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Controllable Fabrication of Mono-Shelled Hollow Sphere CaCO3 Microspheres via CO2 Bubbling Method:Potential Dye Carrier for Cell Bio-imaging
- Corresponding author: ZHANG Jian-Bin, tadzhang@pku.edu.cn
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Citation:
LIU Jiang, SHA Feng, YANG Ting-Yu, MA Liang, ZHANG Jian-Bin. Controllable Fabrication of Mono-Shelled Hollow Sphere CaCO3 Microspheres via CO2 Bubbling Method:Potential Dye Carrier for Cell Bio-imaging[J]. Chinese Journal of Inorganic Chemistry,
;2018, 34(9): 1688-1700.
doi:
10.11862/CJIC.2018.220
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Mono-shelled hollow sphere CaCO3 microspheres were prepared in the presence of L-methionine (L-Met) via a CO2 bubbling method; after that, the effects of L-Met adding amount, CO2 flow rate, and temperature on morphology, size, and phase composition of CaCO3 have been systemically explored. As a potential guest molecule carrier, the as-synthesized hollow sphere CaCO3 microspheres could load with rhodamine B (RhB) to prepare a novel luminescent composite material (RhB@hollow-CaCO3). This luminescent composite material not only presented good biocompatibility to the A-549 lung cancer cells (A-549 LCCs) and HO8910 ovarian cancer cells (HO8910 OCCs), but also had the ability of luminescence in above cells.
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