A glutathione-sensitive drug delivery system based on carboxymethyl chitosan co-deliver Rose Bengal and oxymatrine for combined cancer treatment.

At present, monotherapy of tumor has not met the clinical needs, due to high doses, poor efficacy, and the emergence of drug resistance. Combination therapy can effectively solve these problems, which is a better option for tumor suppression. Based on this, we developed a novel glutathione-sensitive drug delivery nanoparticle system (OMT/CMCS-CYS-RB NPs) for oral cancer treatment.

Glutathione-sensitive IPI-549 nanoparticles synergized with photodynamic Chlorin e6 for the treatment of breast cancer.

We combined phosphoinositol-3-kinin inhibitor IPI-549 and photodynamic Chlorin e6 (Ce6) on carboxymethyl chitosan to develop a novel drug delivery nanoparticle (NP) system (Ce6/CMCS-DSP-IPI549) and evaluate its glutathione (GSH) sensitivity and targeting ability for breast cancer treatment. The NPs were spherical with a uniform size of 218.8 nm, a stable structure over 7 days.

1-MT grafted carboxymethyl chitosan and its nanoparticles: Preparation, characterization and evaluation.

This work aims to synthesize two novel 1-MT (1-Methyl-DL-tryptophan) grafted CMCS (carboxymethyl chitosan) polymer prodrugs CMCS-amido-1-MT and CMCS-ester-1-MT, and to further manufacture their nanoparticles for potential biomedical applications. The polymeric prodrugs are prepared by three-step chemical synthesis. The chemical structure of drugs is confirmed by FTIR and 1H-NMR.

Tuning mPEG-PLA/vitamin E-TPGS-based mixed micelles for combined celecoxib/honokiol therapy for breast cancer.

This study aimed to develop, evaluate, and optimize the mPEG-PLA/vitamin E-TPGS mixed micelle drug delivery system to encapsulate celecoxib (CXB) and honokiol (HNK) for intravenous treatment of breast cancer. To this end, we formulated CXB-loaded mPEG-PLA/vitamin E-TPGS (PV-CXB) and HNK-loaded mPEG-PLA/vitamin E-TPGS (PV-HNK) mixed micelles and analyzed their characteristics. The 4T1 cell line was used for cytotoxicity determination and cellular uptake experiments, and for establishing a 4T1-bearing mouse model for histopathology, immunofluorescence, terminal deoxynucleotidyl transferase-mediated nick end labeling, and Western blot analysis.