Cellular uptake study of CAP/GPC-MPEG nanoparticle in breast cancer cells / 中国癌症杂志

ABSTRACT

Background and purpose:A pressing obstacle in clinical chemotherapy is drug resistance in breast cancer.A nano-delivery system,which has many advantages as a drug carrier,such as carrying anticancer drugs,can be used effectively to overcome drug resistance in tumors.This paper examined a new nano-delivery system,called calcium phosphate and glycerophosphocholine-mPEG(CAP/GPC-MPEG)composite nanoparticle and its influence on the cellular drug uptake of BCRP-over expressing mitoxantrone(MIT)-resistant breast cancer cell MCF-7/MIT.This paper will also examine its effect on overcoming drug resistance in the MCF-7/MIT cells.Methods:After the calcium phosphate and GPC-mPEG composite nanoparticles were designed and prepared,the entrapment efficiency and in vitro drug release of mitoxantrone-loaded nanoparticles were investigated.Quantitative comparisons were made between cellular uptake of drug-loaded nanoparticles and free drugs.Finally,a confocal laser scanning microscopy Was used to compare the subcellular distribution of drug-loaded nanoparticles and the free drugs.Results:Calcium phosphate and GPC-mPEG composite nanoparticles were nanoporous spherical particles with diameters between 50-100 mn.The MIT-loaded nanoparticles have an entrapment efficiency of(89.45±0.05)%.Although the drug-loaded nanoparticles showed an initial burst of drug release,it was followed by a more sustained release.The concentration of mitoxantrone was 1.89 times treated with MIT-loaded nanoparticles for 1 h compared to that treated with free mitoxantrone for 1 h in MCF-7/MIT cells.and which was 2.33 times in MCF-7 cells.Fluorescent red mitoxantrone appeared in the cytoplasm and nucleus of the MCF-7 and MCF-7,MIT cells treated with MlT-loaded nanoparticles whereas it is almost undetected in both cells treated with free mitoxantrone.Conclusion:Calcium phosphate and GPC-mPEG composite nanoparticles Can promote the cellular uptake and entering of mitoxantrone to the nucleus in MCF-7 and its corresponding BCRP-over expressing MIT-resistant MCF-7/MIT breast cancer cell lines.This nanoparticle is a potential nano-carrier for overcoming drug resistance in tumors.