To introduce pH sensitivity into the DSPE-PEG-based micellar system and achieve the quick intracellular drug release in response to the acidity in endosomes, a mixed polymeric micelle was developed based on three grafted copolymers, including 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-polyethylene glycol-2000(DSPE-PEG2000), antinucleosome antibody (mAb 2C5)-modified DSPE-PEG3400 (DSPE-PEG3400-2C5), and poly(ethylene glycol)-coupled poly(l-histidine) (PHIS-PEG2000). The structure of PHIS-PEG2000 was confirmed by 1H NMR spectroscopy. The mixed micelles with the diameter ranging from 110 to 135nm were prepared using a dialysis method against pH 7.6 PBS. Paclitaxel (PCT) was used as a model drug, the encapsulation efficiency and loading content of PCT were 88% and 5%, respectively. The mixed micelles composed with 50wt% of PHIS-PEG2000 showed the desired pH-dependent drug release property with much faster drug release than micelles without PHIS-PEG2000. At pH around 5.5, about 75–95% of the loaded drug was released within 2 h. The MTT assay showed PCT-loaded mixed micelles had higher cytotoxicity at pH 5.8 than that at pH 7.4. Further modification of the mixed micelles with anti-cancer nucleosome- specific monoclonal antibody 2C5 significantly increased their cellular uptake efficiency and cytotoxicity. Thus, the low pH in endosomes could trigger the PCT release from the pH-sensitive mixed micelles after 2C5-mediated endocytosis. The results of this study suggest that the mixed micelles (DSPE-PEG2000/DSPE-PEG3400-2C5/PHIS-PEG2000) could enhance the tumor cell-specific internalization and trigger the quick drug release, resulting in the improved anti-cancer efficacy.
Polymeric micelles (PMs) have been widely investigated as nanocarriers for drug delivery and cancer treatments due to their excellent physicochemical properties, drug loading and release capacities, facile preparation methods, biocompatibility, and tumor targetability. They can be easily engineered with various functional moieties to further improve their performance in terms of bioavailability, circulation time, tumor specificity, and anticancer activity. The stimuli-sensitive PMs capable of responding to various extra- and intracellular biological stimuli (eg, acidic pH, altered redox potential, and upregulated enzyme), as well as external artificial stimuli (eg, magnetic field, light, temperature, and ultrasound), are considered as “smart” nanocarriers for delivery of anticancer drugs and/or imaging agents for various therapeutic and diagnostic applications. In this article, the recent advances in the development of stimuli-responsive PMs for drug delivery, imaging, and cancer therapy are reviewed. The article covers the generalities of stimuli-responsive PMs with a focus on their major delivery strategies and newly emerging technologies/nanomaterials, discusses their drawbacks and limitations, and provides their future perspectives.
Elemental tellurium (Te) nanoparticles are increasingly important in a variety of applications such as thermoelectricity, photoconductivity, and piezoelectricity. However, they have been explored with limited success in their biomedical use, and thus a tremendous challenge still exists in the exploration of Te nanoparticles that can treat tumors as an effective anticancer agent. Here, we introduce bifunctional Te nanodots with well-defined nanostructure as an effective anticancer agent for photo-induced synergistic cancer therapy with tumor ablation, which is accomplished using hollow albumin nanocages as a nanoreactor. Under near-infrared light irradiation, Te nanodots can produce effective photothermal conversion, as well as highly reactive oxygen species such as •O and dismutated •OH via a type-I mechanism through direct electron transfer, thereby triggering the potent in vivo hyperthermia and simultaneous intracellular reactive oxygen species at tumors. Moreover, Te nanodots possess perfect resistance to photobleaching, effective cytoplasmic translocation, preferable tumor accumulation, as well as in vivo renal elimination, promoting severe photo-induced cell damage and subsequent synergy between photothermal and photodynamic treatments for tumor ablation. These findings provide the insight of elemental Te nanodots for biomedical research.
Transition metal sulfide nanocrystals are developed as a theranostic platform through the protein-nanoreactor approach with facile functionalization for multimodal NIRF/PA/SPECT/CT imaging and photothermal tumor ablation.
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