Engineering aggregates of julolidine-substituted aza-BODIPY nanoparticles for NIR-II photothermal therapy

Lulu Cao Yikun Li Dongxiang Zhang Shuai Yue Rong Shang Xin-Dong Jiang Jianjun Du

Citation:  Lulu Cao, Yikun Li, Dongxiang Zhang, Shuai Yue, Rong Shang, Xin-Dong Jiang, Jianjun Du. Engineering aggregates of julolidine-substituted aza-BODIPY nanoparticles for NIR-II photothermal therapy[J]. Chinese Chemical Letters, 2024, 35(12): 109735. doi: 10.1016/j.cclet.2024.109735 shu

Engineering aggregates of julolidine-substituted aza-BODIPY nanoparticles for NIR-II photothermal therapy

English

  • Near infrared (NIR) functional dyes, especially NIR-II (1000–1700 nm) dyes, have shown unique advantages in biomedical applications, due to their powerful ability in penetrating biological tissues [1-5]. Light in the NIR-II region can be strongly captured to transfer high photothermal conversion efficiencies (PCEs) for treating deep-seated tumors at deeper tissue penetration (~5–20 mm), because of the decreased tissue absorption, scattering and autofluorescence, compared to light in visible (400–700 nm) and NIR-I (700–900 nm) regions [6-16]. Therefore, the design and synthesis of NIR-II dyes have been attracting increasing interest.

    In recent years, the classic molecule aza-borondipyrromethene (aza-BODIPY) has attracted the widespread attention, due to its excellent spectral properties such as high molar extinction coefficient [17-21]. However, owing to the limitation of the parent nucleus of aza-BODIPYs, their optical spectra rarely touch the NIR-II region [22-25]. The extension of the π-conjugated system and the wise selection of the donor groups are the effective ways to develop the NIR-II dye aza-BODIPY. Julolidine, with planarity and steric hindrance, is often used as a donor fragment for the star molecules in special fields such as functional dyes, chemical sensors, optoelectronic materials and so forth [26-29]. Recently, Li et al. introduced julolidine into the aza-BODIPY nucleus and prepared NIR-II dye OMe-BDP as template molecule for photothermal therapy (PTT) (Fig. 1a) [30]. Changing the donor groups at 3,5-sites to produce the remarkable red-shift of absorption maximum, NIR-II aza-BODIPY (OMePh-BDP) nanoparticles for efficient osteosarcoma PPT via concurrent apoptosis and pyroptosis were successfully constructed (Fig. 1a) [31]. Moreover, the metallacycle was obtained via the coordination driven self-assembly of the NIR-II fluorescent aza-BODIPY (OMePY-BDP) with di-pyridine at 2,6-sites as the ligand, which provided a paradigm for the development of long-wavelength emissive supramolecular theranostic agents based on ruthenium (Fig. 1a) [32]. However, there is no record for the structural chemistry and molecular aggregating state in the julolidine system. Therefore, we revealed its single crystal structure for the first time and further elucidated the aggregating state of julolidine-based aza-BODIPY. Powerful donor-acceptor (D-A) type molecule was smartly designed through the construction of 1,7-jiuluolidine-3,5-p-dimethylaminophenyl groups. Based on the single crystal structure of QLD-BDP, its aggregation state is found to be the J-aggregation [33-37]. This new molecule absorbs and emits in NIR-II region, with good photothermal conversion efficiency (50.5%). QLD-BDP nanoparticles (QLD-BDP-NPs) could localize in mitochondria. QLD-BDP-NPs inhibited the growth of 4T1 multicellular spheroids (MCSs) by light irradiation, internalized into tumor rapidly and could not be excreted from the cells for 12 h. QLD-BDP-NPs could cause the complete destruction of 4T1 MCSs and had a PTT effect.

    Figure 1

    Figure 1.  Design of aza-BODIPY QLD-BDP with 1,7-julolidine-3,5-NMe2 groups for aggregation.

    Since it is of great value to construct a NIR absorbing dye aza-BODIPY, julolidine at 1,7-sites and p-dimethylaminophenyl group at 3,5-sites in aza-BODIPY system serves as a donor for the aza-BODIPY nucleus as a receptor, constructing a powerful d-A structural molecule. Using hexahydropyrido[3,2,1-ij]quinoline-9-carbaldehyde and 1-(4-(dimethylamino)phenyl)ethanone as the starting material, we successfully synthesized aza-BODIPY QLD-BDP in 14% total yield (Fig. 1b and Scheme S1 in Supporting information). According to the 1H NMR spectra, three different sets of -CH2- peaks and one set of -CH3 peaks can be clearly observed, confirming this molecular structure. Furthermore, we were fortunate to obtain the X-ray crystal of QLD-BDP, which is the first structure of julolidine-containing aza-BODIPY to date (Fig. 2a). Based on the single crystal structure, we found that the -CH2- groups, directly connecting to phenyl groups (C7, C13, C47 and C50) and the sp2 hybridized N (C9, C11, C45 and C48), maintain a coplanar structure with the phenyl groups (Fig. 2a). We also found that the four -CH2- groups in the middle sites (C8, C12, C46 and C49) were all tilted in the same direction, without adopting the distribution pattern on both sides of the phenyl plane. The angle of C48-C49-C50 is 114.3°, far deviating from the ideal value of 109.5°, indicating that C49 is closer to the plane mentioned above. However, the other three -CH2- groups (C8, C12, and C46) basically adopt the ideal sp3 hybrid structure. The B-F distances (1.375 and 1.425 Å) in QLD-BDP were found to be longer than that of the corresponding aza-BODIPY with 1,7-diphenyl groups (1.391 and 1.389 Å) by 0.036 Å [24, 38], owing to the strong electron-donating effect. The N4–B1–N5 and F1–B1–F2 angles were 106.2° and 110.1° respectively, indicating the boron atom in the center is a seriously distorted sp3 configuration. Therefore, due to the introduction of julolidine at 1,7-sites, the aza-BODIPY nucleus exhibits the significant distortion, and the overall molecule appears a bowl shaped structure (Fig. 2b and Fig. S1 in Supporting information).

    Figure 2

    Figure 2.  Oak ridge thermal ellipsoid plot (ORTEP) views of QLD-BDP (CCDC: 2299513) (displacement ellipsoids at the 30% probability level). (a) Front, (b) side views of the molecular structure. Selected bond lengths (Å) and angles (°): N4-B1, 1.547(6); N5-B1: 1.546(6); B1-F1: 1.375(6); B1-F2: 1.425(6); N4-B1-N5: 106.2(4); F1-B1-F2: 110.1(4). (c) Normalized absorption of QLD-BDP in different solvents, respectively.

    Next, we gained insight into spectral characteristics of QLD-BDP in different solvents. It found that the maxima absorption of QLD-BDP in various solvents ranged from 810 nm to 862 nm, with a broad full width at half maxima (FWHM) and a high molar extinction coefficient (for instance, ε = 166,000 L mol−1 cm−1 in CH2Cl2) (Fig. 2c and Table S1 in Supporting information). Among them, the maxima absorption of QLD-BDP in small polar solvent toluene is 810 nm, while QLD-BDP in large polar solvent DMSO is 862 nm with FWHM of 230 nm (Table S1). Subsequently, singlet oxygen (1O2) generation of QLD-BDP to inspect the intersystem crossing (ISC) process was investigated (Fig. S2 in Supporting information). By using 1,3-diphenylisobenzofuran (DPBF) as a 1O2 indicator, the efficiency of 1O2 generation was evaluated by detecting the decrease of DPBF indicator absorbance at 416 nm [39-43]. Based on the decay lines at 416 nm, the 1O2 yields of QLD-BDP were very low and near to be 0, indicating that ISC is basically prohibited.

    Because we obtained the data of weak fluorescence (Table S1) and singlet oxygen generation of this novel dye QLD-BDP, such information urges us to further explore the insight into the photothermal conversion capacity. To enhance the biocompatibility and the water solubility of QLD-BDP for photoimaging and phototherapy in biological system, QLD-BDP and amphipathic polymer material 1,2-distearoyl-sn–glycero‑3-phosphoethanolamine-N-[methoxy(polyethylene glycol)−2000] (DSPE-PEG2000) were self-assembled into dye QLD-BDP nanoparticles (QLD-BDP-NPs) (Fig. 3a) [44-46]. To understand the molecular design concept, the molecular packing mode of QLD-BDP via single crystal structure analysis was firstly investigated (Fig. 3b). In the single-crystal structure, the π-π interactions between one julolidine group (green) and another julolidine group (green), between the julolidine group (green) and the dimethylaminophenyl group (yellow) (Fig. S1), facilitate the aggregation packing mode. While dye QLD-BDP adopts coplanar inclined arrangement of its transition dipole, a slip angle of 35° is clearly observed (Fig. 3b). This arrangement of aggregate is in great agreement with Kasha's molecular exciton model, and corresponds to textbook cases of J-type (θ < 54.7°) packing for QLD-BDP (Fig. 3b) [47-49]. Dynamic light scattering (DLS) of QLD-BDP-NPs showed a suitable hydrodynamic diameter (30–110 nm) in Fig. 3c, and the average hydrodynamic diameter and the polydispersity index (PDI) were about 81.36 nm and 0.173. The azury QLD-BDP-NPs in aqueous solution stood for one week (Figs. 3d and e). Due to the aggregate effect (Fig. 3a and Fig. S3 in Supporting information), the absorption maximum (λabs= 866 nm) of QLD-BDP-NPs in aqueous solution bathochromically shifted 36 nm and its absorption band covered the NIR region (600–1000 nm) and became wider (Fig. 3f), comparing to those (λabs= 830 nm) of QLD-BDP in CH2Cl2. Additionally, QLD-BDP-NPs emit fluorescence (λem = 998 nm, ϕf = 0.001) when excited at 808 nm, and a peak belt covers a NIR-II range of 1000–1300 nm (Fig. 3g).

    Figure 3

    Figure 3.  (a) Self-assembly of QLD-BDP-NPs. (b) Molecular packing diagram of side view for QLD-BDP. (c) DLS of QLD-BDP-NPs in aqueous solution. (d) TEM of QLD-BDP-NPs in aqueous solution. Scale bar: 100 nm. (e) Photo of pure water and QLD-BDP-NPs in water. (f) Absorption of 2 µmol/L QLD-BDP-NPs (black curve) in CH2Cl2 and 10 µmol/L QLD-BDP-NPs in water (green curve). (g) Fluorescence of 10 µmol/L QLD-BDP-NPs in water. λex = 808 nm; laser source. (h) Temperature changes of QLD-BDP-NPs at different concentrations (40–80 µmol/L) under 808 nm laser irradiation (0.8 W/cm2). (i) Temperature response curves of QLD-BDP-NPs in aqueous solutions under irradiation and naturally cooling. (j) Linear fitting of –Lnθ and time.

    Next, photothermal conversion efficiency of QLD-BDP-NPs was measured. The temperatures of QLD-BDP-NPs (40, 60 and 80 µmol/L) in aqueous solution were found to be increased gradually under light radiation (0.8 W/cm2, 5 min) (Fig. 3h). Moreover, the heating effect is proportional to the concentration of QLD-BDP-NPs. Under 80 µmol/L of QLD-BDP-NPs and 0.8 W/cm2 light radiation, the solution can be quickly heated to 55.1 ℃ in 5 min (Fig. S4 in Supporting information). The higher temperature-elevated performance is associated with intense light radiation power (0.4–0.8 W/cm2) in Fig. S5 (Supporting information). So, the photothermal effect was positively related to concentration and light power density, indicating that the heat generation could be controlled. Natural cooling for 5 min after 5 min light radiation could reduce the temperature almost to room temperature (Fig. 3i). Based on the corresponding relationship between cooling time and −Lnθ (Fig. 3j), the photothermal conversion efficiency (η) was calculated as 50.5%, which was in agreement with that previously reported for aza-BODIPY derivatives [19]. Furthermore, we tested the temperature changes of five heating-cooling cycles, which showed that QLD-BDP-NPs had good photothermal stability, and temperature changes of the five cycles were similar (Fig. S6 in Supporting information).

    The colocalization of QLD-BDP-NPs with Lyso-Tracker Green (LTG), ER-Tracker Green (ETG) or Mito-Tracker Green (MTG) in 4T1 cells was investigated, respectively (Fig. 4) [50, 51]. Colocalization experiments showed that the green fluorescence signal of LTR and ETR overlapped poorly with the red fluorescence signal of QLD-BDP-NPs, with low Pearson coefficients of 0.775 and 0.677, respectively (Figs. 4a and b). However, when 4T1 cells were labeled with QLD-BDP-NPs and MTR, colocalization experiments confirmed that the green fluorescence of MTR overlapped well with the red fluorescence of QLD-BDP-NPs, and the Pearson coefficient reached 0.890 (Fig. 4c). These results indicated better specific imaging and localization ability of QLD-BDP-NPs for mitochondria than lysosome and endoplasmic reticulum.

    Figure 4

    Figure 4.  Colocalization of QLD-BDP-NPs with LTG, ETG or MTG for (a) lysosome, (b) endoplasmic reticulum, and (c) mitochondria in 4T1 cells (QLD-BDP-NPs: λex =640 nm, λem = 650–750 nm; Tracker: λex = 488 nm, λem = 500–600 nm; Scale bar: 20 µm). Cells were labeled with QLD-BDP-NPs (20 µg/mL) and LTG (1.0 µmol/L), ETG (1.0 µmol/L) or MTG (1.0 µmol/L), respectively. (Ⅰ) QLD-BDP-NPs labeled with red fluorescence; (Ⅱ) Organelles labeled with green fluorescence; (Ⅲ) Superposition of red and green fluorescence in yellow, indicating colocalization; (Ⅳ) Pearson coefficient of pixel intensity.

    MTT assay was employed to further evaluate the effect of different concentrations of QLD-BDP-NPs on the viability of 4T1 tumor cells under darkness and 850 nm laser irradiation (0.2 W/cm2, 8 min). As shown in Fig. S7 (Supporting information), under darkness the inhibition of QLD-BDP-NPs on the activity of tumor cells gradually increased with the increase of QLD-BDP-NPs concentration. Under laser irradiation, cell viability decreased significantly, and cell viability was only 3.01% in present of 40 µg/mL QLD-BDP-NPs. The experimental results showed that QLD-BDP-NPs had low dark toxicity and high phototoxicity. Furthermore, to investigate the triggering mechanism of QLD-BDP-NPs on cancer cells, flow cytometry was applied to explore relevant apoptosis in 4T1 cells (Fig. S8 in Supporting information). The treatment with QLD-BDP-NPs plus laser irradiation obviously caused apoptosis in cancer cells, and the percentage of apoptotic cells increased from 7.24% to 50.67%, whereas cells treated with QLD-BDP-NPs or light alone showed a lower rate of apoptosis.

    The uptake and permeation ability of drugs in MCSs is an important factor affecting their therapeutic effect on tumors [52-54]. Therefore, based on mouse breast cancer 4T1 cells, a 3D multicellular spheroid tumor model in vitro was established to study cell uptake. After 12 h of exposure to QLD-BDP-NPs, imaging of MCSs was performed using single photon fluorescence confocal microscopy (CLSM). As the Z-axis stacking depth extends, QLD-BDP-NPs were found to exhibit a clear process of infiltrating from the edge to the inside (Fig. 5a), stimulating their tracking and imaging in vitro. So, QLD-BDP-NPs could internalize into tumor rapidly and could not be excreted from the cells for 12 h. To evaluate the phototoxicity of QLD-BDP-NPs on MCSs, the MCSs of 4T1 cells were treated with 20 and 40 µg/mL QLD-BDP-NPs in phosphate buffered saline (PBS), and the culture medium was changed every other day (Fig. 5b). After 12 h of cultivation, the MCSs were formed. Then, the MCSs were further cultured under laser irradiation (0.3 W/cm2, 900 s) or darkness for two days to observe the morphological changes. Compared with the control group without laser irradiation, 20 or 40 µg/mL QLD-BDP-NPs have a slight inhibitory effect on the growth of MCSs. Under laser irradiation, 20 or 40 µg/mL QLD-BDP-NPs have a significant inhibitory effect on the growth of MCSs. Especially, MCSs treated with 40 µg/mL QLD-BDP-NPs exhibited more significant disintegration, demonstrating higher PTT efficiency. Therefore, the unique ability of QLD-BDP-NPs to inhibit the growth of MCSs by light irradiation indicates that QLD-BDP-NPs have the potential to inhibit solid tumors in vivo.

    Figure 5

    Figure 5.  (a) Imaging of MCSs of 4T1 cells (λex =640 nm, λem = 650–750 nm). (b) CLSM analysis image of 4T1 MCSs. MCSs were cultured in a medium PBS containing 20 or 40 µg/mL QLD-BDP-NPs. Use a laser at 850 nm (0.3 W/cm2, 900 s) for light irradiation. The images of the spherical formation for 12 h before irradiation were recorded, and the images of the first and second days with or without light irradiation were recorded. (c) Live/dead cell imaging of 4T1 MCS treated with QLD-BDP-NPs under dark and light irradiation (850 nm, 0.3 W/cm2, 900 s), respectively. Scale bar: 200 µm.

    To further test the phototherapy effect of QLD-BDP-NPs, MCSs were treated with 40 µg/mL QLD-BDP-NPs, and then stained with calcein AM (green) and propidium iodide (PI, red) dyes in the dark group and the light group, respectively. Green fluorescence represents living cells, while red fluorescence represents dead cells. As shown in Fig. 5c, it is once again demonstrated that QLD-BDP-NPs have a slight inhibitory effect on the growth of 4T1 MCSs without laser irradiation. Under NIR laser irradiation (850 nm, 0.3 W/cm2, 900 s), a strong red fluorescence was obviously observed, indicating that QLD-BDP-NPs caused the complete destruction of 4T1 MCSs.

    In conclusion, utilizing hexahydropyrido[3,2,1-ij]quinoline-9-carbaldehyde and 1-(4-(dimethylamino)phenyl)ethanone as the starting material, we successfully synthesized aza-BODIPY QLD-BDP in 14% total yield. Based on the single crystal structure, due to the introduction of julolidine at 1,7-sites, the aza-BODIPY nucleus exhibits the significant distortion, and the overall molecule appears a bowl shaped structure. Owing to the aggregation effect, the absorption maximum (λabs = 866 nm) of QLD-BDP-NPs in aqueous solution bathochromically shifted 36 nm and the absorption band covered the NIR region (600–1000 nm) and became wider. QLD-BDP-NPs emit fluorescence (λem = 998 nm, ϕf = 0.001) when excited at 808 nm, and a peak belt covers a NIR-II range of 1000–1300 nm. The PCE of the self-assembled QLD-BDP-NPs by aggregate can reach 50.5%. QLD-BDP-NPs have better specific imaging and localization ability for mitochondria than lysosome and endoplasmic reticulum. QLD-BDP-NPs could internalize into tumor rapidly and could not be excreted from the cells. QLD-BDP-NPs caused the complete destruction of 4T1 MCSs and possessed a PTT effect.

    The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

    This work was supported by the National Natural Science Foundation of China (Nos. 22078201, U1908202), Liaoning & Shenyang Key Laboratory of Functional Dye and Pigment (Nos. 2021JH13/10200018, 21–104–0–23).

    Supplementary material associated with this article can be found, in the online version, at doi:10.1016/j.cclet.2024.109735.


    1. [1]

      S. Diao, G. Hong, A.L. Antaris, et al., Nano Res. 8 (2015) 3027–3034. doi: 10.1007/s12274-015-0808-9

    2. [2]

      G. Hong, A.L. Antaris, H. Dai, Nat. Biomed. Eng. 1 (2017) 0010. doi: 10.1038/s41551-016-0010

    3. [3]

      Z. Lei, F. Zhang, Angew. Chem. Int. Ed. 60 (2021) 16294–16308. doi: 10.1002/anie.202007040

    4. [4]

      C. Li, G. Chen, Y. Zhang, et al., J. Am. Chem. Soc. 142 (2020) 14789–14804. doi: 10.1021/jacs.0c07022

    5. [5]

      S. Wang, H. Shi, L. Wang, et al., J. Am. Chem. Soc. 144 (2022) 23668–23676. doi: 10.1021/jacs.2c11223

    6. [6]

      J. Cao, B. Zhu, K. Zheng, et al., Front. Bioeng. Biotechnol. 7 (2020) 487. doi: 10.3389/fbioe.2019.00487

    7. [7]

      S. He, J. Song, J. Qu, et al., Chem. Soc. Rev. 47 (2018) 4258–4278. doi: 10.1039/C8CS00234G

    8. [8]

      G. Hong, J.C. Lee, J.T. Robinson, et al., Nat. Med. 18 (2012) 1841–1846. doi: 10.1038/nm.2995

    9. [9]

      G. Hong, Y. Zou, A.L. Antaris, et al., Nat. Commun. 5 (2014) 4206. doi: 10.1038/ncomms5206

    10. [10]

      Z. Hu, C. Fang, B. Li, et al., Nat. Biomed. Eng. 4 (2019) 259–271. doi: 10.1038/s41551-019-0494-0

    11. [11]

      Y. Jiang, K. Pu, Adv. Biosyst. 2 (2018) 1700262. doi: 10.1002/adbi.201700262

    12. [12]

      M.H. Lee, A. Sharma, M.J. Chang, et al., Chem. Soc. Rev. 47 (2018) 28–52. doi: 10.1039/C7CS00557A

    13. [13]

      Q. Shen, S. Wang, N. -D. Yang, et al., J. Lumin. 225 (2020) 117338. doi: 10.1016/j.jlumin.2020.117338

    14. [14]

      A.M. Smith, M.C. Mancini, S. Nie, Nat. Nanotechnol. 4 (2009) 710–711. doi: 10.1038/nnano.2009.326

    15. [15]

      S. Zhu, B.C. Yung, S. Chandra, et al., Theranostics 8 (2018) 4141–4151. doi: 10.7150/thno.27995

    16. [16]

      Y. Zhang, Y. Jia, S. Zhu, SmartMat 5 (2024) e1245. doi: 10.1002/smm2.1245

    17. [17]

      T. Li, T. Meyer, R. Meerheim, et al., J. Mater. Chem. A 5 (2017) 10696–10703. doi: 10.1039/C7TA02133J

    18. [18]

      Y. Liu, D. Gao, M. Xu, et al., J. Biophotonics 12 (2018) e201800237.

    19. [19]

      Z. Shi, X. Han, W. Hu, et al., Chem. Soc. Rev. 49 (2020) 7533–7567. doi: 10.1039/D0CS00234H

    20. [20]

      M. Strobl, A. Walcher, T. Mayr, et al., Anal. Chem. 89 (2017) 2859–2865. doi: 10.1021/acs.analchem.6b04045

    21. [21]

      M. Liu, S. Ma, M. She, et al., Chin. Chem. Lett. 30 (2019) 1815–1824. doi: 10.1016/j.cclet.2019.08.028

    22. [22]

      M. Kaur, A. Janaagal, N. Balsukuri, et al., Coord. Chem. Rev. 498 (2024) 215428. doi: 10.1016/j.ccr.2023.215428

    23. [23]

      Y. Wang, D. Zhang, K. Xiong, et al., Chin. Chem. Lett. 33 (2022) 115–122. doi: 10.1016/j.cclet.2021.06.083

    24. [24]

      Y. Su, Q. Hu, D. Zhang, et al., Chem. Eur. J. 28 (2022) e202103571. doi: 10.1002/chem.202103571

    25. [25]

      S.Z. Wang, Y. Guo, X. Zhang, et al., Adv. Funct. Mater. 33 (2023) 2303328. doi: 10.1002/adfm.202303328

    26. [26]

      A.M. Scott, T. Miura, A.B. Ricks, et al., J. Am. Chem. Soc. 131 (2009) 17655–17666. doi: 10.1021/ja907625k

    27. [27]

      H. Dang, D. Yin, Y. Tian, et al., J. Mater. Chem. B 10 (2022) 5279–5290. doi: 10.1039/D2TB00705C

    28. [28]

      K. Okino, S. Hira, Y. Inoue, et al., Angew. Chem. Int. Ed. 56 (2017) 16597–16601. doi: 10.1002/anie.201710354

    29. [29]

      G. Wu, F. Kong, J. Li, et al., J. Power Sources 243 (2013) 131–137. doi: 10.1016/j.jpowsour.2013.05.188

    30. [30]

      L. Bai, P. Sun, Y. Liu, et al., Chem. Commun. 55 (2019) 10920–10923. doi: 10.1039/C9CC03378E

    31. [31]

      Z. Shi, H. Bai, J. Wu, et al., Research 6 (2023) 0169. doi: 10.34133/research.0169

    32. [32]

      C. Li, Y. Xu, L. Tu, et al., Chem. Sci. 13 (2022) 6541–6549. doi: 10.1039/D2SC01518H

    33. [33]

      F. Würthner, T.E. Kaiser, C.R. Saha-Möller, Angew. Chem. Int. Ed. 50 (2011) 3376–3410. doi: 10.1002/anie.201002307

    34. [34]

      M.H.Y. Cheng, K.M. Harmatys, D.M. Charron, et al., Angew. Chem. Int. Ed. 58 (2019) 13394–13399. doi: 10.1002/anie.201907754

    35. [35]

      X. Zhang, H. Wang, D. Li, et al., Macromolecules 53 (2020) 3747–3755. doi: 10.1021/acs.macromol.0c00469

    36. [36]

      Y. Qu, W. Jin, Y. Wan, et al., Chin. Chem. Lett. 35 (2024) 108493. doi: 10.1016/j.cclet.2023.108493

    37. [37]

      N. Yang, S. Song, M.H. Akhtar, et al., J. Mater. Chem. B 11 (2023) 9712–9720. doi: 10.1039/D3TB01280H

    38. [38]

      A. Gorman, J. Killoran, C. O'Shea, et al., J. Am. Chem. Soc. 126 (2004) 10619–10631. doi: 10.1021/ja047649e

    39. [39]

      J.N. Schrauben, J.L. Ryerson, J. Michl, et al., J. Am. Chem. Soc. 136 (2014) 7363–7373. doi: 10.1021/ja501337b

    40. [40]

      W. Zhang, B. Li, H. Ma, et al., ACS Appl. Mater. Interfaces 8 (2016) 21465–21471. doi: 10.1021/acsami.6b05817

    41. [41]

      M.L. Agazzi, M.B. Ballatore, E. Reynoso, et al., Eur. J. Med. Chem. 126 (2017) 110–121. doi: 10.1016/j.ejmech.2016.10.001

    42. [42]

      Z. Li, C. Liu, H. Abroshan, et al., ACS Catal. 7 (2017) 3368–3374. doi: 10.1021/acscatal.7b00239

    43. [43]

      X. Wang, Y. Yu, K. Cheng, et al., Mikrochim. Acta 186 (2019) 842. doi: 10.1007/s00604-019-3924-5

    44. [44]

      S. Jiang, X. Wang, Z. Zhang, et al., Int. J. Nanomedicine 11 (2016) 5505–5518. doi: 10.2147/IJN.S115428

    45. [45]

      J. Chen, A.C. Sedgwick, S. Sen, et al., Chem. Sci. 12 (2021) 9916–9921. doi: 10.1039/D1SC01591E

    46. [46]

      H. Ning, Y. Yang, C. Lv, et al., Nano Res. 16 (2023) 12294–12303. doi: 10.1007/s12274-023-5923-4

    47. [47]

      Y.H. Kim, D.H. Jeong, D. Kim, et al., J. Am. Chem. Soc. 123 (2000) 76–86.

    48. [48]

      T.L.C. Jansen, Chem 5 (2019) 3010–3012. doi: 10.1016/j.chempr.2019.11.011

    49. [49]

      Y. Li, T. Ma, H. Jiang, et al., Angew. Chem. Int. Ed. 61 (2022) e202203093. doi: 10.1002/anie.202203093

    50. [50]

      C. Li, H. Ge, D. Zhang, et al., Sens. Actuator. B: Chem. 344 (2021) 130213. doi: 10.1016/j.snb.2021.130213

    51. [51]

      J. Huang, X. Sun, Y. Wang, et al., Ecotoxicol. Environ. Saf. 264 (2023) 115447. doi: 10.1016/j.ecoenv.2023.115447

    52. [52]

      M. Azharuddin, K. Roberg, A.K. Dhara, et al., Sci. Rep. 9 (2019) 20066. doi: 10.1038/s41598-019-56273-6

    53. [53]

      M. Wan, Q. Wang, X. Li, et al., Angew. Chem. Int. Ed. 59 (2020) 14458–14465. doi: 10.1002/anie.202002452

    54. [54]

      Y. Lu, F. Xu, Y. Wang, et al., Biomaterials 278 (2021) 121167. doi: 10.1016/j.biomaterials.2021.121167

  • Figure 1  Design of aza-BODIPY QLD-BDP with 1,7-julolidine-3,5-NMe2 groups for aggregation.

    Figure 2  Oak ridge thermal ellipsoid plot (ORTEP) views of QLD-BDP (CCDC: 2299513) (displacement ellipsoids at the 30% probability level). (a) Front, (b) side views of the molecular structure. Selected bond lengths (Å) and angles (°): N4-B1, 1.547(6); N5-B1: 1.546(6); B1-F1: 1.375(6); B1-F2: 1.425(6); N4-B1-N5: 106.2(4); F1-B1-F2: 110.1(4). (c) Normalized absorption of QLD-BDP in different solvents, respectively.

    Figure 3  (a) Self-assembly of QLD-BDP-NPs. (b) Molecular packing diagram of side view for QLD-BDP. (c) DLS of QLD-BDP-NPs in aqueous solution. (d) TEM of QLD-BDP-NPs in aqueous solution. Scale bar: 100 nm. (e) Photo of pure water and QLD-BDP-NPs in water. (f) Absorption of 2 µmol/L QLD-BDP-NPs (black curve) in CH2Cl2 and 10 µmol/L QLD-BDP-NPs in water (green curve). (g) Fluorescence of 10 µmol/L QLD-BDP-NPs in water. λex = 808 nm; laser source. (h) Temperature changes of QLD-BDP-NPs at different concentrations (40–80 µmol/L) under 808 nm laser irradiation (0.8 W/cm2). (i) Temperature response curves of QLD-BDP-NPs in aqueous solutions under irradiation and naturally cooling. (j) Linear fitting of –Lnθ and time.

    Figure 4  Colocalization of QLD-BDP-NPs with LTG, ETG or MTG for (a) lysosome, (b) endoplasmic reticulum, and (c) mitochondria in 4T1 cells (QLD-BDP-NPs: λex =640 nm, λem = 650–750 nm; Tracker: λex = 488 nm, λem = 500–600 nm; Scale bar: 20 µm). Cells were labeled with QLD-BDP-NPs (20 µg/mL) and LTG (1.0 µmol/L), ETG (1.0 µmol/L) or MTG (1.0 µmol/L), respectively. (Ⅰ) QLD-BDP-NPs labeled with red fluorescence; (Ⅱ) Organelles labeled with green fluorescence; (Ⅲ) Superposition of red and green fluorescence in yellow, indicating colocalization; (Ⅳ) Pearson coefficient of pixel intensity.

    Figure 5  (a) Imaging of MCSs of 4T1 cells (λex =640 nm, λem = 650–750 nm). (b) CLSM analysis image of 4T1 MCSs. MCSs were cultured in a medium PBS containing 20 or 40 µg/mL QLD-BDP-NPs. Use a laser at 850 nm (0.3 W/cm2, 900 s) for light irradiation. The images of the spherical formation for 12 h before irradiation were recorded, and the images of the first and second days with or without light irradiation were recorded. (c) Live/dead cell imaging of 4T1 MCS treated with QLD-BDP-NPs under dark and light irradiation (850 nm, 0.3 W/cm2, 900 s), respectively. Scale bar: 200 µm.

  • 加载中
计量
  • PDF下载量:  0
  • 文章访问数:  35
  • HTML全文浏览量:  1
文章相关
  • 发布日期:  2024-12-15
  • 收稿日期:  2023-12-24
  • 接受日期:  2024-02-21
  • 修回日期:  2024-02-20
  • 网络出版日期:  2024-03-08
通讯作者: 陈斌, bchen63@163.com
  • 1. 

    沈阳化工大学材料科学与工程学院 沈阳 110142

  1. 本站搜索
  2. 百度学术搜索
  3. 万方数据库搜索
  4. CNKI搜索

/

返回文章