutic application of gambogic acid (GA) based on the biological characteristics of TME. The microgels have a uniform double-layer structure with aptamer in the outer layer which helps in recognizing receptors on the tumor cells. The GA loaded nano-herb exhibited environment-responsive drug release profiles under acidic pH, reductant and high temperature. The nano-herb significantly improved the accumulation of GA in tumor sites through the synergistic combination of the enhanced permeability and retention effect and dual-ligand mediated internalization. Then, it accelerated intracellular drug release and killed tumor cells. Therefore, the nano-herb had specific therapeutic effects on the tumor in vitro and in vivo as they remarkably inhibited tumor growth while depicting optimal biosafety and lower levels of off-target toxicity. Overall, these findings demonstrate the great potential of the multifunctional AS/Ge-pNAB microgels for precisely targeted GA delivery and open a new avenue for the facile preparation of multifunctional DDSs.
Multifunctional drug delivery systems (DDSs) have shown great prospects in overcoming the heterogeneous barrier of delivery drugs to the complex tumor microenvironment (TME). In this study, multifunctional AS/Ge-pNAB microgels with dual-active targeting, triple environment responsiveness, and fluorescence imaging capability were prepared through a straightforward procedure. This was aimed to improve the antitumor therapeutic application of gambogic acid (GA) based on the biological characteristics of TME. The microgels have a uniform double-layer structure with aptamer in the outer layer which helps in recognizing receptors on the tumor cells. The GA loaded nano-herb exhibited environment-responsive drug release profiles under acidic pH, reductant and high temperature. The nano-herb significantly improved the accumulation of GA in tumor sites through the synergistic combination of the enhanced permeability and retention effect and dual-ligand mediated internalization. Then, it accelerated intracellular drug release and killed tumor cells. Therefore, the nano-herb had specific therapeutic effects on the tumor in vitro and in vivo as they remarkably inhibited tumor growth while depicting optimal biosafety and lower levels of off-target toxicity. Overall, these findings demonstrate the great potential of the multifunctional AS/Ge-pNAB microgels for precisely targeted GA delivery and open a new avenue for the facile preparation of multifunctional DDSs.
2024, 35(5): 108755
doi: 10.1016/j.cclet.2023.108755
Abstract:
Dendritic cell (DC)-targeted delivery of mRNA is a prominent method to boost the efficacy of mRNA tumor vaccines. The targeting ligands are often modified on nanocarriers by polyethylene glycol (PEG) linker in mRNA delivery systems. Whether the PEG linker length influences the targeting delivery efficiency of mRNA nanocarrier in vivo remains unclear. Here, we designed and constructed DC-targeted mRNA delivery systems modified by mannose via different PEG linker lengths (100/400/1000/2000) (MPn-LPX). The top candidate MP400-LPX (the linker was PEG400) showed the optimal mRNA expression and antigen presentation owing to the highly efficient uptake by DCs. Furthermore, MP400-LPX could better inhibited tumor growth and extended survival in the E.G7-OVA lymphoma and TC-1 cervical tumor mouse model. Collectively, these results demonstrated that PEG400 was the optimal linker for the PEGylated DC-targeted mRNA vaccines. Our findings provided a new platform for the rational design of targeted mRNA nanovaccines with shorter-length PEG.
Dendritic cell (DC)-targeted delivery of mRNA is a prominent method to boost the efficacy of mRNA tumor vaccines. The targeting ligands are often modified on nanocarriers by polyethylene glycol (PEG) linker in mRNA delivery systems. Whether the PEG linker length influences the targeting delivery efficiency of mRNA nanocarrier in vivo remains unclear. Here, we designed and constructed DC-targeted mRNA delivery systems modified by mannose via different PEG linker lengths (100/400/1000/2000) (MPn-LPX). The top candidate MP400-LPX (the linker was PEG400) showed the optimal mRNA expression and antigen presentation owing to the highly efficient uptake by DCs. Furthermore, MP400-LPX could better inhibited tumor growth and extended survival in the E.G7-OVA lymphoma and TC-1 cervical tumor mouse model. Collectively, these results demonstrated that PEG400 was the optimal linker for the PEGylated DC-targeted mRNA vaccines. Our findings provided a new platform for the rational design of targeted mRNA nanovaccines with shorter-length PEG.
2024, 35(5): 108762
doi: 10.1016/j.cclet.2023.108762
Abstract:
The interaction among type Ⅱ collagen (CII), human DR4 major histocompatibility complex type Ⅱ molecule (MHC Ⅱ) and T-cell receptor (TCR) is associated with the development of rheumatoid arthritis (RA). The activation of T cells can be reduced through exposure to modified CII(263–272) glycopeptide fragment via competitive inhibition with self-antigen. In this work, 30 peptides based on the sequence of CII(263–272) were prepared and evaluated for their binding to DR4 protein by surface plasmon resonance (SPR) assay. The effect on the secretion of pro-inflammatory factors by the spleen cells in collagen induced rheumatoid arthritis (CIA) mouse was also investigated. Two N-glycosylated CII peptides were identified to have strong binding to the human recombinant DR4 protein and weak proinflammatory effect. These glycopeptides could be developed as therapeutic saccharide vaccines for the treatment of rheumatoid arthritis (RA).
The interaction among type Ⅱ collagen (CII), human DR4 major histocompatibility complex type Ⅱ molecule (MHC Ⅱ) and T-cell receptor (TCR) is associated with the development of rheumatoid arthritis (RA). The activation of T cells can be reduced through exposure to modified CII(263–272) glycopeptide fragment via competitive inhibition with self-antigen. In this work, 30 peptides based on the sequence of CII(263–272) were prepared and evaluated for their binding to DR4 protein by surface plasmon resonance (SPR) assay. The effect on the secretion of pro-inflammatory factors by the spleen cells in collagen induced rheumatoid arthritis (CIA) mouse was also investigated. Two N-glycosylated CII peptides were identified to have strong binding to the human recombinant DR4 protein and weak proinflammatory effect. These glycopeptides could be developed as therapeutic saccharide vaccines for the treatment of rheumatoid arthritis (RA).
2024, 35(5): 108763
doi: 10.1016/j.cclet.2023.108763
Abstract:
High-performance carbon dots (CDs) allowing the application in high-end display devices are highly desirable and usually limited by the absence of simple and easy synthesis methods. In this work, we exploited an easy-to-implement strategy for the one-step synthesis of green-emitting CDs (G-CDs) with superb optical properties. The G-CDs were synthesized using m-phenylenediamine (m-PD) as a single precursor, and the reaction reacted at 180 ℃ for 12 h The resultant G-CDs exhibit high-purity and excitation-independent green fluorescence with the photoluminescence (PL) peak located at 516 nm, full width at half maximum (FWHM) of 46 nm, and PL quantum yield (QY) of ~80% under the 470 nm excitation light. The G-CDs and corresponding composite film prepared with polyvinyl butyral (G-CDs@PVB) exhibit good PL stability after undergoing long-time storage for one year and 360 h exposure under 460 nm blue light. The G-CDs@PVB film was used as color-conversion materials in green-emitting light-emitting diode (LED) application, exhibiting a Commission internationale de l'Eclairage (CIE) chromaticity coordinate of (0.21, 0.44). The film was also used in CD-based liquid crystal display (CD-LCD) application, achieving a color gamut value of 85%. This work will offer a working basis for the synthesis of high-performance CDs as well as their application in displays.
High-performance carbon dots (CDs) allowing the application in high-end display devices are highly desirable and usually limited by the absence of simple and easy synthesis methods. In this work, we exploited an easy-to-implement strategy for the one-step synthesis of green-emitting CDs (G-CDs) with superb optical properties. The G-CDs were synthesized using m-phenylenediamine (m-PD) as a single precursor, and the reaction reacted at 180 ℃ for 12 h The resultant G-CDs exhibit high-purity and excitation-independent green fluorescence with the photoluminescence (PL) peak located at 516 nm, full width at half maximum (FWHM) of 46 nm, and PL quantum yield (QY) of ~80% under the 470 nm excitation light. The G-CDs and corresponding composite film prepared with polyvinyl butyral (G-CDs@PVB) exhibit good PL stability after undergoing long-time storage for one year and 360 h exposure under 460 nm blue light. The G-CDs@PVB film was used as color-conversion materials in green-emitting light-emitting diode (LED) application, exhibiting a Commission internationale de l'Eclairage (CIE) chromaticity coordinate of (0.21, 0.44). The film was also used in CD-based liquid crystal display (CD-LCD) application, achieving a color gamut value of 85%. This work will offer a working basis for the synthesis of high-performance CDs as well as their application in displays.
2024, 35(5): 108788
doi: 10.1016/j.cclet.2023.108788
Abstract:
We reported the characterization of a novel brassicicene diterpene biosynthetic gene cluster, which contains a unique α-ketoglutarate-dependent dioxygenase (αKGD) enzyme, AbnI. Our findings revealed that AbnI demonstrates remarkable substrate promiscuity and is capable of activating multiple sites on both 5–8–5 and 5–9–5 brassicicene skeletons, resulting in skeleton modifications and an unexpected ring system rearrangement. These results suggested the potential utility of AbnI as an enzymatic tool for terpene CH functionalization. In addition, the catalytic mechanism of AbnI and its potential ecological implications were discussed.
We reported the characterization of a novel brassicicene diterpene biosynthetic gene cluster, which contains a unique α-ketoglutarate-dependent dioxygenase (αKGD) enzyme, AbnI. Our findings revealed that AbnI demonstrates remarkable substrate promiscuity and is capable of activating multiple sites on both 5–8–5 and 5–9–5 brassicicene skeletons, resulting in skeleton modifications and an unexpected ring system rearrangement. These results suggested the potential utility of AbnI as an enzymatic tool for terpene CH functionalization. In addition, the catalytic mechanism of AbnI and its potential ecological implications were discussed.
2024, 35(5): 108792
doi: 10.1016/j.cclet.2023.108792
Abstract:
Thirty-one new 10,12-disubstituted aloperine derivatives were subtly constructed through a selective oxidation on the 10-α-C–H induced by sulfonyl and a nucleophilic substitution with the stereoselectivity and scalability. Of them, compound 6b displayed a moderate anti-human coronavirus OC43 (HCoV-OC43) potency and blocked the viral entry stage through a host mechanism of action. Using chemoproteomic techniques, both transmembrane serine protease 2 (TMPRSS2) and scavenger receptor class B type 1 (SR-B1) proteins, which act as host cofactors of viral entry, were identified to be the direct targets of 6b against HCoV-OC43. Furthermore, 6b may deactivate the TMPRSS2 by inducing a change in protein conformation, rather than binding to its catalytic center, thus suppressing the viral membrane fusion. Accordingly, our study provided key scientific data for the development of aloperine derivatives into a new class of antiviral candidates against human β-coronavirus, including severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2).
Thirty-one new 10,12-disubstituted aloperine derivatives were subtly constructed through a selective oxidation on the 10-α-C–H induced by sulfonyl and a nucleophilic substitution with the stereoselectivity and scalability. Of them, compound 6b displayed a moderate anti-human coronavirus OC43 (HCoV-OC43) potency and blocked the viral entry stage through a host mechanism of action. Using chemoproteomic techniques, both transmembrane serine protease 2 (TMPRSS2) and scavenger receptor class B type 1 (SR-B1) proteins, which act as host cofactors of viral entry, were identified to be the direct targets of 6b against HCoV-OC43. Furthermore, 6b may deactivate the TMPRSS2 by inducing a change in protein conformation, rather than binding to its catalytic center, thus suppressing the viral membrane fusion. Accordingly, our study provided key scientific data for the development of aloperine derivatives into a new class of antiviral candidates against human β-coronavirus, including severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2).
2024, 35(5): 108805
doi: 10.1016/j.cclet.2023.108805
Abstract:
The fascinating chemical structure and broad application prospect of Keggin-type polyoxometalates (POMs) have attracted many chemists to explore and discover continuously. Unlike the traditional Keggin, larger metal atomic radius, higher metal coordinated numbers, lower metal valence states and other features allow the group IVB metal-based Keggin (IVB-Keggin) more space and unknown in terms of structure and performance. Herein, density functional theory (DFT) calculations were performed to explore the influences including cores, shells, caps, and terminal ligands, et al. on IVB-Keggin, and analyze the possibility of novel structure synthesis. From the perspective of multi-layer onion-like clusters, molecular energy level, host-guest interaction energy, surface charge and covalent bond polarity can be further adjusted to achieve the oriented design of functional IVB-Keggin. These insights are expected to provide theoretical support for experimental synthesis, opening a new perspective to understand the growth of Keggin.
The fascinating chemical structure and broad application prospect of Keggin-type polyoxometalates (POMs) have attracted many chemists to explore and discover continuously. Unlike the traditional Keggin, larger metal atomic radius, higher metal coordinated numbers, lower metal valence states and other features allow the group IVB metal-based Keggin (IVB-Keggin) more space and unknown in terms of structure and performance. Herein, density functional theory (DFT) calculations were performed to explore the influences including cores, shells, caps, and terminal ligands, et al. on IVB-Keggin, and analyze the possibility of novel structure synthesis. From the perspective of multi-layer onion-like clusters, molecular energy level, host-guest interaction energy, surface charge and covalent bond polarity can be further adjusted to achieve the oriented design of functional IVB-Keggin. These insights are expected to provide theoretical support for experimental synthesis, opening a new perspective to understand the growth of Keggin.
2024, 35(5): 108818
doi: 10.1016/j.cclet.2023.108818
Abstract:
Hydroxylation of steroid core is critical to the synthesis of steroid drugs. Direct sp3 C–H hydroxylation is challenging through chemical catalysis, alternatively, fungal biotransformation offers a possible solution to this problem. However, mining and metabolic engineering of cytochrome P450 monooxygenases (CYPs) is usually regarded as a more eco-friendly and efficient strategy. Herein, we report the mining and identification of a new steroid CYP (CYP68BE1) from Beauveria bassiana by transcriptomics, heterologous expression, in vivo and in vitro functional characterization. The catalytic promiscuity of CYP68BE1 was explored, and CYP68BE1 showed promiscuously and catalytically versatile, which is qualified for monohydroxylation on C11α, C1α, C6β and dihydroxylation on C1β, 11α and C6β, 11α of six steroids, leading to the production of key steroid intermediates required in the industrial synthesis of some indispensable steroid drugs. Molecular dynamics simulations were performed, revealing the molecular basis of different binding orientations of CYP68BE1 with different substrates. The discovery of CYP68BE1 offers a promising biocatalyst for enriching the steroid structural and functional diversity, which also can be applied to biosynthesize valuable steroid drug intermediates.
Hydroxylation of steroid core is critical to the synthesis of steroid drugs. Direct sp3 C–H hydroxylation is challenging through chemical catalysis, alternatively, fungal biotransformation offers a possible solution to this problem. However, mining and metabolic engineering of cytochrome P450 monooxygenases (CYPs) is usually regarded as a more eco-friendly and efficient strategy. Herein, we report the mining and identification of a new steroid CYP (CYP68BE1) from Beauveria bassiana by transcriptomics, heterologous expression, in vivo and in vitro functional characterization. The catalytic promiscuity of CYP68BE1 was explored, and CYP68BE1 showed promiscuously and catalytically versatile, which is qualified for monohydroxylation on C11α, C1α, C6β and dihydroxylation on C1β, 11α and C6β, 11α of six steroids, leading to the production of key steroid intermediates required in the industrial synthesis of some indispensable steroid drugs. Molecular dynamics simulations were performed, revealing the molecular basis of different binding orientations of CYP68BE1 with different substrates. The discovery of CYP68BE1 offers a promising biocatalyst for enriching the steroid structural and functional diversity, which also can be applied to biosynthesize valuable steroid drug intermediates.
2024, 35(5): 108819
doi: 10.1016/j.cclet.2023.108819
Abstract:
A novel cationic Pt(Ⅱ) complex 2 with 2-(2,4-difluorophenyl)pyridine as the cyclometalating ligand and 1,10-phenanthroline as the auxiliary ligand has been synthesized and fully characterized. This complex exhibits much higher aggregation-induced phosphorescent emission activity than that of a non-fluorinated complex 1 in CH3CN/H2O. The complex 2 demonstrates efficient detection on picric acid (PA) in CH3CN/H2O, providing a high quenching constant (KSV = 2.3 × 104 L/mol) and a low limit of detection (LOD = 0.26 µmol/L). In addition, complex 2 shows high selectivity for detection of PA in real water samples. Density functional theory calculations and proton nuclear magnetic resonance spectra suggest that the detection mechanism is attributed to the photo-induced electron transfer.
A novel cationic Pt(Ⅱ) complex 2 with 2-(2,4-difluorophenyl)pyridine as the cyclometalating ligand and 1,10-phenanthroline as the auxiliary ligand has been synthesized and fully characterized. This complex exhibits much higher aggregation-induced phosphorescent emission activity than that of a non-fluorinated complex 1 in CH3CN/H2O. The complex 2 demonstrates efficient detection on picric acid (PA) in CH3CN/H2O, providing a high quenching constant (KSV = 2.3 × 104 L/mol) and a low limit of detection (LOD = 0.26 µmol/L). In addition, complex 2 shows high selectivity for detection of PA in real water samples. Density functional theory calculations and proton nuclear magnetic resonance spectra suggest that the detection mechanism is attributed to the photo-induced electron transfer.
2024, 35(5): 108820
doi: 10.1016/j.cclet.2023.108820
Abstract:
Alginate is a natural polysaccharide polymer. Hydrogel filtration membranes prepared from alginate show excellent fouling resistance and controllable separation performance, but poor mechanical properties limit the use of algae hydrogels. In this study, Ba2+/Ca2+ co-crosslinked alginate (Ba/CaAlg) hydrogel membrane was prepared by cross-linking sodium alginate with a blend aqueous solution of barium ions and calcium ions, and the membrane was applied to the separation of dyes/salts from dyeing wastewater. Compared with the CaAlg membrane, the Ba/CaAlg hydrogel membrane exhibited more stable structure, and the mechanical properties and salt tolerance of the membrane were significantly improved. The flux of Ba/CaAlg membrane for methyl blue/sodium chloride mixed solution reached 43.5 L m−2 h−1, which was significantly higher than that of CaAlg membrane. Besides, the Ba/CaAlg membrane showed higher dye rejection (>99.6%) and lower salt rejection (<8.2%). The structure of Ba/CaAlg membrane was preliminarily simulated by molecular dynamics, and the pore size and distribution of the membrane were calculated. The Ba/CaAlg membrane has a broad application prospect in dyes/salts separation.
Alginate is a natural polysaccharide polymer. Hydrogel filtration membranes prepared from alginate show excellent fouling resistance and controllable separation performance, but poor mechanical properties limit the use of algae hydrogels. In this study, Ba2+/Ca2+ co-crosslinked alginate (Ba/CaAlg) hydrogel membrane was prepared by cross-linking sodium alginate with a blend aqueous solution of barium ions and calcium ions, and the membrane was applied to the separation of dyes/salts from dyeing wastewater. Compared with the CaAlg membrane, the Ba/CaAlg hydrogel membrane exhibited more stable structure, and the mechanical properties and salt tolerance of the membrane were significantly improved. The flux of Ba/CaAlg membrane for methyl blue/sodium chloride mixed solution reached 43.5 L m−2 h−1, which was significantly higher than that of CaAlg membrane. Besides, the Ba/CaAlg membrane showed higher dye rejection (>99.6%) and lower salt rejection (<8.2%). The structure of Ba/CaAlg membrane was preliminarily simulated by molecular dynamics, and the pore size and distribution of the membrane were calculated. The Ba/CaAlg membrane has a broad application prospect in dyes/salts separation.
2024, 35(5): 108822
doi: 10.1016/j.cclet.2023.108822
Abstract:
Staphylococcal enterotoxin A (SEA) derived from Staphylococcus aureus, as a superantigen, shows potential for cancer immunotherapy, but systemic immunotoxicity restricts its clinical application. Targeted delivery of SEA to tumor site provides a promising option for reducing the systemic toxicity. Here, we constructed an iRGD peptide (H-[Cys-Arg-Gly-Asp-Lys-Gly-Pro-Asp-Cys]-NH2) modified nanoparticle (iDPP) to deliver plasmids encoding SEA for melanoma treatment. The iDPP/SEA nanocomplexes efficiently mediated SEA expression in B16-F10 cells in vivo and in vitro and induced the activation of lymphocytes and maturation of murine bone marrow-derived dendritic cells (BMDCs) in vitro. In the subcutaneous B16-F10 melanoma model, the iDPP/SEA nanocomplexes could effectively enhance immune response and T lymphocytes infiltration in tumor site after intravenous administration, thereby considerably decreased melanoma growth. Meanwhile, no obvious adverse effect was observed after intravenous administration of the iDPP/SEA nanocomplexes in vivo. Our findings demonstrated that gene therapy of SEA is a potential candidate for melanoma treatment.
Staphylococcal enterotoxin A (SEA) derived from Staphylococcus aureus, as a superantigen, shows potential for cancer immunotherapy, but systemic immunotoxicity restricts its clinical application. Targeted delivery of SEA to tumor site provides a promising option for reducing the systemic toxicity. Here, we constructed an iRGD peptide (H-[Cys-Arg-Gly-Asp-Lys-Gly-Pro-Asp-Cys]-NH2) modified nanoparticle (iDPP) to deliver plasmids encoding SEA for melanoma treatment. The iDPP/SEA nanocomplexes efficiently mediated SEA expression in B16-F10 cells in vivo and in vitro and induced the activation of lymphocytes and maturation of murine bone marrow-derived dendritic cells (BMDCs) in vitro. In the subcutaneous B16-F10 melanoma model, the iDPP/SEA nanocomplexes could effectively enhance immune response and T lymphocytes infiltration in tumor site after intravenous administration, thereby considerably decreased melanoma growth. Meanwhile, no obvious adverse effect was observed after intravenous administration of the iDPP/SEA nanocomplexes in vivo. Our findings demonstrated that gene therapy of SEA is a potential candidate for melanoma treatment.
2024, 35(5): 108823
doi: 10.1016/j.cclet.2023.108823
Abstract:
The clinical benefit of combination therapy is significant, but it is not easy to define the mechanism of complexity and diversity. Previous studies illustrate that phillygenin (Phi) binds in the allosteric inhibit pocket of protein kinase B (AKT), and swertiamarin (Swe) acts on the pleckstrin homology (PH) domain of AKT. However, the combined synergistic effect of relieving the inflammatory response has yet to be elucidated. Based on high sensitivity, specificity and fast-responsibility fluorescent sensors, the Förster resonance energy transfer (FRET) technique offers a route to provide clear insights into physiological and pathological processes. In the study, molecular docking, the fluorescent probes of Phi and Swe for FRET were designed and synthesized. FRET analysis shown that Swe and Phi concurrently acted on the PH domain and allosterically inhibited pocket of AKT, respectively. The combination of Swe and Phi significantly increased the heat stability of AKT and decreased protease-induced degeneration. In lipopolysaccharides (LPS)-induced mice and cells, the combination arrested AKT activation, nuclear factor kappa-B (NF-κB) phosphorylation, and the expression of tumor necrosis factor-α (TNF-α), interleukin (IL)-6 and IL-8. In conclusion, FRET revealed Phi and Swe concurrently targeted AKT on different domains and the combination of Phi and Swe enhanced the anti-inflammatory effect.
The clinical benefit of combination therapy is significant, but it is not easy to define the mechanism of complexity and diversity. Previous studies illustrate that phillygenin (Phi) binds in the allosteric inhibit pocket of protein kinase B (AKT), and swertiamarin (Swe) acts on the pleckstrin homology (PH) domain of AKT. However, the combined synergistic effect of relieving the inflammatory response has yet to be elucidated. Based on high sensitivity, specificity and fast-responsibility fluorescent sensors, the Förster resonance energy transfer (FRET) technique offers a route to provide clear insights into physiological and pathological processes. In the study, molecular docking, the fluorescent probes of Phi and Swe for FRET were designed and synthesized. FRET analysis shown that Swe and Phi concurrently acted on the PH domain and allosterically inhibited pocket of AKT, respectively. The combination of Swe and Phi significantly increased the heat stability of AKT and decreased protease-induced degeneration. In lipopolysaccharides (LPS)-induced mice and cells, the combination arrested AKT activation, nuclear factor kappa-B (NF-κB) phosphorylation, and the expression of tumor necrosis factor-α (TNF-α), interleukin (IL)-6 and IL-8. In conclusion, FRET revealed Phi and Swe concurrently targeted AKT on different domains and the combination of Phi and Swe enhanced the anti-inflammatory effect.
2024, 35(5): 108825
doi: 10.1016/j.cclet.2023.108825
Abstract:
Ursolic acid (UA) is a naturally occurring ursane triterpenoid, which exhibits a wide range of unique biological activities. To clarify its mechanism of action (MOA), a series of fluorescent derivatives of UA (5a–c) were designed and synthesized by conjugation with 7-nitrobenzo-2-oxa-1,3-diazole (NBD) fluorophore. Among them, 5c exhibited similar anti-proliferative activity with UA against HCT116 cells (half maximal inhibitory concentration (IC50) = 9.21 ± 0.50 µmol/L). Cell imaging experiment indicated that 5c was rapidly taken up in HCT116 cells in a dose and time-dependent manner. Then, 5c was found to localize in endoplasmic reticulum (ER), lysosomes, and mitochondria, but not in nucleus of HCT116 cells by confocal microscopy studies. Preliminary MOA proved that UA induced autophagy with a unique intracellular distribution mechanism involving ER and lysosome. In all, our work provides new clues for revealing the molecular mechanism of UA as an antitumor agent.
Ursolic acid (UA) is a naturally occurring ursane triterpenoid, which exhibits a wide range of unique biological activities. To clarify its mechanism of action (MOA), a series of fluorescent derivatives of UA (5a–c) were designed and synthesized by conjugation with 7-nitrobenzo-2-oxa-1,3-diazole (NBD) fluorophore. Among them, 5c exhibited similar anti-proliferative activity with UA against HCT116 cells (half maximal inhibitory concentration (IC50) = 9.21 ± 0.50 µmol/L). Cell imaging experiment indicated that 5c was rapidly taken up in HCT116 cells in a dose and time-dependent manner. Then, 5c was found to localize in endoplasmic reticulum (ER), lysosomes, and mitochondria, but not in nucleus of HCT116 cells by confocal microscopy studies. Preliminary MOA proved that UA induced autophagy with a unique intracellular distribution mechanism involving ER and lysosome. In all, our work provides new clues for revealing the molecular mechanism of UA as an antitumor agent.
2024, 35(5): 108826
doi: 10.1016/j.cclet.2023.108826
Abstract:
Strand displacement reaction is a crucial component in the assembly of diverse DNA-based nanodevices, with the toehold-mediated strand displacement reaction representing the prevailing strategy. However, the single-stranded Watson-Crick sticky region that serves as the trigger for strand displacement can also cause leakage reactions by introducing crosstalk in complex DNA circuits. Here, we proposed the toeless and reversible DNA strand displacement reaction based on the Hoogsteen-bond triplex, which is compatible with most of the existing DNA circuits. We demonstrated that our proposed reaction can occur at pH 5 and can be reversed at pH 9. We also observed an approximately linear relationship between the degree of reaction and pH within the range of pH 5–6, providing the potential for precise regulation of the reaction. Meanwhile, by altering the sequence orientation, we have demonstrated that our proposed reaction can be initiated or regulated through the same toeless mechanism without the requirement for protonation in low pH conditions. Based on the proposed reaction principle, we further constructed a variety of DNA nanodevices, including two types of DNA logic gates that rely on pH 5/pH 9 changes for initiating and reversing: the AND gate and the OR gate. We also successfully constructed a DNA Walker based on our proposed reaction modes, which can move along a given track after the introduction of a programmable DNA sequence and complete a cycle after 4 steps. Our findings suggest that this innovative approach will have broad utility in the development of DNA circuits, molecular sensors, and other complex biological systems.
Strand displacement reaction is a crucial component in the assembly of diverse DNA-based nanodevices, with the toehold-mediated strand displacement reaction representing the prevailing strategy. However, the single-stranded Watson-Crick sticky region that serves as the trigger for strand displacement can also cause leakage reactions by introducing crosstalk in complex DNA circuits. Here, we proposed the toeless and reversible DNA strand displacement reaction based on the Hoogsteen-bond triplex, which is compatible with most of the existing DNA circuits. We demonstrated that our proposed reaction can occur at pH 5 and can be reversed at pH 9. We also observed an approximately linear relationship between the degree of reaction and pH within the range of pH 5–6, providing the potential for precise regulation of the reaction. Meanwhile, by altering the sequence orientation, we have demonstrated that our proposed reaction can be initiated or regulated through the same toeless mechanism without the requirement for protonation in low pH conditions. Based on the proposed reaction principle, we further constructed a variety of DNA nanodevices, including two types of DNA logic gates that rely on pH 5/pH 9 changes for initiating and reversing: the AND gate and the OR gate. We also successfully constructed a DNA Walker based on our proposed reaction modes, which can move along a given track after the introduction of a programmable DNA sequence and complete a cycle after 4 steps. Our findings suggest that this innovative approach will have broad utility in the development of DNA circuits, molecular sensors, and other complex biological systems.
2024, 35(5): 108863
doi: 10.1016/j.cclet.2023.108863
Abstract:
An approach for distinguishing two types of positional isomers of dimeric shikonin and its analogs was explored with 4JC, H long-range correlation by prolonging the acquisition time at 2,3JC, H values of 2.0 and 8.0 Hz. Furthermore, the 1H (proton) nuclear magnetic resonance (NMR) pattern of phenolic hydroxyl protons was developed as a "diagnosis signal" to ascertain the relative location of each side chain in DMSO–d6 at sample concentrations of 0.022–0.034 mol/L. The chemical shift differences of 0.6 ppm between OH-5′ and OH-1 and between OH-8′ and OH-4 are assigned to Type A and Type B, respectively. All reported ambiguous structures were corrected by this pattern. Additionally, the steric structures of isolated compounds were elucidated by quantum chemical calculations of electronic circular dichroism (ECD) spectra.
An approach for distinguishing two types of positional isomers of dimeric shikonin and its analogs was explored with 4JC, H long-range correlation by prolonging the acquisition time at 2,3JC, H values of 2.0 and 8.0 Hz. Furthermore, the 1H (proton) nuclear magnetic resonance (NMR) pattern of phenolic hydroxyl protons was developed as a "diagnosis signal" to ascertain the relative location of each side chain in DMSO–d6 at sample concentrations of 0.022–0.034 mol/L. The chemical shift differences of 0.6 ppm between OH-5′ and OH-1 and between OH-8′ and OH-4 are assigned to Type A and Type B, respectively. All reported ambiguous structures were corrected by this pattern. Additionally, the steric structures of isolated compounds were elucidated by quantum chemical calculations of electronic circular dichroism (ECD) spectra.
2024, 35(5): 108882
doi: 10.1016/j.cclet.2023.108882
Abstract:
AIEgens can serve as an effective platform for the construction of photosensitizer-based immunogenic cell death (ICD) inducers. To date, several mitochondria or endoplasmic reticulum (ER)-targeted aggregation-induced emission (AIE) molecules have been developed and have evoked massive ICD in cells. However, due to the complex physicochemical environment in cells, these small AIE molecules cannot maintain a stable aggregate state, which not only affects the fluorescence intensity of the photosensitizer but also decreases the generation of reactive oxygen species (ROS), and thus reducing the effect of the photosensitizer to elicit ICD. AIEgen-based nanomicelles, which maintain a stable micellar structure, can prevent defects of AIE molecules in photodynamic therapy (PDT) applications. Therefore, in this study, a mitochondria-targeted AIE nanophotosensitizer was synthesized and used as a highly potent ICD inducer for vaccine preparation and tumor prevention.
AIEgens can serve as an effective platform for the construction of photosensitizer-based immunogenic cell death (ICD) inducers. To date, several mitochondria or endoplasmic reticulum (ER)-targeted aggregation-induced emission (AIE) molecules have been developed and have evoked massive ICD in cells. However, due to the complex physicochemical environment in cells, these small AIE molecules cannot maintain a stable aggregate state, which not only affects the fluorescence intensity of the photosensitizer but also decreases the generation of reactive oxygen species (ROS), and thus reducing the effect of the photosensitizer to elicit ICD. AIEgen-based nanomicelles, which maintain a stable micellar structure, can prevent defects of AIE molecules in photodynamic therapy (PDT) applications. Therefore, in this study, a mitochondria-targeted AIE nanophotosensitizer was synthesized and used as a highly potent ICD inducer for vaccine preparation and tumor prevention.
2024, 35(5): 108885
doi: 10.1016/j.cclet.2023.108885
Abstract:
Saccharides are a sort of ubiquitous and vital molecules within the whole life. However, the application of saccharides analysis with matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) is restricted by their low ionization efficiency and the instability of the sialic acid fraction. Derivatization strategy based on nonreductive amination provides a good solution, however, this is often time consuming and may result in sample loss due to removal of excessive derivatization reagents. Herein, hydralazine (HZN) was utilized as a reactive matrix for labeling reducing saccharides directly on MALDI target which eliminated tedious sample preparation and avoided sample loss. After optimization, effective and reproducible on-MALDI-target derivatization of neutral and acidic saccharides was achieved in both positive and negative modes. Compared with 2,5-dihydroxybenzoic acid (DHB) and 9-aminoacridine (9-AA), HZN improved the detection sensitivity of reducing saccharides and provided more abundant fragment ions in MS/MS analysis. Moreover, 26 kinds of neutral glycans and 5 kinds of sialic glycans were identified from ovalbumin (OVA) and bovine fetuin, respectively. Combined with the statistical models, this strategy could be used to distinguish and predict samples of 6 brands of beer, and discriminate 2 kinds of beer fermentation modes. In addition, HZN was applied for quantitative analysis of glucose in urine samples, and the obtained urine glucose concentrations of diabetic patients were consistent with the clinical test results, showing the potential of qualitative and quantitative analysis of reducing saccharides in complex samples.
Saccharides are a sort of ubiquitous and vital molecules within the whole life. However, the application of saccharides analysis with matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) is restricted by their low ionization efficiency and the instability of the sialic acid fraction. Derivatization strategy based on nonreductive amination provides a good solution, however, this is often time consuming and may result in sample loss due to removal of excessive derivatization reagents. Herein, hydralazine (HZN) was utilized as a reactive matrix for labeling reducing saccharides directly on MALDI target which eliminated tedious sample preparation and avoided sample loss. After optimization, effective and reproducible on-MALDI-target derivatization of neutral and acidic saccharides was achieved in both positive and negative modes. Compared with 2,5-dihydroxybenzoic acid (DHB) and 9-aminoacridine (9-AA), HZN improved the detection sensitivity of reducing saccharides and provided more abundant fragment ions in MS/MS analysis. Moreover, 26 kinds of neutral glycans and 5 kinds of sialic glycans were identified from ovalbumin (OVA) and bovine fetuin, respectively. Combined with the statistical models, this strategy could be used to distinguish and predict samples of 6 brands of beer, and discriminate 2 kinds of beer fermentation modes. In addition, HZN was applied for quantitative analysis of glucose in urine samples, and the obtained urine glucose concentrations of diabetic patients were consistent with the clinical test results, showing the potential of qualitative and quantitative analysis of reducing saccharides in complex samples.
2024, 35(5): 108888
doi: 10.1016/j.cclet.2023.108888
Abstract:
The platinum-based chemotherapy is a routine strategy for the treatment of ovarian cancer, while it is prone to chemoresistance in clinical, which hinders the treatment. Therefore, it is urgently needed to elucidate the underlying mechanism of drug resistance and form the appropriate strategy. The sequencing results showed that cisplatin (DDP) resistant ovarian cancer overexpressed BTB and CNC homology 1 (BACH1), and up-regulated the “don't eat me” signal CD47. We identified that hemin, a BACH1 inhibitor, could effectively down-regulate BACH1 and simultaneously inhibit CD47. Moreover, hemin has a synergistic effect with DDP. We designed a pH-responsive nanoparticle (H/D@FA–CaP–NPs) in which folic acid (FA) ensured targeting of ovarian cancer cells, while hemin inhibited BACH1 as well as down-regulated CD47, achieving the promotion of apoptosis of tumor cells and inducing phagocytosis of tumors by macrophages. Moreover, hemin has a synergistic effect with DDP to promote apoptosis of tumor cells. Structurally, hemin and DDP was encapsulated within hydrophobic 1,2-distearoyl-sn-glycero-3-phospho-ethanolamine (DSPE) to form a tight core, and hydrophilic polyethylene glycol 2000 (PEG2000) and calcium phosphate (CaP) formed the outside shell, and FA was modified on the surface of nanoparticles. In terms of function, (a) FA enhanced the active targeting of nanoparticles to tumors; (b) NPs targeted mitochondria to induce reactive oxygen species (ROS) production; (c) hemin encapsulated in nanoparticles could specifically target BACH1, thereby down regulating CD47; (d) hemin had a synergistic effect with DDP, thus augmenting the chemotherapy. Altogether, mitochondria-targeted nanoparticles H/D@FA–CaP–NPs promoted tumor apoptosis and mobilized phagocytosis to treat tumor, providing a novel scheme for clinical treatment of cisplatin-resistant ovarian carcinoma.
The platinum-based chemotherapy is a routine strategy for the treatment of ovarian cancer, while it is prone to chemoresistance in clinical, which hinders the treatment. Therefore, it is urgently needed to elucidate the underlying mechanism of drug resistance and form the appropriate strategy. The sequencing results showed that cisplatin (DDP) resistant ovarian cancer overexpressed BTB and CNC homology 1 (BACH1), and up-regulated the “don't eat me” signal CD47. We identified that hemin, a BACH1 inhibitor, could effectively down-regulate BACH1 and simultaneously inhibit CD47. Moreover, hemin has a synergistic effect with DDP. We designed a pH-responsive nanoparticle (H/D@FA–CaP–NPs) in which folic acid (FA) ensured targeting of ovarian cancer cells, while hemin inhibited BACH1 as well as down-regulated CD47, achieving the promotion of apoptosis of tumor cells and inducing phagocytosis of tumors by macrophages. Moreover, hemin has a synergistic effect with DDP to promote apoptosis of tumor cells. Structurally, hemin and DDP was encapsulated within hydrophobic 1,2-distearoyl-sn-glycero-3-phospho-ethanolamine (DSPE) to form a tight core, and hydrophilic polyethylene glycol 2000 (PEG2000) and calcium phosphate (CaP) formed the outside shell, and FA was modified on the surface of nanoparticles. In terms of function, (a) FA enhanced the active targeting of nanoparticles to tumors; (b) NPs targeted mitochondria to induce reactive oxygen species (ROS) production; (c) hemin encapsulated in nanoparticles could specifically target BACH1, thereby down regulating CD47; (d) hemin had a synergistic effect with DDP, thus augmenting the chemotherapy. Altogether, mitochondria-targeted nanoparticles H/D@FA–CaP–NPs promoted tumor apoptosis and mobilized phagocytosis to treat tumor, providing a novel scheme for clinical treatment of cisplatin-resistant ovarian carcinoma.
2024, 35(5): 108891
doi: 10.1016/j.cclet.2023.108891
Abstract:
A novel citric acid-modified chitosan gel (CSCA) was synthesized through a simple one-step process and was used to extract thorium ions from wastewater. The CSCA samples with varying chemical compositions were analyzed using SEM with mapping EDS, FT-IR, and static water contact angle measurements, and their adsorption behaviors were studied in detail. The results showed that the adsorption performance of CSCA improves with the increase of CA content in the sample. CSCA possesses an impressive capacity for thorium adsorption of 279.8 mg/g. Furthermore, it showed an ultra-fast adsorption rate and reached equilibrium within 30 min. In terms of recyclability, the CSCA still retained more than 86% of its initial adsorption capacity after 6 cycles of reuse. Density functional theory (DFT) analysis reveals that the good selectivity of this material towards thorium ions should be attributed to the high density of adsorption sites and strong interaction between carboxyl groups and thorium ions. This work could be beneficial in the design and synthesis of new polymer materials for extracting thorium.
A novel citric acid-modified chitosan gel (CSCA) was synthesized through a simple one-step process and was used to extract thorium ions from wastewater. The CSCA samples with varying chemical compositions were analyzed using SEM with mapping EDS, FT-IR, and static water contact angle measurements, and their adsorption behaviors were studied in detail. The results showed that the adsorption performance of CSCA improves with the increase of CA content in the sample. CSCA possesses an impressive capacity for thorium adsorption of 279.8 mg/g. Furthermore, it showed an ultra-fast adsorption rate and reached equilibrium within 30 min. In terms of recyclability, the CSCA still retained more than 86% of its initial adsorption capacity after 6 cycles of reuse. Density functional theory (DFT) analysis reveals that the good selectivity of this material towards thorium ions should be attributed to the high density of adsorption sites and strong interaction between carboxyl groups and thorium ions. This work could be beneficial in the design and synthesis of new polymer materials for extracting thorium.
2024, 35(5): 108903
doi: 10.1016/j.cclet.2023.108903
Abstract:
Nonradical oxidation has received wide attention in advanced oxidation processes for environmental remediation. Understanding the relationship between material characteristics and their ability to initiate nonradical oxidation processes is the key to better material design and performance. Herein, a novel titanium-based metal-organic framework MIL-125-Ti/H2O2 system was established to show a highly selective degradation efficacy toward tetracycline antibiotics. MIL-125-Ti with the abundance of TiO6 octahedra units was found to effectively activate H2O2 under dark conditions by forming an oxidative Ti-peroxo complex. The presence of the Ti-peroxo complex, confirmed by UV-visible spectrophotometer, fourier transform infrared spectroscopy, and X-ray photoelectron spectroscopy characterizations, showed superior degradation (> 95% removal rate) of oxytetracycline hydrochloride (OTC), doxycycline hydrochloride, chlortetracycline hydrochloride, and tetracycline. Density functional theory calculations were performed to assist the elucidation on the mechanism of H2O2 activation and antibiotics degradation. The MIL-125-Ti/H2O2 system was highly resistant to halogens and background organics, and could well maintain its original catalytic activity in actual water matrices. It retained the ability to degrade 75% of OTC within ten test cycles. This study provides new insight into the nonradical oxidation process initiated by the unique Ti-peroxo complex of Ti-based MOF.
Nonradical oxidation has received wide attention in advanced oxidation processes for environmental remediation. Understanding the relationship between material characteristics and their ability to initiate nonradical oxidation processes is the key to better material design and performance. Herein, a novel titanium-based metal-organic framework MIL-125-Ti/H2O2 system was established to show a highly selective degradation efficacy toward tetracycline antibiotics. MIL-125-Ti with the abundance of TiO6 octahedra units was found to effectively activate H2O2 under dark conditions by forming an oxidative Ti-peroxo complex. The presence of the Ti-peroxo complex, confirmed by UV-visible spectrophotometer, fourier transform infrared spectroscopy, and X-ray photoelectron spectroscopy characterizations, showed superior degradation (> 95% removal rate) of oxytetracycline hydrochloride (OTC), doxycycline hydrochloride, chlortetracycline hydrochloride, and tetracycline. Density functional theory calculations were performed to assist the elucidation on the mechanism of H2O2 activation and antibiotics degradation. The MIL-125-Ti/H2O2 system was highly resistant to halogens and background organics, and could well maintain its original catalytic activity in actual water matrices. It retained the ability to degrade 75% of OTC within ten test cycles. This study provides new insight into the nonradical oxidation process initiated by the unique Ti-peroxo complex of Ti-based MOF.
2024, 35(5): 108904
doi: 10.1016/j.cclet.2023.108904
Abstract:
Targeted construction of new covalent organic frameworks (COFs) with specific purposes and rationalities to build colorimetric assay platform for environmental pollutant monitoring have attracted increasing interest. However, it is still challenging due to lack of available coordination sites inside COFs pores and only a slight bonding ability for anchoring metal. In this work, a two-dimensional (2D) COFs (termed as Tz-COF) with high crystallinity, excellent chemical stability, and abundant sulfur coordination in its skeletons was synthesized and used for the confined growth of Au NPs. It was found that the Au NPs showed significant dispersibility for the support of Tz-COF. The proposed Tz-COF@Au NPs possessed outstanding Hg2+-activated peroxidase-like activity benefited from physicochemical properties of gold amalgam and synergistic effect between COFs and Au NPs to oxidize chromogenic substrate. Based on highly efficient activity and distinctive color evolution, the strategy for detecting Hg2+ was developed and successfully applied to determine the content of Hg2+ in real environmental samples. This work manifests that a potential strategy to establish a colorimetric assay platform for environmental pollutant monitoring based on the targeted manufacturing of novel COFs with specific functions.
Targeted construction of new covalent organic frameworks (COFs) with specific purposes and rationalities to build colorimetric assay platform for environmental pollutant monitoring have attracted increasing interest. However, it is still challenging due to lack of available coordination sites inside COFs pores and only a slight bonding ability for anchoring metal. In this work, a two-dimensional (2D) COFs (termed as Tz-COF) with high crystallinity, excellent chemical stability, and abundant sulfur coordination in its skeletons was synthesized and used for the confined growth of Au NPs. It was found that the Au NPs showed significant dispersibility for the support of Tz-COF. The proposed Tz-COF@Au NPs possessed outstanding Hg2+-activated peroxidase-like activity benefited from physicochemical properties of gold amalgam and synergistic effect between COFs and Au NPs to oxidize chromogenic substrate. Based on highly efficient activity and distinctive color evolution, the strategy for detecting Hg2+ was developed and successfully applied to determine the content of Hg2+ in real environmental samples. This work manifests that a potential strategy to establish a colorimetric assay platform for environmental pollutant monitoring based on the targeted manufacturing of novel COFs with specific functions.
2024, 35(5): 108906
doi: 10.1016/j.cclet.2023.108906
Abstract:
Rhodium(Ⅲ)-catalyzed CH couplings of arenes with alkenes are among the most powerful methods for CC bond formation. For these transformations, subtle manipulation of ancillary ligands can lead to dramatic changes in reactivity and selectivity. However, detailed mechanistic studies concerning the ligand effects are rare. In this study, we investigated the origin of ligand-controlled product-selectivity in rhodium(Ⅲ)-catalyzed CH couplings of arenes with alkenes, using a series of well-defined [CpXRhⅢ] complexes that feature electronically or sterically distinct CpX (Cp (η5-C5H5), CpCF3 (η5-C5Me4CF3) and Cp* (η5-C5Me5)) ligands. A combination of experimental and theoretical investigations showed that (i) rhodium hydride species containing the electron rich Cp* ligand can undergo reinsertion of the alkene, thereby allowing rhodium-walking, (ii) rhodium hydride species involving the electron-deficient Cp or CpCF3 ligands prefer reductive elimination rather than alkene insertion. These findings offer valuable insights on future rational catalyst design for selective arene–alkene cross coupling reactions.
Rhodium(Ⅲ)-catalyzed CH couplings of arenes with alkenes are among the most powerful methods for CC bond formation. For these transformations, subtle manipulation of ancillary ligands can lead to dramatic changes in reactivity and selectivity. However, detailed mechanistic studies concerning the ligand effects are rare. In this study, we investigated the origin of ligand-controlled product-selectivity in rhodium(Ⅲ)-catalyzed CH couplings of arenes with alkenes, using a series of well-defined [CpXRhⅢ] complexes that feature electronically or sterically distinct CpX (Cp (η5-C5H5), CpCF3 (η5-C5Me4CF3) and Cp* (η5-C5Me5)) ligands. A combination of experimental and theoretical investigations showed that (i) rhodium hydride species containing the electron rich Cp* ligand can undergo reinsertion of the alkene, thereby allowing rhodium-walking, (ii) rhodium hydride species involving the electron-deficient Cp or CpCF3 ligands prefer reductive elimination rather than alkene insertion. These findings offer valuable insights on future rational catalyst design for selective arene–alkene cross coupling reactions.
2024, 35(5): 108939
doi: 10.1016/j.cclet.2023.108939
Abstract:
Catalytic enantioselective alkenylation is an efficient method to construct chiral alkene molecules, but the asymmetric alkenylation of simple alkenes catalyzed by metal-free catalysts remains an elusive challenge. Herein, we reported an asymmetric alkenylation of benzoxazinones with diarylethylenes by utilizing a B(C6F5)3/chiral phosphoric acid catalyst. A broad of benzoxazinones and diarylethylenes with electron-withdrawing and electron-donating groups were tolerated (up to 95% yield and 97.5:2.5 e.r.) in the methodology under mild reaction conditions. Moreover, the synthetic utility was confirmed by the scaled-up reaction and transformations of the products. The mechanism was preliminarily explored by control reactions, nonlinear effect experiment and DFT calculations.
Catalytic enantioselective alkenylation is an efficient method to construct chiral alkene molecules, but the asymmetric alkenylation of simple alkenes catalyzed by metal-free catalysts remains an elusive challenge. Herein, we reported an asymmetric alkenylation of benzoxazinones with diarylethylenes by utilizing a B(C6F5)3/chiral phosphoric acid catalyst. A broad of benzoxazinones and diarylethylenes with electron-withdrawing and electron-donating groups were tolerated (up to 95% yield and 97.5:2.5 e.r.) in the methodology under mild reaction conditions. Moreover, the synthetic utility was confirmed by the scaled-up reaction and transformations of the products. The mechanism was preliminarily explored by control reactions, nonlinear effect experiment and DFT calculations.
2024, 35(5): 108940
doi: 10.1016/j.cclet.2023.108940
Abstract:
As key biomarkers, amyloid-β (Aβ) plaques are frequently used to diagnose Alzheimer's disease (AD). Although fluorescence imaging has proven to be effective in detecting these plaques, the gold standard probe thioflavin T (ThT), used for Aβ aggregates, cannot be applied in vivo owing to its invasive nature. Therefore, the development of novel fluorescent probes capable of identifying Aβ plaques in situ is necessary. Based on the ThT structure, two π-conjugated heterocyclic D-π-A probes were designed bearing the hydroxytricyanopyrrole acceptor and N,N-dimethylaminophenyl donor. These probes exhibited red to near-infrared fluorescence emission (λmax = 732 nm), large Stokes shifts (>100 nm), exceptional signal-to-noise ratio, rapid response (<30 s), and high binding affinity (NT-HTCP = 33.32 nmol/L; NF-HTCP = 53.35 nmol/L) for Aβ aggregates. As the best candidate, NT-HTCP was used for in situ imaging of Aβ plaques in AD mouse models. Furthermore, in vivo research demonstrated that NT-HTCP could cross the blood–brain barrier and continue imaging the Aβ plaques with a good signal-to-noise ratio. Additionally, the outcomes of the docking computations helped guide the development of the Aβ probes. This study expands the family of N,N-dimethylaminophenyl-based Aβ-sensitive fluorophores, with NT-HTCP emerging as a highly promising imaging agent.
As key biomarkers, amyloid-β (Aβ) plaques are frequently used to diagnose Alzheimer's disease (AD). Although fluorescence imaging has proven to be effective in detecting these plaques, the gold standard probe thioflavin T (ThT), used for Aβ aggregates, cannot be applied in vivo owing to its invasive nature. Therefore, the development of novel fluorescent probes capable of identifying Aβ plaques in situ is necessary. Based on the ThT structure, two π-conjugated heterocyclic D-π-A probes were designed bearing the hydroxytricyanopyrrole acceptor and N,N-dimethylaminophenyl donor. These probes exhibited red to near-infrared fluorescence emission (λmax = 732 nm), large Stokes shifts (>100 nm), exceptional signal-to-noise ratio, rapid response (<30 s), and high binding affinity (NT-HTCP = 33.32 nmol/L; NF-HTCP = 53.35 nmol/L) for Aβ aggregates. As the best candidate, NT-HTCP was used for in situ imaging of Aβ plaques in AD mouse models. Furthermore, in vivo research demonstrated that NT-HTCP could cross the blood–brain barrier and continue imaging the Aβ plaques with a good signal-to-noise ratio. Additionally, the outcomes of the docking computations helped guide the development of the Aβ probes. This study expands the family of N,N-dimethylaminophenyl-based Aβ-sensitive fluorophores, with NT-HTCP emerging as a highly promising imaging agent.
2024, 35(5): 108949
doi: 10.1016/j.cclet.2023.108949
Abstract:
Mechanochromophores based on bichromic molecular switches, such as bis-naphthopyanes, allow multimodal mechanochromic behavior beyond the typical binary response from single chromophores, which is important for distinguishing between multiple stress states through discrete changes in color. Spontaneously generated persistent and distinguishable multi-colors from activated bis-naphthopyanes remain challenging. And the versatility of bis-mechanophore design for advanced optical molecular systems and the fundamental insights into the corresponding mechano-reactivity are not enough. Here, we identify a dihydroanthracene bridged bis-naphthopyrans as a multimodal mechanochromophore in polymers. Bridging two pyrans with the sterically constrained dihydroanthracene is helpful to control the steric effect for the favorable formation of a distinctly appreciable bis-merocyanine (bis-MC) product. By varying the length of the polymer chains, the force delivered to the mechanophore is modulated, resulting in a gradient change in the relative distribution of two distinctly colored MC products and a multicolor mechanochromism. Mechanical activation of this bis-naphthopyanes proceeds via a mechanistically distinct pathway compared to the photochemical process. In addition, the bulk films can also achieve pronounced color changes when subjected to mechanical force. This study thus further expands the molecular diversity of mechanochromophores and tune the multimodal switch properties of bis-naphthopyrans based polymers.
Mechanochromophores based on bichromic molecular switches, such as bis-naphthopyanes, allow multimodal mechanochromic behavior beyond the typical binary response from single chromophores, which is important for distinguishing between multiple stress states through discrete changes in color. Spontaneously generated persistent and distinguishable multi-colors from activated bis-naphthopyanes remain challenging. And the versatility of bis-mechanophore design for advanced optical molecular systems and the fundamental insights into the corresponding mechano-reactivity are not enough. Here, we identify a dihydroanthracene bridged bis-naphthopyrans as a multimodal mechanochromophore in polymers. Bridging two pyrans with the sterically constrained dihydroanthracene is helpful to control the steric effect for the favorable formation of a distinctly appreciable bis-merocyanine (bis-MC) product. By varying the length of the polymer chains, the force delivered to the mechanophore is modulated, resulting in a gradient change in the relative distribution of two distinctly colored MC products and a multicolor mechanochromism. Mechanical activation of this bis-naphthopyanes proceeds via a mechanistically distinct pathway compared to the photochemical process. In addition, the bulk films can also achieve pronounced color changes when subjected to mechanical force. This study thus further expands the molecular diversity of mechanochromophores and tune the multimodal switch properties of bis-naphthopyrans based polymers.
2024, 35(5): 108953
doi: 10.1016/j.cclet.2023.108953
Abstract:
The dynamic RNA modifications have been viewed as new posttranscriptional regulator in modulating gene expression as well as in a broad range of physiological processes. N1-methyladenosine (m1A) is one of the most prevalent modifications existing in multiple types of RNAs. In-depth investigation of the functions of m1A requires the site-specific assessment of m1A stoichiometry in RNA. Herein, we established a demethylase-assisted method (DA-m1A) for the site-specific detection and quantification of m1A in RNA. N1-methyl group in m1A could result in the stalling of reverse transcription at m1A site, thus producing the truncated cDNA. E. coli AlkB is a demethylase that can demethylate m1A to produce adenine in RNA, thus generating full-length cDNA from AlkB-treated RNA. Evaluation of the produced amounts of full-length cDNA by quantitative real-time PCR can achieve the site-specific detection and quantification of m1A in RNA. With the DA-m1A method, we examined and successfully confirmed the previously well-characterized m1A sites in various types of RNAs with low false positive rate. In addition, we found that the level of m1A was significantly decreased at the bromodomain containing 2 (BRD2) mRNA position 1674 and CST telomere replication complex component 1 (CTC1) mRNA position 5643 in human hepatocellular carcinoma tissues. The results suggest that these two m1A sites in mRNA may be involved in liver tumorigenesis. Taken together, the DA-m1A method is simple and enables the rapid, cost-effective, and site-specific detection and quantification of m1A in RNA, which provides a valuable tool to decipher the functions of m1A in human diseases.
The dynamic RNA modifications have been viewed as new posttranscriptional regulator in modulating gene expression as well as in a broad range of physiological processes. N1-methyladenosine (m1A) is one of the most prevalent modifications existing in multiple types of RNAs. In-depth investigation of the functions of m1A requires the site-specific assessment of m1A stoichiometry in RNA. Herein, we established a demethylase-assisted method (DA-m1A) for the site-specific detection and quantification of m1A in RNA. N1-methyl group in m1A could result in the stalling of reverse transcription at m1A site, thus producing the truncated cDNA. E. coli AlkB is a demethylase that can demethylate m1A to produce adenine in RNA, thus generating full-length cDNA from AlkB-treated RNA. Evaluation of the produced amounts of full-length cDNA by quantitative real-time PCR can achieve the site-specific detection and quantification of m1A in RNA. With the DA-m1A method, we examined and successfully confirmed the previously well-characterized m1A sites in various types of RNAs with low false positive rate. In addition, we found that the level of m1A was significantly decreased at the bromodomain containing 2 (BRD2) mRNA position 1674 and CST telomere replication complex component 1 (CTC1) mRNA position 5643 in human hepatocellular carcinoma tissues. The results suggest that these two m1A sites in mRNA may be involved in liver tumorigenesis. Taken together, the DA-m1A method is simple and enables the rapid, cost-effective, and site-specific detection and quantification of m1A in RNA, which provides a valuable tool to decipher the functions of m1A in human diseases.
2024, 35(5): 108971
doi: 10.1016/j.cclet.2023.108971
Abstract:
The present study reported fabrication of novel carbon quantum dots-MnFe2O4@ZIF-8 (CQDs-MFO@ZIF-8) by using co-precipitation hydrothermal method for activation of peroxydisulfate (PDS) to degrade bisphenol A (BPA), one of important emerging organic pollutants in water environment. CQDs-MFO@ZIF-8 served as a highly efficient thermal activated PDS catalyst with high catalytic degradation efficiency, reusability and stability. The catalyst achieved almost completely removal of 20.0 mg/L BPA within 5.0 min, and the degradation efficiency remained higher than 83% after 5 consecutive cycles. Free radicals (•OH, SO4•− and •O2−) and non-free radicals (1O2) were generated in the thermal PDS-activation system, in which singlet oxygen (1O2) played a dominant role in the degradation of BPA. The potential toxicity of BPA degradation intermediates was analyzed upon the culture of E. coli and Chlorella sorokiniana by using Ecological Structure-Activity Relationship Model (ECOSAR) program. The catalytic performances of BPA degradation by CQDs-MFO@ZIF-8 were evaluated for treatment of different practical water samples to further verify the feasibility of practical applications. This study provides proof-in-concept demonstration of new nanomaterials for enhanced catalytic water decontamination.
The present study reported fabrication of novel carbon quantum dots-MnFe2O4@ZIF-8 (CQDs-MFO@ZIF-8) by using co-precipitation hydrothermal method for activation of peroxydisulfate (PDS) to degrade bisphenol A (BPA), one of important emerging organic pollutants in water environment. CQDs-MFO@ZIF-8 served as a highly efficient thermal activated PDS catalyst with high catalytic degradation efficiency, reusability and stability. The catalyst achieved almost completely removal of 20.0 mg/L BPA within 5.0 min, and the degradation efficiency remained higher than 83% after 5 consecutive cycles. Free radicals (•OH, SO4•− and •O2−) and non-free radicals (1O2) were generated in the thermal PDS-activation system, in which singlet oxygen (1O2) played a dominant role in the degradation of BPA. The potential toxicity of BPA degradation intermediates was analyzed upon the culture of E. coli and Chlorella sorokiniana by using Ecological Structure-Activity Relationship Model (ECOSAR) program. The catalytic performances of BPA degradation by CQDs-MFO@ZIF-8 were evaluated for treatment of different practical water samples to further verify the feasibility of practical applications. This study provides proof-in-concept demonstration of new nanomaterials for enhanced catalytic water decontamination.
2024, 35(5): 108975
doi: 10.1016/j.cclet.2023.108975
Abstract:
As the most common pathological type of nephrotic syndrome, membranous nephropathy (MN) presents diversity in progression trends, facing severe complications. The precise discrimination of MN from healthy people, other types of nephrotic syndrome or those with therapeutic remission has always been huge challenge in clinics, not to mention comprehensive individualized monitoring relied on minimally invasive molecular detection means. Herein, we construct a functionalized pore architecture to couple with machine learning to aid all-round peptidome enrichment and data profiling from hundreds of human serum samples, and finally establish a set of defined peptide panel consisting of 12 specific feature signals. In addition to the realization of above-mentioned precise discrimination with more than 97% of sensitivity, 88% of accuracy and f1 score, the simultaneously comprehensive individualized monitoring for MN can also be achieved, including conventionally screening diagnosis, congeneric distinction and prognostic evaluation. This work greatly advances the development of peptidome data-driven individualized monitoring means for complex diseases and undoubtedly inspire more devotion into molecular detection field.
As the most common pathological type of nephrotic syndrome, membranous nephropathy (MN) presents diversity in progression trends, facing severe complications. The precise discrimination of MN from healthy people, other types of nephrotic syndrome or those with therapeutic remission has always been huge challenge in clinics, not to mention comprehensive individualized monitoring relied on minimally invasive molecular detection means. Herein, we construct a functionalized pore architecture to couple with machine learning to aid all-round peptidome enrichment and data profiling from hundreds of human serum samples, and finally establish a set of defined peptide panel consisting of 12 specific feature signals. In addition to the realization of above-mentioned precise discrimination with more than 97% of sensitivity, 88% of accuracy and f1 score, the simultaneously comprehensive individualized monitoring for MN can also be achieved, including conventionally screening diagnosis, congeneric distinction and prognostic evaluation. This work greatly advances the development of peptidome data-driven individualized monitoring means for complex diseases and undoubtedly inspire more devotion into molecular detection field.
2024, 35(5): 108980
doi: 10.1016/j.cclet.2023.108980
Abstract:
Borylation of 1,3-enynes with bis(boronate) compounds often ends up with the formation of hydroborylated products, leaving the diborylation of 1,3-enynes for the formation of 1,4-diborylated allenes to be challenging. Herein, a copper-catalyzed chemo-, regio-, and stereo-selective diborylation of 1,3-enynes for the efficient construction of 1,4-diborylated allenes under base-free conditions was reported. A wide range of 1,3-enynes bearing various functional groups can participant in the reaction and afforded the corresponding 1,4-diborylated allenes in good to excellent yields, which was enabled by the protocol of Bpin to BF3K conversion. the borylcopper species was supposed to selectively attack the C–C triple bond of the 1,3-enynes.
Borylation of 1,3-enynes with bis(boronate) compounds often ends up with the formation of hydroborylated products, leaving the diborylation of 1,3-enynes for the formation of 1,4-diborylated allenes to be challenging. Herein, a copper-catalyzed chemo-, regio-, and stereo-selective diborylation of 1,3-enynes for the efficient construction of 1,4-diborylated allenes under base-free conditions was reported. A wide range of 1,3-enynes bearing various functional groups can participant in the reaction and afforded the corresponding 1,4-diborylated allenes in good to excellent yields, which was enabled by the protocol of Bpin to BF3K conversion. the borylcopper species was supposed to selectively attack the C–C triple bond of the 1,3-enynes.
2024, 35(5): 109032
doi: 10.1016/j.cclet.2023.109032
Abstract:
The virtual cocrystal screening approach based on molecular electrostatic potential surface (MEPS) maps is a fast and feasible computational method to estimate the probability of cocrystal formation by calculating the difference in the interaction site pairing energies of monomers and that of their assemblies prior to experimental screening. In this paper, we report 12 cocrystal forms of temozolomide with mono-, di-, and trihydroxy benzoic acids, namely, 3-hydroxy-, 2,4-dihydroxy-, 2,5-dihydroxy-, 2,6-dihydroxy-, 3,4-dihydroxy-, and 3,4,5-trihydroxy-benzoic acids, as well as benzoic acid, as pharmaceutical coformers for the first time. 10 single crystals out of the 12 cocrystal forms were obtained and unequivocally determined by single-crystal X-ray diffraction, which clarified spatial arrangements, molecular conformations, and supramolecular synthons. MEPS further gains some insights into the sites of hydrogen bonding interactions for exploring combination patterns in these assemblies. Modulated stability of TMZ was successfully achieved by cocrystallization with these acids.
The virtual cocrystal screening approach based on molecular electrostatic potential surface (MEPS) maps is a fast and feasible computational method to estimate the probability of cocrystal formation by calculating the difference in the interaction site pairing energies of monomers and that of their assemblies prior to experimental screening. In this paper, we report 12 cocrystal forms of temozolomide with mono-, di-, and trihydroxy benzoic acids, namely, 3-hydroxy-, 2,4-dihydroxy-, 2,5-dihydroxy-, 2,6-dihydroxy-, 3,4-dihydroxy-, and 3,4,5-trihydroxy-benzoic acids, as well as benzoic acid, as pharmaceutical coformers for the first time. 10 single crystals out of the 12 cocrystal forms were obtained and unequivocally determined by single-crystal X-ray diffraction, which clarified spatial arrangements, molecular conformations, and supramolecular synthons. MEPS further gains some insights into the sites of hydrogen bonding interactions for exploring combination patterns in these assemblies. Modulated stability of TMZ was successfully achieved by cocrystallization with these acids.
2024, 35(5): 109033
doi: 10.1016/j.cclet.2023.109033
Abstract:
The 2-hydroxy-4-methoxybenzyl (Hmb) backbone modification can prevent amide bond-mediated side-reactions (e.g., aspartimide formation, peptide aggregation) by installing the removable Hmb group into a peptide bond, thus improving the synthesis of long and challenging peptides and proteins. However, its use is largely precluded by the limited Hmb's installation sites. In this report, an improved installation of Hmb (iHmb) method was developed to achieve the flexible installation and the convenient removal of Hmb. The iHmb method involves two critical steps: (1) oxidative diazotization of the readily installed 2-hydroxy-4-methoxy-5-amino-benzyl (Hmab) to give 2-hydroxy-4-methoxy-5-diazonium-benzyl (Hmdab) by combining soamyl nitrite (IAN)/HBF4, and (2) reductive elimination of Hmdab to give the desired Hmb by 1,2-ethanedithiol (EDT). The iHmb method enables the installation of Hmb at any primary amino acid including the highly sterically hindered amino acids (e.g., valine and isoleucine). The practicality and utility of the iHmb method was demonstrated by one-shot solid-phase synthesis of a challenging aspartimide-prone peptide, the mirror-image version of a hydrophobic peptide and a long-chain peptide up to 76-residue. Furthermore, the iHmb method can be utilized to facilitate chemical protein ligation, as exemplified by the synthesis of the single-spanning membrane protein sarcolipin. The iHmb method expands the toolkit for peptide synthesis and ligation and facilitates the preparation of peptides/proteins.
The 2-hydroxy-4-methoxybenzyl (Hmb) backbone modification can prevent amide bond-mediated side-reactions (e.g., aspartimide formation, peptide aggregation) by installing the removable Hmb group into a peptide bond, thus improving the synthesis of long and challenging peptides and proteins. However, its use is largely precluded by the limited Hmb's installation sites. In this report, an improved installation of Hmb (iHmb) method was developed to achieve the flexible installation and the convenient removal of Hmb. The iHmb method involves two critical steps: (1) oxidative diazotization of the readily installed 2-hydroxy-4-methoxy-5-amino-benzyl (Hmab) to give 2-hydroxy-4-methoxy-5-diazonium-benzyl (Hmdab) by combining soamyl nitrite (IAN)/HBF4, and (2) reductive elimination of Hmdab to give the desired Hmb by 1,2-ethanedithiol (EDT). The iHmb method enables the installation of Hmb at any primary amino acid including the highly sterically hindered amino acids (e.g., valine and isoleucine). The practicality and utility of the iHmb method was demonstrated by one-shot solid-phase synthesis of a challenging aspartimide-prone peptide, the mirror-image version of a hydrophobic peptide and a long-chain peptide up to 76-residue. Furthermore, the iHmb method can be utilized to facilitate chemical protein ligation, as exemplified by the synthesis of the single-spanning membrane protein sarcolipin. The iHmb method expands the toolkit for peptide synthesis and ligation and facilitates the preparation of peptides/proteins.
2024, 35(5): 109036
doi: 10.1016/j.cclet.2023.109036
Abstract:
Antibiotic abuse now poses a grave threat to global ecology and bestirs public concerns about the residue issue in daily necessities. The traceability measurements along supply chain or logistic circulation have become increasingly essential given the labile nature of diverse synthetic residuals on site. In an attempt to answer this urgency, here a miniaturized fluorometric aptasensor prototype was contrived that catered to the point-of-care screening norm for two typical additives: chloramphenicol and enrofloxacin. The key target-indicating module worked in vitro based on the competitive binding-induced fluorescence recovery of fluorescein-labeled aptamers, which were photobleached beforehand in the format of double helix on burlike nanogold carriers. The “prickly” geometry of the latter not just enriched the capture probes at preferentially substrate-accessible spires; but also contributed to a tip-enhanced surface plasmon effect, sensitizing the signal-on during the duplex dissociation even at nanomolar threshold of the analytes. On the other hand, to encompass a full portable, a set of optical devices were mounted within a 3D-printed cartridge (adaptor) to converge the light beam and route it towards the detector, for which the smartphone camera came up in handy with a home-developed App for calibrating the emissive brightness. Enlightened by the high-dynamic-range compression, an imaging diagnostic algorithm was built in to grid and digitize each slide in the album for augmented detection performance. Thus, a novel bio-to-silico integration was invented that capable of in situ rapid reporting on the antibiotic presence with high sensitivity and selectivity. Further field practices in spiked milk on sales proved the precision and rudimentary feasibility of the well-assembled model of appliance, thus holding nice prospects in nonexpert (e.g., family and local community) utilities for foodborne antibiotic identification.
Antibiotic abuse now poses a grave threat to global ecology and bestirs public concerns about the residue issue in daily necessities. The traceability measurements along supply chain or logistic circulation have become increasingly essential given the labile nature of diverse synthetic residuals on site. In an attempt to answer this urgency, here a miniaturized fluorometric aptasensor prototype was contrived that catered to the point-of-care screening norm for two typical additives: chloramphenicol and enrofloxacin. The key target-indicating module worked in vitro based on the competitive binding-induced fluorescence recovery of fluorescein-labeled aptamers, which were photobleached beforehand in the format of double helix on burlike nanogold carriers. The “prickly” geometry of the latter not just enriched the capture probes at preferentially substrate-accessible spires; but also contributed to a tip-enhanced surface plasmon effect, sensitizing the signal-on during the duplex dissociation even at nanomolar threshold of the analytes. On the other hand, to encompass a full portable, a set of optical devices were mounted within a 3D-printed cartridge (adaptor) to converge the light beam and route it towards the detector, for which the smartphone camera came up in handy with a home-developed App for calibrating the emissive brightness. Enlightened by the high-dynamic-range compression, an imaging diagnostic algorithm was built in to grid and digitize each slide in the album for augmented detection performance. Thus, a novel bio-to-silico integration was invented that capable of in situ rapid reporting on the antibiotic presence with high sensitivity and selectivity. Further field practices in spiked milk on sales proved the precision and rudimentary feasibility of the well-assembled model of appliance, thus holding nice prospects in nonexpert (e.g., family and local community) utilities for foodborne antibiotic identification.
2024, 35(5): 109037
doi: 10.1016/j.cclet.2023.109037
Abstract:
Electrocatalytic synthesis of ammonia as an environment-friendly and sustainable development method has received widespread attention in recent years. Two-dimensional (2D) materials are a promising catalyst for ammonia synthesis due to their large surface area. In this work, we have constructed a series of 2D metal borides (MBenes) with transition metal (TM) defects (TMd-MBenes) and comprehensively calculated the reactivity of electrocatalytic synthesis of ammonia-based on density functional theory. The results have demonstrated that the TMd-MBenes can effectively activate nitrogen oxide (NO) and nitrogen (N2) molecules thermodynamically. Particularly interesting, the co-chemisorption of O atoms, dissociated from NO, can facilitate the spilled of the inert N2 molecules into single N atoms, which can further hydrogenate into ammonia easily with an ultralow limiting potential of 0.59 V on TMd-MnB. Our research has not only provided clues for catalyst design for experimental study but also paved the way for the industrial application of electrocatalytic ammonia synthesis.
Electrocatalytic synthesis of ammonia as an environment-friendly and sustainable development method has received widespread attention in recent years. Two-dimensional (2D) materials are a promising catalyst for ammonia synthesis due to their large surface area. In this work, we have constructed a series of 2D metal borides (MBenes) with transition metal (TM) defects (TMd-MBenes) and comprehensively calculated the reactivity of electrocatalytic synthesis of ammonia-based on density functional theory. The results have demonstrated that the TMd-MBenes can effectively activate nitrogen oxide (NO) and nitrogen (N2) molecules thermodynamically. Particularly interesting, the co-chemisorption of O atoms, dissociated from NO, can facilitate the spilled of the inert N2 molecules into single N atoms, which can further hydrogenate into ammonia easily with an ultralow limiting potential of 0.59 V on TMd-MnB. Our research has not only provided clues for catalyst design for experimental study but also paved the way for the industrial application of electrocatalytic ammonia synthesis.
2024, 35(5): 109055
doi: 10.1016/j.cclet.2023.109055
Abstract:
Herein, we report the facile synthesis of a highly strained hexabenzocoronene-containing carbon nanoring, cyclo[4]-paraphenylene[2]-2,11-hexabenzocoronenylene ([4,2]CPHBC), as the segment of a [10,10] single-walled carbon nanotube ([10,10]SWNT). [4,2]CPHBC was synthesized based on the platinum-mediated assembly of diborylbiphenyl and diborylhexabenzocoronene, forming a tetranuclear platinum complex, followed by reductive elimination. This nanoring molecule was confirmed by NMR and HR-MS, and its photophysical properties were studied using steady-state and time-resolved spectroscopies. Moreover, the selective supramolecular host-guest interaction between [4,2]CPHBC and C60 was also investigated.
Herein, we report the facile synthesis of a highly strained hexabenzocoronene-containing carbon nanoring, cyclo[4]-paraphenylene[2]-2,11-hexabenzocoronenylene ([4,2]CPHBC), as the segment of a [10,10] single-walled carbon nanotube ([10,10]SWNT). [4,2]CPHBC was synthesized based on the platinum-mediated assembly of diborylbiphenyl and diborylhexabenzocoronene, forming a tetranuclear platinum complex, followed by reductive elimination. This nanoring molecule was confirmed by NMR and HR-MS, and its photophysical properties were studied using steady-state and time-resolved spectroscopies. Moreover, the selective supramolecular host-guest interaction between [4,2]CPHBC and C60 was also investigated.
2024, 35(5): 109076
doi: 10.1016/j.cclet.2023.109076
Abstract:
An efficient synthesis of the electrophilic reagent, S-(1,3-dioxoisoindolin-2-yl)O,O-diethyl phosphorothioate (SDDP) is described. Moreover, the synthetic applications of SDDP wherein the transfer of the SP(O)(OEt)2 moiety occurs were investigated. In this manner, SDDP underwent facile SP(O)(OEt)2 transfer with electron-rich substrates such as ketones, indoles, and thiols to form α-phosphorothiolated ketones, 3-phosphorothiolated indoles and S-phosphorothiolated thioethers, respectively.
An efficient synthesis of the electrophilic reagent, S-(1,3-dioxoisoindolin-2-yl)O,O-diethyl phosphorothioate (SDDP) is described. Moreover, the synthetic applications of SDDP wherein the transfer of the SP(O)(OEt)2 moiety occurs were investigated. In this manner, SDDP underwent facile SP(O)(OEt)2 transfer with electron-rich substrates such as ketones, indoles, and thiols to form α-phosphorothiolated ketones, 3-phosphorothiolated indoles and S-phosphorothiolated thioethers, respectively.
2024, 35(5): 109077
doi: 10.1016/j.cclet.2023.109077
Abstract:
Presented here is a one-pot strategy starting from rationally designed macrocyclic precursors for the diverse construction of sophisticated ultracycles. The type and amount of the base were found to significantly influence the macrocyclization outcome. The use of 4.0 equiv. CsF resulted in ultracycles of both types A and B while the presence of CsF larger than 6.0 equiv. produced only type B ultracycles. Existence of anion template increased the total yields and affected the distribution of the ultracycles. The ultracycles can accommodate large organic dicarboxylates anions via multiple anion–π and hydrogen bonds, and show selectivity to the size-matched heptanedioate (C72−). Based on all possible species and relevant equilibrium constants as well as material and charge balances, a numerical iterative algorithm was developed and applied to fit the association constants of B2H with dicarboxylates from glutarate (C52−) to octanedioate (C82−), which gave association constants up to 103 L/mol.
Presented here is a one-pot strategy starting from rationally designed macrocyclic precursors for the diverse construction of sophisticated ultracycles. The type and amount of the base were found to significantly influence the macrocyclization outcome. The use of 4.0 equiv. CsF resulted in ultracycles of both types A and B while the presence of CsF larger than 6.0 equiv. produced only type B ultracycles. Existence of anion template increased the total yields and affected the distribution of the ultracycles. The ultracycles can accommodate large organic dicarboxylates anions via multiple anion–π and hydrogen bonds, and show selectivity to the size-matched heptanedioate (C72−). Based on all possible species and relevant equilibrium constants as well as material and charge balances, a numerical iterative algorithm was developed and applied to fit the association constants of B2H with dicarboxylates from glutarate (C52−) to octanedioate (C82−), which gave association constants up to 103 L/mol.
2024, 35(5): 109089
doi: 10.1016/j.cclet.2023.109089
Abstract:
The galactomannan from Antrodia cinnamomea (AC) is characterized as one of the important bioactive components that exhibits potential immunostimulatory propriety. The biological function of its corresponding oligosaccharide fragments has not been revealed yet. In this study, we reported the first chemical synthesis of the series of oligosaccharide fragments related to AC galactomannan via the convergent glycosylation strategy. The preliminary immunological evaluation of these synthesized AC oligosaccharides disclosed that the backbone tetrasaccharide 1d showed the best immunomodulatory ability on enhancing proliferation, phagocytosis and cytokines secretion of Raw264.7 macrophages in vitro, indicating its immense potential as an immunostimulant candidate.
The galactomannan from Antrodia cinnamomea (AC) is characterized as one of the important bioactive components that exhibits potential immunostimulatory propriety. The biological function of its corresponding oligosaccharide fragments has not been revealed yet. In this study, we reported the first chemical synthesis of the series of oligosaccharide fragments related to AC galactomannan via the convergent glycosylation strategy. The preliminary immunological evaluation of these synthesized AC oligosaccharides disclosed that the backbone tetrasaccharide 1d showed the best immunomodulatory ability on enhancing proliferation, phagocytosis and cytokines secretion of Raw264.7 macrophages in vitro, indicating its immense potential as an immunostimulant candidate.
2024, 35(5): 109093
doi: 10.1016/j.cclet.2023.109093
Abstract:
To develop efficient sensitizers for dye-sensitized solar cells (DSSCs), we recently reported doubly concerted companion (DCC) dye XW83 with a wrapped porphyrin sub-dye unit linked to an organic sub-dye unit through a flexible chain, which exhibits panchromatic absorption and excellent anti-aggregation ability. To further improve the absorption, we herein report XW87 and XW88 by inserting an ethynyl group into the organic sub-dye unit of XW83 near the donor and acceptor, respectively. For the corresponding organic dyes Z3 and Z4, the introduced ethynyl group improves their absorption, but induces aggravated charge recombination, leading to lowered power conversion efficiencies (PCEs). Similar to the organic dyes, the introduced ethynyl group improves the absorption of DCC dyes XW87 and XW88 as well. In addition, the ethynyl group near the acceptor of the organic sub-dye unit can be well protected by the long wrapping chains from the porphyrin unit. As a result, XW88 affords the highest JSC (21.84 mA/cm2), VOC (782 mV) and PCE (12.2%) among the DCC dyes. These results provide an effective method for developing efficient DSSC dyes by inserting an ethynyl group at a suitable position of a DCC dye.
To develop efficient sensitizers for dye-sensitized solar cells (DSSCs), we recently reported doubly concerted companion (DCC) dye XW83 with a wrapped porphyrin sub-dye unit linked to an organic sub-dye unit through a flexible chain, which exhibits panchromatic absorption and excellent anti-aggregation ability. To further improve the absorption, we herein report XW87 and XW88 by inserting an ethynyl group into the organic sub-dye unit of XW83 near the donor and acceptor, respectively. For the corresponding organic dyes Z3 and Z4, the introduced ethynyl group improves their absorption, but induces aggravated charge recombination, leading to lowered power conversion efficiencies (PCEs). Similar to the organic dyes, the introduced ethynyl group improves the absorption of DCC dyes XW87 and XW88 as well. In addition, the ethynyl group near the acceptor of the organic sub-dye unit can be well protected by the long wrapping chains from the porphyrin unit. As a result, XW88 affords the highest JSC (21.84 mA/cm2), VOC (782 mV) and PCE (12.2%) among the DCC dyes. These results provide an effective method for developing efficient DSSC dyes by inserting an ethynyl group at a suitable position of a DCC dye.
2024, 35(5): 109119
doi: 10.1016/j.cclet.2023.109119
Abstract:
A water-soluble macrocycle that bears four carboxylate anions has been designed and prepared, which forms a rectangular cavity that can efficiently encapsulate discrete electron-deficient aromatic compounds, including berberine and palmatine. This macrocycle is revealed to be highly biocompatible and able to inhibit the bitter taste of the two drugs.
A water-soluble macrocycle that bears four carboxylate anions has been designed and prepared, which forms a rectangular cavity that can efficiently encapsulate discrete electron-deficient aromatic compounds, including berberine and palmatine. This macrocycle is revealed to be highly biocompatible and able to inhibit the bitter taste of the two drugs.
2024, 35(5): 109121
doi: 10.1016/j.cclet.2023.109121
Abstract:
Protein recognition using host-guest recognition approach is of great interest but has been limited mainly to the protein N-terminal residues. Here, we site-specific incorporated two novel non-canonical amino acids containing supramolecular guest motifs into protein via an expanded genetic code. Through Staudinger reduction reactions, the encoded unnatural residues on protein becoming activated and can be specifically recognized by cucurbit[7]uril (CB[7]) and cucurbit[8]uril (CB[8]). We demonstrated that enzyme containing guest amino acid incorporated near the active site can be reversibly regulated by CB[7] recognition, and CB[8] recognition induces protein dimerization. These amino acids will make useful addition to the supramolecular toolbox for protein targeting using molecular recognition approaches.
Protein recognition using host-guest recognition approach is of great interest but has been limited mainly to the protein N-terminal residues. Here, we site-specific incorporated two novel non-canonical amino acids containing supramolecular guest motifs into protein via an expanded genetic code. Through Staudinger reduction reactions, the encoded unnatural residues on protein becoming activated and can be specifically recognized by cucurbit[7]uril (CB[7]) and cucurbit[8]uril (CB[8]). We demonstrated that enzyme containing guest amino acid incorporated near the active site can be reversibly regulated by CB[7] recognition, and CB[8] recognition induces protein dimerization. These amino acids will make useful addition to the supramolecular toolbox for protein targeting using molecular recognition approaches.
2024, 35(5): 109127
doi: 10.1016/j.cclet.2023.109127
Abstract:
Molecular weaving is a powerful approach to make molecularly woven materials that have showed unprecedented characteristics and properties intrinsically distinct to those of non-woven materials. We here report a facile and efficient approach for the synthesis of 2D woven supramolecular polymers by differentiated self-assembly through orthogonal noncovalent interactions. Importantly, the difference in binding strength of two orthogonal noncovalent interactions can be used to control the process of molecular weaving. Consequently, single-layered 2D woven supramolecular polymers were synthesized and fully characterized by various techniques. This study demonstrates a controllable method for molecular weaving, and will significantly hasten the development of molecularly woven materials.
Molecular weaving is a powerful approach to make molecularly woven materials that have showed unprecedented characteristics and properties intrinsically distinct to those of non-woven materials. We here report a facile and efficient approach for the synthesis of 2D woven supramolecular polymers by differentiated self-assembly through orthogonal noncovalent interactions. Importantly, the difference in binding strength of two orthogonal noncovalent interactions can be used to control the process of molecular weaving. Consequently, single-layered 2D woven supramolecular polymers were synthesized and fully characterized by various techniques. This study demonstrates a controllable method for molecular weaving, and will significantly hasten the development of molecularly woven materials.
2024, 35(5): 109135
doi: 10.1016/j.cclet.2023.109135
Abstract:
Microcystins (MCs), a family of cyclic heptapeptide cyanotoxins, exists in aquatic environment where cyanobacterial bloom happens, which will accumulate in aquatic organisms and transfer through the food chain to higher trophic levels, posing a health risk to both animals and human bodies. Among various MCs, Microcystin-LR (MC-LR) is worthiest studied for its strong toxicity, ubiquity and widespread. Here in this work, iminodiacetic acid (IDA) decorated magnetic mesoporous silica (mSiO2) nanocomposites (Fe3O4@mSiO2-IDA) were facilely synthesized which possessed the merits of large surface area (188.21 m2/g), accessible porosity (2.66 nm), excellent hydrophilicity and rapid responsiveness to magnetic field. Then the composites were successfully employed to the removal process of Microcystin-LR in real water samples followed by Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) analysis, achieving the removal efficiency above 92.5% even after ten recycles of the composites. It provided a potential method for removing MC-LR in aqueous environment with high effectiveness, lower costs and less secondary contamination.
Microcystins (MCs), a family of cyclic heptapeptide cyanotoxins, exists in aquatic environment where cyanobacterial bloom happens, which will accumulate in aquatic organisms and transfer through the food chain to higher trophic levels, posing a health risk to both animals and human bodies. Among various MCs, Microcystin-LR (MC-LR) is worthiest studied for its strong toxicity, ubiquity and widespread. Here in this work, iminodiacetic acid (IDA) decorated magnetic mesoporous silica (mSiO2) nanocomposites (Fe3O4@mSiO2-IDA) were facilely synthesized which possessed the merits of large surface area (188.21 m2/g), accessible porosity (2.66 nm), excellent hydrophilicity and rapid responsiveness to magnetic field. Then the composites were successfully employed to the removal process of Microcystin-LR in real water samples followed by Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) analysis, achieving the removal efficiency above 92.5% even after ten recycles of the composites. It provided a potential method for removing MC-LR in aqueous environment with high effectiveness, lower costs and less secondary contamination.
2024, 35(5): 109145
doi: 10.1016/j.cclet.2023.109145
Abstract:
Imine bonds are among the most explored building motifs in dynamic chemistry, polymers, and materials, and yet, their acid-resistance remains a longstanding issue. Herein we demonstrate a concept of internal protecting groups for improving the kinetic stability of dynamic imine bonds and polymers. Systematic examination of structure-reactivity relationship of a series of aldehydes/imines bearing a neighboring carboxyl allowed uncovering of required structural features for dynamically masking imine bonds with cyclic structures. Mechanistic studies indicated that noncovalent interactions along with sterics control the ring-chain equilibrium and the stability of imine bonds. The incorporation of internal protecting groups into imine polymers further enabled their controlled stability in acidic media. Moreover, a combination of dynamic covalent network and coordination supramolecular network provided a facile means for the modulation of luminescent and mechanical properties of polymers. The strategies and results reported should be beneficial to molecular assemblies, dynamic polymers, biological delivery, and intelligent materials.
Imine bonds are among the most explored building motifs in dynamic chemistry, polymers, and materials, and yet, their acid-resistance remains a longstanding issue. Herein we demonstrate a concept of internal protecting groups for improving the kinetic stability of dynamic imine bonds and polymers. Systematic examination of structure-reactivity relationship of a series of aldehydes/imines bearing a neighboring carboxyl allowed uncovering of required structural features for dynamically masking imine bonds with cyclic structures. Mechanistic studies indicated that noncovalent interactions along with sterics control the ring-chain equilibrium and the stability of imine bonds. The incorporation of internal protecting groups into imine polymers further enabled their controlled stability in acidic media. Moreover, a combination of dynamic covalent network and coordination supramolecular network provided a facile means for the modulation of luminescent and mechanical properties of polymers. The strategies and results reported should be beneficial to molecular assemblies, dynamic polymers, biological delivery, and intelligent materials.
2024, 35(5): 109156
doi: 10.1016/j.cclet.2023.109156
Abstract:
Sulfydryl-contained (-SH) substances including hydrogen sulfide (H2S), cysteine (Cys), homocysteine (Hcy) and glutathione (GSH) play crucial roles in living systems, and their variations are closely associated with various diseases. Herein, we developed a near-infrared intramolecular charge transfer (ICT) based fluorescent probe Y-NBD, achieving detection of Cys/Hcy and H2S with different fluorescent signals (green-red for Cys/Hcy, red for H2S), large Stokes shifts (~100/105 nm or 191 nm) and high signal-background-ratio, but not responding to GSH. Y-NBD was successfully applied to image exogenous/endogenous Cys/Hcy and H2S in various living cancer cells (HeLa, A549, and HepG2) and in zebrafish. It not only visualized the transformation pathway of several thiols in HepG2 cells but also verified that the intestine is the main site for the activation and metabolism of Y-NBD in zebrafish, as well as realized to evaluate the degree of drug-induced liver injury. This work provides a promising tool for imaging Cys/Hcy and H2S in living systems and shows great potency in evaluating drug-induced liver injury and its treatment.
Sulfydryl-contained (-SH) substances including hydrogen sulfide (H2S), cysteine (Cys), homocysteine (Hcy) and glutathione (GSH) play crucial roles in living systems, and their variations are closely associated with various diseases. Herein, we developed a near-infrared intramolecular charge transfer (ICT) based fluorescent probe Y-NBD, achieving detection of Cys/Hcy and H2S with different fluorescent signals (green-red for Cys/Hcy, red for H2S), large Stokes shifts (~100/105 nm or 191 nm) and high signal-background-ratio, but not responding to GSH. Y-NBD was successfully applied to image exogenous/endogenous Cys/Hcy and H2S in various living cancer cells (HeLa, A549, and HepG2) and in zebrafish. It not only visualized the transformation pathway of several thiols in HepG2 cells but also verified that the intestine is the main site for the activation and metabolism of Y-NBD in zebrafish, as well as realized to evaluate the degree of drug-induced liver injury. This work provides a promising tool for imaging Cys/Hcy and H2S in living systems and shows great potency in evaluating drug-induced liver injury and its treatment.
2024, 35(5): 109279
doi: 10.1016/j.cclet.2023.109279
Abstract:
Covalent organic polymer (COP) thin film-based memristors have generated intensive research interest, but the studies are still in their infancy. Herein, by controlling the content of hydroxyl groups in the aldehyde monomer, Py-COP thin films with different electronic push-pull effects were fabricated bearing distinct memory performances, where the films were prepared by the solid-liquid interface method on the ITO substrates and further fabricated as memory devices with ITO/Py-COPs/Ag architectures. The Py-COP-1-based memory device only exhibited binary memory behavior with an ON/OFF ratio of 1:101.87. In contrast, the device based on Py-COP-2 demonstrated ternary memory behavior with an ON/OFF ratio of 1:100.6: 103.1 and a ternary yield of 55%. The ternary memory mechanism of the ITO/Py-COP-2/Ag memory device is most likely due to the combination of the trapping of charge carriers and conductive filaments. Interestingly, the Py-COPs-based devices can successfully emulate the synaptic potentiation/depression behavior, clarifying the programmability of these devices in neuromorphic systems. These results suggest that the electronic properties of COPs can be precisely tuned at the molecular level, which provides a promising route for designing multi-level memory devices.
Covalent organic polymer (COP) thin film-based memristors have generated intensive research interest, but the studies are still in their infancy. Herein, by controlling the content of hydroxyl groups in the aldehyde monomer, Py-COP thin films with different electronic push-pull effects were fabricated bearing distinct memory performances, where the films were prepared by the solid-liquid interface method on the ITO substrates and further fabricated as memory devices with ITO/Py-COPs/Ag architectures. The Py-COP-1-based memory device only exhibited binary memory behavior with an ON/OFF ratio of 1:101.87. In contrast, the device based on Py-COP-2 demonstrated ternary memory behavior with an ON/OFF ratio of 1:100.6: 103.1 and a ternary yield of 55%. The ternary memory mechanism of the ITO/Py-COP-2/Ag memory device is most likely due to the combination of the trapping of charge carriers and conductive filaments. Interestingly, the Py-COPs-based devices can successfully emulate the synaptic potentiation/depression behavior, clarifying the programmability of these devices in neuromorphic systems. These results suggest that the electronic properties of COPs can be precisely tuned at the molecular level, which provides a promising route for designing multi-level memory devices.
2024, 35(5): 109297
doi: 10.1016/j.cclet.2023.109297
Abstract:
Due to the various pH liquid environment in nature, the pH-responsive lubricating hydrogel is widely investigated and developed for tissue interface substitute. However, the applied liquid environment will lead to poor mechanical property and weaken the pH-responsive capability. In this work, a carbon dots-enhanced pH-responsive lubricating hydrogel is developed by combining a pH-responsive section of dynamic PVA-borax network into a PAAm covalent polymer network. The formed hydrogel presents a partial gel-sol transition under controlled pH environments. At low pH environments (< 6.0), the formed lubricating layer originated from dynamic disassembly of PVA-borax hydrogel, and brings the lubricating properties on the hydrogel surface. Moreover, the mechanical strength and lubrication properties are well promoted by introducing the carbon dots into the hydrogel, the blue sol layer can be observed more visually under the fluorescence microscope. The pH-response also exhibits well reversibility. The prepared hydrogel broadens the idea for designing pH-responsive soft materials for soft lubricating actuator or robot.
Due to the various pH liquid environment in nature, the pH-responsive lubricating hydrogel is widely investigated and developed for tissue interface substitute. However, the applied liquid environment will lead to poor mechanical property and weaken the pH-responsive capability. In this work, a carbon dots-enhanced pH-responsive lubricating hydrogel is developed by combining a pH-responsive section of dynamic PVA-borax network into a PAAm covalent polymer network. The formed hydrogel presents a partial gel-sol transition under controlled pH environments. At low pH environments (< 6.0), the formed lubricating layer originated from dynamic disassembly of PVA-borax hydrogel, and brings the lubricating properties on the hydrogel surface. Moreover, the mechanical strength and lubrication properties are well promoted by introducing the carbon dots into the hydrogel, the blue sol layer can be observed more visually under the fluorescence microscope. The pH-response also exhibits well reversibility. The prepared hydrogel broadens the idea for designing pH-responsive soft materials for soft lubricating actuator or robot.
2024, 35(5): 109305
doi: 10.1016/j.cclet.2023.109305
Abstract:
Covalent adaptable networks (CANs), which share the properties of both thermosets and thermoplastics at the same time, are desirable for many applications. Introducing bulky substituents is a feasible way to design dynamic covalent bonds for constructing CANs, as evidenced by the successful implementation in CANs based on hindered urea bonds (HUBs). However, the dynamicity induced by introducing bulky substituents always come with low bond energy, resulting in low mechanical strength and poor stability of the CANs. Herein, we designed a novel hindered urethane bond, which is weak in thermodynamic (Keq = 1701.23 L/mol at 25 ℃) and inert in kinetic at low temperature, but stable in thermodynamic (Keq = 1.54 × 104 L/mol at 100 ℃) and active in kinetic at high temperature (k-1 = 0.105 h−1 at 80 ℃ and 0.315 h−1 at 120 ℃). As a result, the polyurethane based on it exhibits high mechanical properties (with Youngs' modulus of 1011 ± 29 MPa and flexible modulus reached 1833 ± 50 MPa) and excellent reversibility (can be reprocessed at 60 ℃ under 100 kPa in 30 min and completely healed at 40 ℃ in 10 min). Moreover, unlike to many CANs based on hindered urea bonds, our dynamic polyurethanes are highly stable in humid environment or even water solutions due to the slow hydrolysis kinetics. Such high-performance dynamic polyurethane polymers are attractive for many applications.
Covalent adaptable networks (CANs), which share the properties of both thermosets and thermoplastics at the same time, are desirable for many applications. Introducing bulky substituents is a feasible way to design dynamic covalent bonds for constructing CANs, as evidenced by the successful implementation in CANs based on hindered urea bonds (HUBs). However, the dynamicity induced by introducing bulky substituents always come with low bond energy, resulting in low mechanical strength and poor stability of the CANs. Herein, we designed a novel hindered urethane bond, which is weak in thermodynamic (Keq = 1701.23 L/mol at 25 ℃) and inert in kinetic at low temperature, but stable in thermodynamic (Keq = 1.54 × 104 L/mol at 100 ℃) and active in kinetic at high temperature (k-1 = 0.105 h−1 at 80 ℃ and 0.315 h−1 at 120 ℃). As a result, the polyurethane based on it exhibits high mechanical properties (with Youngs' modulus of 1011 ± 29 MPa and flexible modulus reached 1833 ± 50 MPa) and excellent reversibility (can be reprocessed at 60 ℃ under 100 kPa in 30 min and completely healed at 40 ℃ in 10 min). Moreover, unlike to many CANs based on hindered urea bonds, our dynamic polyurethanes are highly stable in humid environment or even water solutions due to the slow hydrolysis kinetics. Such high-performance dynamic polyurethane polymers are attractive for many applications.
2024, 35(5): 109321
doi: 10.1016/j.cclet.2023.109321
Abstract:
Azulene is a promising building block for creating innovative polycyclic aromatic hydrocarbons. This study involved the construction of three nonalternant isomers of pentacene by fusing two azulene units, named Az-PH1/2/3. Az-PH1 was initially developed through the rhodium(II)-catalyzed cyclization of bis(N-tosylhydrazone)s. Intriguingly, Az-PH1 was also unexpectedly obtained during a nickel(0)-catalyzed one-step tandem reaction. We investigated the optical and electrochemical properties, aromaticity, and photo-oxidative stability of Az-PH1, comparing it with the well-known pentacene using density functional theory, electrochemical, and photophysical tests. Our results showed that the azulene-fusing strategy resulted in a molecule with narrow optical bandgaps (2.046 eV) and a long half-life time under ambient air conditions.
Azulene is a promising building block for creating innovative polycyclic aromatic hydrocarbons. This study involved the construction of three nonalternant isomers of pentacene by fusing two azulene units, named Az-PH1/2/3. Az-PH1 was initially developed through the rhodium(II)-catalyzed cyclization of bis(N-tosylhydrazone)s. Intriguingly, Az-PH1 was also unexpectedly obtained during a nickel(0)-catalyzed one-step tandem reaction. We investigated the optical and electrochemical properties, aromaticity, and photo-oxidative stability of Az-PH1, comparing it with the well-known pentacene using density functional theory, electrochemical, and photophysical tests. Our results showed that the azulene-fusing strategy resulted in a molecule with narrow optical bandgaps (2.046 eV) and a long half-life time under ambient air conditions.
2024, 35(5): 109337
doi: 10.1016/j.cclet.2023.109337
Abstract:
Quinoidal π-conjugated structures, a kind of fundamental subunits for organic π-systems, may produce some intriguing optical, electronic and magnetic properties of polycyclic hydrocarbons (PHs). Herein, we report two thienothiophene-centered ladder-type polycyclic molecules (1 and 2), which possess one quinoidal thienothiophene moiety and two para-quinodimethane (p-QDM) subunits, respectively. As theoretically and experimentally studied, while 1 is a fully closed-shell molecule, 2 owns an open-shell structure along with partial contribution of tetraradical state that is induced by the resonance of p-QDM. Moreover, although 2 has a larger π-conjugated skeleton and open-shell electronic state, it exhibits larger bandgap and blue-shifted absorption. On the other hand, the reversible oxidation activity of 1 enables the preparation of its dication, and the studies on its single-crystal and aromatic structures demonstrate that its two positive charges are delocalized onto the oxygen atoms, thus achieving fully π-extended structure and near-infrared absorption. This study not only gains insight into quinoidal π-subunits, but also provides an important basis for the development of antiaromatic and open-shell π-electron materials.
Quinoidal π-conjugated structures, a kind of fundamental subunits for organic π-systems, may produce some intriguing optical, electronic and magnetic properties of polycyclic hydrocarbons (PHs). Herein, we report two thienothiophene-centered ladder-type polycyclic molecules (1 and 2), which possess one quinoidal thienothiophene moiety and two para-quinodimethane (p-QDM) subunits, respectively. As theoretically and experimentally studied, while 1 is a fully closed-shell molecule, 2 owns an open-shell structure along with partial contribution of tetraradical state that is induced by the resonance of p-QDM. Moreover, although 2 has a larger π-conjugated skeleton and open-shell electronic state, it exhibits larger bandgap and blue-shifted absorption. On the other hand, the reversible oxidation activity of 1 enables the preparation of its dication, and the studies on its single-crystal and aromatic structures demonstrate that its two positive charges are delocalized onto the oxygen atoms, thus achieving fully π-extended structure and near-infrared absorption. This study not only gains insight into quinoidal π-subunits, but also provides an important basis for the development of antiaromatic and open-shell π-electron materials.
2024, 35(5): 109339
doi: 10.1016/j.cclet.2023.109339
Abstract:
Surface fluorination of conventional polymers can give them desirable surface properties similar to the expensive and difficult-to-process fluoropolymers. However, traditional surface fluorination techniques often require toxic reagents and special equipment. Here, we report a simple and effective polymer surface fluorination method by using safe and inexpensive perfluoro-2-methyl-3-pentanone (PFMP, C2F5C(O)CF(CF3)2) and UV irradiation. This method is applicable to various polymer materials, and generates nanometer-thick fluorinated layer on the outermost surface, significantly changing their surface properties without changing the surface morphology.
Surface fluorination of conventional polymers can give them desirable surface properties similar to the expensive and difficult-to-process fluoropolymers. However, traditional surface fluorination techniques often require toxic reagents and special equipment. Here, we report a simple and effective polymer surface fluorination method by using safe and inexpensive perfluoro-2-methyl-3-pentanone (PFMP, C2F5C(O)CF(CF3)2) and UV irradiation. This method is applicable to various polymer materials, and generates nanometer-thick fluorinated layer on the outermost surface, significantly changing their surface properties without changing the surface morphology.
2024, 35(5): 109340
doi: 10.1016/j.cclet.2023.109340
Abstract:
It is of great interest to make a degradable material widely tailorable to replace petroleum-derived products among diverse applications. Here, we report the construction of a new multi-purpose degradable material for the first time via a simple ternary copolymerization system comprising ε-caprolactone (ε-CL), cyclohexane oxide (CHO) and CO2. Under low pressure of 1 bar ~5 bar, the ring-opening polymerization (ROP) of ε-CL and ring-opening copolymerization (ROCOP) of CO2 and CHO can simultaneously proceed. The carbonate units are randomly distributed on the polymer chain. These random terpolymers have controllable molar mass (10–106 kDa) and compositions (4–33 mol% CO2). And the obtained materials show large-span tunability from tough plastic to elastomer and even adhesive.
It is of great interest to make a degradable material widely tailorable to replace petroleum-derived products among diverse applications. Here, we report the construction of a new multi-purpose degradable material for the first time via a simple ternary copolymerization system comprising ε-caprolactone (ε-CL), cyclohexane oxide (CHO) and CO2. Under low pressure of 1 bar ~5 bar, the ring-opening polymerization (ROP) of ε-CL and ring-opening copolymerization (ROCOP) of CO2 and CHO can simultaneously proceed. The carbonate units are randomly distributed on the polymer chain. These random terpolymers have controllable molar mass (10–106 kDa) and compositions (4–33 mol% CO2). And the obtained materials show large-span tunability from tough plastic to elastomer and even adhesive.
2024, 35(5): 109354
doi: 10.1016/j.cclet.2023.109354
Abstract:
Developing platinum-group-metal (PGM) catalysts possessing strong metal-support interaction and controllable PGM size is urgent for the sluggish oxygen reduction reaction (ORR) in proton-exchange membrane fuel cells. Herein, we propose an in-situ self-assembled reduction strategy to successfully induce highly-dispersed sub-3 nm platinum nanoparticles (Pt NPs) to attach on resin-derived atomic Co coordinated by N-doped carbon substrate (Pt/CoSA-N-C) for ORR. To be specific, the interfacial electron interaction effect, along with a highly robust CoSA-N-C support endow the as-fabricated Pt/CoSA-N-C catalyst with significantly enhanced catalytic properties, i.e., a mass activity (MA) of 0.719 A/mgPt at 0.9 ViR‑free and a reduction of 24.2% in MA after a 20,000-cycles test. Density functional theory (DFT) calculations demonstrate that the enhanced electron interaction between Pt and CoSA-N-C support decreases the d-band center of Pt, which is in favor of lowering the desorption energy of *OH on Pt/CoSA-N-C surface and accelerating the formation of H2O, thus enhance the instinct activity of ORR. Furthermore, the higher binding energy between Pt and CoSA-N-C compared to Pt and C indicates that the migration of Pt has been suppressed, which theoretically explains the improved durability of Pt/CoSA-N-C. Our work offers an enlightenment on constructing composite Pt-based catalysts with multiple active sites.
Developing platinum-group-metal (PGM) catalysts possessing strong metal-support interaction and controllable PGM size is urgent for the sluggish oxygen reduction reaction (ORR) in proton-exchange membrane fuel cells. Herein, we propose an in-situ self-assembled reduction strategy to successfully induce highly-dispersed sub-3 nm platinum nanoparticles (Pt NPs) to attach on resin-derived atomic Co coordinated by N-doped carbon substrate (Pt/CoSA-N-C) for ORR. To be specific, the interfacial electron interaction effect, along with a highly robust CoSA-N-C support endow the as-fabricated Pt/CoSA-N-C catalyst with significantly enhanced catalytic properties, i.e., a mass activity (MA) of 0.719 A/mgPt at 0.9 ViR‑free and a reduction of 24.2% in MA after a 20,000-cycles test. Density functional theory (DFT) calculations demonstrate that the enhanced electron interaction between Pt and CoSA-N-C support decreases the d-band center of Pt, which is in favor of lowering the desorption energy of *OH on Pt/CoSA-N-C surface and accelerating the formation of H2O, thus enhance the instinct activity of ORR. Furthermore, the higher binding energy between Pt and CoSA-N-C compared to Pt and C indicates that the migration of Pt has been suppressed, which theoretically explains the improved durability of Pt/CoSA-N-C. Our work offers an enlightenment on constructing composite Pt-based catalysts with multiple active sites.
2024, 35(5): 109383
doi: 10.1016/j.cclet.2023.109383
Abstract:
Glioblastoma multiforme (GBM) is the most common malignant primary brain tumor in adults. The precise identification and distinction of GBM heterogeneity from surrounding brain parenchyma at the cellular level and even at the tissue level are important for GBM therapy. In this study, GBM cells are distinguished from normal astrocytes and non-central nervous system (CNS) tumor cells by surface-enhanced Raman scattering (SERS) based on gold nanoshell (SiO2@Au) particles and support vector machine (SVM) algorithm. In addition, the gold nanoisland (AuNI) SERS substrates are further developed and explored for accurate detection of GBM at the tissue level. The distinction between glioma and trauma tissues, identification of different tumor grades, and IDH mutation are realized with the assistance of orthogonal partial least squares discriminant analysis (OPLS-DA) in a rapid, non-invasive, and convenient method. The results show that the developed SERS-based analytical method has the potential for practical application for the detection of GBM at the single-cell and tissue levels and even for real-time intraoperative diagnosis.
Glioblastoma multiforme (GBM) is the most common malignant primary brain tumor in adults. The precise identification and distinction of GBM heterogeneity from surrounding brain parenchyma at the cellular level and even at the tissue level are important for GBM therapy. In this study, GBM cells are distinguished from normal astrocytes and non-central nervous system (CNS) tumor cells by surface-enhanced Raman scattering (SERS) based on gold nanoshell (SiO2@Au) particles and support vector machine (SVM) algorithm. In addition, the gold nanoisland (AuNI) SERS substrates are further developed and explored for accurate detection of GBM at the tissue level. The distinction between glioma and trauma tissues, identification of different tumor grades, and IDH mutation are realized with the assistance of orthogonal partial least squares discriminant analysis (OPLS-DA) in a rapid, non-invasive, and convenient method. The results show that the developed SERS-based analytical method has the potential for practical application for the detection of GBM at the single-cell and tissue levels and even for real-time intraoperative diagnosis.
2024, 35(5): 109419
doi: 10.1016/j.cclet.2023.109419
Abstract:
Diagnostic C9orf72 hexanucleotide repeat expansions (C9-HRE) is essential for the early and accurate diagnosis of amyotrophic lateral sclerosis (ALS) and will provide support for the prognosis and gene therapy of ALS. In the present study, by combining catalytic hairpin assembly (CHA) with Mycobacterium smegmatis porin A (MspA) nanopore, a new nanopore-based strategy for the detection of C9-HRE was reported. Less than 30 repeats of C9-HRE could be detected via this method, and the results have the potential to help distinguish between patients and healthy individuals. Moreover, the method demonstrated its great specificity for C9-HRE by identifying other repeat expansions. Given the high selectivity, this approach had been successfully used to detect C9-HRE in cell and blood samples with high accuracy. This detection strategy is user-friendly and has a strong anti-interference ability, thus providing a powerful tool for clinical diagnosis.
Diagnostic C9orf72 hexanucleotide repeat expansions (C9-HRE) is essential for the early and accurate diagnosis of amyotrophic lateral sclerosis (ALS) and will provide support for the prognosis and gene therapy of ALS. In the present study, by combining catalytic hairpin assembly (CHA) with Mycobacterium smegmatis porin A (MspA) nanopore, a new nanopore-based strategy for the detection of C9-HRE was reported. Less than 30 repeats of C9-HRE could be detected via this method, and the results have the potential to help distinguish between patients and healthy individuals. Moreover, the method demonstrated its great specificity for C9-HRE by identifying other repeat expansions. Given the high selectivity, this approach had been successfully used to detect C9-HRE in cell and blood samples with high accuracy. This detection strategy is user-friendly and has a strong anti-interference ability, thus providing a powerful tool for clinical diagnosis.
Advanced development of grain boundaries in TMDs from fundamentals to hydrogen evolution application
2024, 35(5): 108628
doi: 10.1016/j.cclet.2023.108628
Abstract:
Grain boundary (GB), as a kind of lattice defect, widely exists in two-dimensional transition metal dichalcogenides (2D TMDs), which has complex and diverse influences on the physical/chemical properties of 2D TMDs. GBs are universally considered to be a double-edged sword, although some electrical and mechanical properties of 2D TMDs would be adversely affected leading to the reduced overall quality, certain structure-oriented applications could be realized based on its unique properties. In this review, we first detailed the atomic structure characteristics of GBs and the corresponding techniques, then we systematically summarized the methods of introducing GBs into 2D TMDs. Next, we expounded unique electrical, mechanical, and chemical properties of the GBs in 2D TMDs and clarified its internal relationship with the atomic structure. Moreover, the application of GB structure in hydrogen evolution reaction (HER) is also discussed. In the end, we make a conclusion and put forward outlooks, hoping to further promote the basic research of GB and boost the wide application of 2D TMDs.
Grain boundary (GB), as a kind of lattice defect, widely exists in two-dimensional transition metal dichalcogenides (2D TMDs), which has complex and diverse influences on the physical/chemical properties of 2D TMDs. GBs are universally considered to be a double-edged sword, although some electrical and mechanical properties of 2D TMDs would be adversely affected leading to the reduced overall quality, certain structure-oriented applications could be realized based on its unique properties. In this review, we first detailed the atomic structure characteristics of GBs and the corresponding techniques, then we systematically summarized the methods of introducing GBs into 2D TMDs. Next, we expounded unique electrical, mechanical, and chemical properties of the GBs in 2D TMDs and clarified its internal relationship with the atomic structure. Moreover, the application of GB structure in hydrogen evolution reaction (HER) is also discussed. In the end, we make a conclusion and put forward outlooks, hoping to further promote the basic research of GB and boost the wide application of 2D TMDs.
2024, 35(5): 108821
doi: 10.1016/j.cclet.2023.108821
Abstract:
Metal–organic framework (MOF) is a periodic sexual network structure with large surface area and high porosity, which is assembled by inorganic nodes and organic ligands through coordinate covalent bond. MOFs have the advantages of controllable pore size and shape, large specific surface area, easy modification and more active sites. In addition, MOF based nanoenzymes display excellent enzyme catalytic activity due to their special structure and multiple exposed metal active sites, controlling the production of reactive oxygen species (ROS) in cells or the body, and thus regulating the polarization of macrophage. This article reviews the mechanism of MOF material regulating macrophage polarization and the function of macrophages with different phenotypes. By utilizing the excellent properties of MOFs and the advantages of combining them with bioactive materials, we have discovered their excellent applications in the treatment of inflammatory diseases. Finally, we discussed the current challenges and prospects faced by MOF based composite materials. We expect that the research in this developing field will play a more important role in combating inflammatory diseases in the field of nanomedicine.
Metal–organic framework (MOF) is a periodic sexual network structure with large surface area and high porosity, which is assembled by inorganic nodes and organic ligands through coordinate covalent bond. MOFs have the advantages of controllable pore size and shape, large specific surface area, easy modification and more active sites. In addition, MOF based nanoenzymes display excellent enzyme catalytic activity due to their special structure and multiple exposed metal active sites, controlling the production of reactive oxygen species (ROS) in cells or the body, and thus regulating the polarization of macrophage. This article reviews the mechanism of MOF material regulating macrophage polarization and the function of macrophages with different phenotypes. By utilizing the excellent properties of MOFs and the advantages of combining them with bioactive materials, we have discovered their excellent applications in the treatment of inflammatory diseases. Finally, we discussed the current challenges and prospects faced by MOF based composite materials. We expect that the research in this developing field will play a more important role in combating inflammatory diseases in the field of nanomedicine.
2024, 35(5): 108954
doi: 10.1016/j.cclet.2023.108954
Abstract:
Integrated CO2 capture and conversion of (ICCC) is one of the most effective solutions to reduce anthropogenic CO2 emissions, which has attracted extensive public attention. Dual functional materials (DFMs), including adsorbent and catalyst, are the key components to achieve ICCC. Magnesium oxide (MgO) is an ideal adsorbent for ICCC, since it is characterized by high theoretical adsorption capacity, low cost, low energy consumption and extensive sources. It can also be used as DFMs in combination with the Ni catalysts. MgO not only can act as an adsorbent in DFMs but also enhance the catalytic performance of Ni. This review summarizes the advantages and modification methods of MgO as adsorbent and the influence of its adsorption conditions on the adsorption performance. Moreover, the important role of MgO in facilitating the catalytic conversion of CO2 is highlighted. Future research focuses are proposed for the development of MgO based DFMs with high adsorption capacity, high stability, conversion, and selectivity as well as low cost and energy consumption.
Integrated CO2 capture and conversion of (ICCC) is one of the most effective solutions to reduce anthropogenic CO2 emissions, which has attracted extensive public attention. Dual functional materials (DFMs), including adsorbent and catalyst, are the key components to achieve ICCC. Magnesium oxide (MgO) is an ideal adsorbent for ICCC, since it is characterized by high theoretical adsorption capacity, low cost, low energy consumption and extensive sources. It can also be used as DFMs in combination with the Ni catalysts. MgO not only can act as an adsorbent in DFMs but also enhance the catalytic performance of Ni. This review summarizes the advantages and modification methods of MgO as adsorbent and the influence of its adsorption conditions on the adsorption performance. Moreover, the important role of MgO in facilitating the catalytic conversion of CO2 is highlighted. Future research focuses are proposed for the development of MgO based DFMs with high adsorption capacity, high stability, conversion, and selectivity as well as low cost and energy consumption.
2024, 35(5): 109020
doi: 10.1016/j.cclet.2023.109020
Abstract:
In September 2018, we proposed the cutting-edge concept of "Beyond Limits Manufacturing" (BLM). BLM technology is based on the three-dimensional inner engraving or precise outer engraving of ultra-fast laser, to invent micro/nano scale flow chips or devices, which makes it possible for the microform, integration, economy, safety, high efficiency, green and intelligence of research, development and manufacturing process, so as to realize transformational manufacturing in the era of Industry 4.0. In this paper, we reviewed the representative results we made in the field of micro/nano flow chemistry during the implementation of the BLM major project (December 2019 to August 2023), and discussed its application prospects in micro/nano flow chemistry.
In September 2018, we proposed the cutting-edge concept of "Beyond Limits Manufacturing" (BLM). BLM technology is based on the three-dimensional inner engraving or precise outer engraving of ultra-fast laser, to invent micro/nano scale flow chips or devices, which makes it possible for the microform, integration, economy, safety, high efficiency, green and intelligence of research, development and manufacturing process, so as to realize transformational manufacturing in the era of Industry 4.0. In this paper, we reviewed the representative results we made in the field of micro/nano flow chemistry during the implementation of the BLM major project (December 2019 to August 2023), and discussed its application prospects in micro/nano flow chemistry.
2024, 35(5): 109022
doi: 10.1016/j.cclet.2023.109022
Abstract:
Thin-film composite (TFC) reverse osmosis (RO) membranes have attracted considerable attention in water treatment and desalination processes due to their specific separation advantages. Nevertheless, the trade-off effect between water flux and salt rejection poses huge challenges to further improvement in TFC RO membrane performance. Numerous research works have been dedicated to optimizing membrane fabrication and modification for addressing this issue. In the meantime, several reviews summarized these approaches. However, the existing reviews seldom analyzed these methods from a theoretical perspective and thus failed to offer effective optimization directions for the RO process from the root cause. In this review, we first propose a mass transfer model to facilitate a better understanding of the entire process of how water and solute permeate through RO membranes in detail, namely the migration process outside the membrane, the dissolution process on the membrane surface, and the diffusion process within the membrane. Thereafter, the water and salt mass transfer behaviors obtained from model deduction are comprehensively analyzed to provide potential guidelines for alleviating the trade-off effect between water flux and salt rejection in the RO process. Finally, inspired by the theoretical analysis and the accurate identification of existing bottlenecks, several promising strategies for both regulating RO membranes and optimizing operational conditions are proposed to further exploit the potential of RO membrane performance. This review is expected to guide the development of high-performance RO membranes from a mass transfer theory standpoint.
Thin-film composite (TFC) reverse osmosis (RO) membranes have attracted considerable attention in water treatment and desalination processes due to their specific separation advantages. Nevertheless, the trade-off effect between water flux and salt rejection poses huge challenges to further improvement in TFC RO membrane performance. Numerous research works have been dedicated to optimizing membrane fabrication and modification for addressing this issue. In the meantime, several reviews summarized these approaches. However, the existing reviews seldom analyzed these methods from a theoretical perspective and thus failed to offer effective optimization directions for the RO process from the root cause. In this review, we first propose a mass transfer model to facilitate a better understanding of the entire process of how water and solute permeate through RO membranes in detail, namely the migration process outside the membrane, the dissolution process on the membrane surface, and the diffusion process within the membrane. Thereafter, the water and salt mass transfer behaviors obtained from model deduction are comprehensively analyzed to provide potential guidelines for alleviating the trade-off effect between water flux and salt rejection in the RO process. Finally, inspired by the theoretical analysis and the accurate identification of existing bottlenecks, several promising strategies for both regulating RO membranes and optimizing operational conditions are proposed to further exploit the potential of RO membrane performance. This review is expected to guide the development of high-performance RO membranes from a mass transfer theory standpoint.
2024, 35(5): 109091
doi: 10.1016/j.cclet.2023.109091
Abstract:
This review explores the concept of life-on-a-chip, which involves the creation of miniaturized biological systems, such as organs, tissues, and model organisms, on microscale platforms called microfluidic chips. These chips consist of intricately etched channels, wells, and chambers that enable precise control and observation of fluids, cells, and biochemical reactions, facilitating the simulation of various aspects of human or animal physiology and the study of responses to different stimuli, drugs, or disease conditions. The review highlights the application of a novel technology, "Beyond Limit Manufacturing" (BLM), in the development of sophisticated three-dimensional cell models and model organism microchips. Model-organism-on-a-chip and organ-on-a-chip (OoC) are among the thriving developments in the field of microfluidics, allowing for the reconstruction of living microenvironments and implementation of multiple stimuli. The review discusses the latest advancements in life-on-a-chip technology using BLM and outlines potential future research directions, emphasizing the significant role of these chips in studying complex biological processes in a controlled and scalable manner.
This review explores the concept of life-on-a-chip, which involves the creation of miniaturized biological systems, such as organs, tissues, and model organisms, on microscale platforms called microfluidic chips. These chips consist of intricately etched channels, wells, and chambers that enable precise control and observation of fluids, cells, and biochemical reactions, facilitating the simulation of various aspects of human or animal physiology and the study of responses to different stimuli, drugs, or disease conditions. The review highlights the application of a novel technology, "Beyond Limit Manufacturing" (BLM), in the development of sophisticated three-dimensional cell models and model organism microchips. Model-organism-on-a-chip and organ-on-a-chip (OoC) are among the thriving developments in the field of microfluidics, allowing for the reconstruction of living microenvironments and implementation of multiple stimuli. The review discusses the latest advancements in life-on-a-chip technology using BLM and outlines potential future research directions, emphasizing the significant role of these chips in studying complex biological processes in a controlled and scalable manner.
2024, 35(5): 109094
doi: 10.1016/j.cclet.2023.109094
Abstract:
Water pollution caused by global population growth, urban expansion and industrialization development is one of the urgent issues that need to be addressed in the 21st century. Up to now, it was challenging for metal-organic frameworks (MOFs) to be used in the actual water treatment due to that the powder MOFs suffered from difficult reuse, poor water stability and easy corrosion. It is an effective strategy to immobilize MOFs powder onto porous sponge foam carriers for accomplishing large flux, facile recycling, easy processing water treatment setups. In this review article, the fabrication approaches and applications of different MOFs/sponge composites were highlighted, in which the fluorescence detection of pollutants, adsorption and separation of pollutants, catalytic reduction and oxidation of pollutants were included. Finally, the future challenges and opportunities of MOF/sponge for water treatment are proposed, aiming to provide in-depth guidance for the future design and manufacture of the immobilized MOFs onto sponge foams.
Water pollution caused by global population growth, urban expansion and industrialization development is one of the urgent issues that need to be addressed in the 21st century. Up to now, it was challenging for metal-organic frameworks (MOFs) to be used in the actual water treatment due to that the powder MOFs suffered from difficult reuse, poor water stability and easy corrosion. It is an effective strategy to immobilize MOFs powder onto porous sponge foam carriers for accomplishing large flux, facile recycling, easy processing water treatment setups. In this review article, the fabrication approaches and applications of different MOFs/sponge composites were highlighted, in which the fluorescence detection of pollutants, adsorption and separation of pollutants, catalytic reduction and oxidation of pollutants were included. Finally, the future challenges and opportunities of MOF/sponge for water treatment are proposed, aiming to provide in-depth guidance for the future design and manufacture of the immobilized MOFs onto sponge foams.
2024, 35(5): 109160
doi: 10.1016/j.cclet.2023.109160
Abstract:
Chiral alcohols and amines are important structural units widely existing in pharmaceuticals, agrochemicals, and food additives. Dynamic kinetic resolution (DKR) is an efficient strategy to deliver optically active alcohols and amines from their racemates. For the development of DKR method, racemization catalyst plays as a crucial element with the requirement of compatibility with the kinetic resolution (KR) system. In this paper, recent advance in the catalytic racemization of secondary alcohols and amines is summarized based on different types of racemizing intermediates, which are redox racemization via ketone/imine intermediates, racemization via radical intermediates, and racemization via carbocation intermediates. Enzymatic racemization of secondary alcohols and amines is also enclosed.
Chiral alcohols and amines are important structural units widely existing in pharmaceuticals, agrochemicals, and food additives. Dynamic kinetic resolution (DKR) is an efficient strategy to deliver optically active alcohols and amines from their racemates. For the development of DKR method, racemization catalyst plays as a crucial element with the requirement of compatibility with the kinetic resolution (KR) system. In this paper, recent advance in the catalytic racemization of secondary alcohols and amines is summarized based on different types of racemizing intermediates, which are redox racemization via ketone/imine intermediates, racemization via radical intermediates, and racemization via carbocation intermediates. Enzymatic racemization of secondary alcohols and amines is also enclosed.
2024, 35(5): 109161
doi: 10.1016/j.cclet.2023.109161
Abstract:
Molecular recognition in water, the biological solvent, always receives significant research focus in supramolecular chemistry. The mechanisms of molecular recognition in water is key to comprehending biological processes at the molecular level. Over the past five decades, supramolecular chemists have developed a vast array of synthetic receptors with highly diverse structures and recognition properties. Among them, cyclophanes represent an important family of macrocyclic receptors that have been extensively explored. The aromatic moieties in cyclophanes not only facilitate chemical modifications to impart water solubility but also enable forming hydrophobic cavities for guest inclusion in aqueous environments. Pioneered by Koga et al., who reported the first inclusion complex of cyclophanes in water and solid state, numerous water-soluble cyclophanes, including derivatives of blue box, calixarenes, resorcinarenes, pillararenes, octopusarenes, biphenarenes, coronarenes, and naphthotubes, etc., have been synthesized and subjected to investigation of the recognition capabilities in aqueous solutions. This review provides an overview of cyclophane receptors designed to bind organic guests in water. We categorize them into two classes based on the modifications made to their hydrophobic cavities: those with "exo-functionalized hydrophobic cavities" and those with "endo-functionalized hydrophobic cavities". We introduce their distinctive features and discuss strategies to enhance recognition affinity and selectivity. This review aims to inspire the development of novel synthetic receptors with intriguing properties and foster practical applications of cyclophanes.
Molecular recognition in water, the biological solvent, always receives significant research focus in supramolecular chemistry. The mechanisms of molecular recognition in water is key to comprehending biological processes at the molecular level. Over the past five decades, supramolecular chemists have developed a vast array of synthetic receptors with highly diverse structures and recognition properties. Among them, cyclophanes represent an important family of macrocyclic receptors that have been extensively explored. The aromatic moieties in cyclophanes not only facilitate chemical modifications to impart water solubility but also enable forming hydrophobic cavities for guest inclusion in aqueous environments. Pioneered by Koga et al., who reported the first inclusion complex of cyclophanes in water and solid state, numerous water-soluble cyclophanes, including derivatives of blue box, calixarenes, resorcinarenes, pillararenes, octopusarenes, biphenarenes, coronarenes, and naphthotubes, etc., have been synthesized and subjected to investigation of the recognition capabilities in aqueous solutions. This review provides an overview of cyclophane receptors designed to bind organic guests in water. We categorize them into two classes based on the modifications made to their hydrophobic cavities: those with "exo-functionalized hydrophobic cavities" and those with "endo-functionalized hydrophobic cavities". We introduce their distinctive features and discuss strategies to enhance recognition affinity and selectivity. This review aims to inspire the development of novel synthetic receptors with intriguing properties and foster practical applications of cyclophanes.
2024, 35(5): 109393
doi: 10.1016/j.cclet.2023.109393
Abstract:
Zinc-based batteries (ZBs) have been deemed as a potential substitute for lithium-ion batteries due to its unique advantages of abundant resources, low cost and acceptable energy density. Despite great progress in designing electrode materials has been made, the development of high-performance ZBs still remain challenges, such as the dendrite growth of zinc anode, hydrogen evolution reaction, limited electrochemical stability window, water evaporation and liquid leakage. Gel polymer electrolytes (GPEs), including hydrous GPEs with low content of active water and anhydrous GPEs without the presence of water, are proposed to avoid these problems. Furthermore, employing GPEs is conductive to fabricate flexible devices owing to the good mechanical strength. To date, most of researches focus on discovering new GPEs and exploring its application on flexible or wearable devices. Recent reviews also have outlined the polymer matrixes and advances of GPEs in various battery systems. Given this, herein, we seek to summarize the gelation mechanisms of GPEs, involving physical gel of polymer, chemical crosslinking of polymer and chemical polymerization of monomers. Peculiarly, the preparation methods are also classified. In addition, not only the features and central conundrum of GPEs are analyzed but also the corresponding strategies are discussed, contributing to design GPEs with ideal properties for high-performance ZBs.
Zinc-based batteries (ZBs) have been deemed as a potential substitute for lithium-ion batteries due to its unique advantages of abundant resources, low cost and acceptable energy density. Despite great progress in designing electrode materials has been made, the development of high-performance ZBs still remain challenges, such as the dendrite growth of zinc anode, hydrogen evolution reaction, limited electrochemical stability window, water evaporation and liquid leakage. Gel polymer electrolytes (GPEs), including hydrous GPEs with low content of active water and anhydrous GPEs without the presence of water, are proposed to avoid these problems. Furthermore, employing GPEs is conductive to fabricate flexible devices owing to the good mechanical strength. To date, most of researches focus on discovering new GPEs and exploring its application on flexible or wearable devices. Recent reviews also have outlined the polymer matrixes and advances of GPEs in various battery systems. Given this, herein, we seek to summarize the gelation mechanisms of GPEs, involving physical gel of polymer, chemical crosslinking of polymer and chemical polymerization of monomers. Peculiarly, the preparation methods are also classified. In addition, not only the features and central conundrum of GPEs are analyzed but also the corresponding strategies are discussed, contributing to design GPEs with ideal properties for high-performance ZBs.
2024, 35(5): 109418
doi: 10.1016/j.cclet.2023.109418
Abstract:
Microbial fuel cells (MFCs) have a simple structure and excellent pollutant treatment and power generation performance. However, the slow kinetics of the oxygen reduction reaction (ORR) at the MFC cathode limit power generation. The electrochemical performance of MFCs can be improved through electrocatalysis. Thus far, metal-based catalysts have shown astonishing results in the field of electrocatalysis, enabling MFC devices to demonstrate power generation capabilities comparable to those of Pt, thus showing enormous potential. This article reviews the research progress of meta-based MFC cathode ORR catalysts, including the ORR reaction mechanism of MFC, different types of catalysts, and preparation strategies. The catalytic effects of different catalysts in MFC are compared and summarized. Before discussing the practical application and expanded manufacturing of catalysts, we summarize the key challenges that must be addressed when using metal-based catalysts in MFC, with the aim of providing a scientific direction for the future development of advanced materials.
Microbial fuel cells (MFCs) have a simple structure and excellent pollutant treatment and power generation performance. However, the slow kinetics of the oxygen reduction reaction (ORR) at the MFC cathode limit power generation. The electrochemical performance of MFCs can be improved through electrocatalysis. Thus far, metal-based catalysts have shown astonishing results in the field of electrocatalysis, enabling MFC devices to demonstrate power generation capabilities comparable to those of Pt, thus showing enormous potential. This article reviews the research progress of meta-based MFC cathode ORR catalysts, including the ORR reaction mechanism of MFC, different types of catalysts, and preparation strategies. The catalytic effects of different catalysts in MFC are compared and summarized. Before discussing the practical application and expanded manufacturing of catalysts, we summarize the key challenges that must be addressed when using metal-based catalysts in MFC, with the aim of providing a scientific direction for the future development of advanced materials.
2024, 35(5): 109460
doi: 10.1016/j.cclet.2023.109460
Abstract:
