Construction and cellular uptake behavior of redox-sensitive docetaxel prodrug-loaded liposomes.

A redox-responsive docetaxel (DTX) prodrug consisting of a disulfide linkage between DTX and vitamin E (DTX-SS-VE) was synthesized in our laboratory and was successfully formulated into liposomes. The aim of this study was to optimize the formulation and investigate the cellular uptake of DTX prodrug-loaded liposomes (DPLs). The content of DTX-SS-VE was determined by ultrahigh-performance liquid chromatography (UPLC). The formulation and process were optimized using entrapment efficiency (EE), drug-loading (DL), particle size and polydispersity index (PDI) as the evaluation indices. The optimal formulation was as follows: drug/lipid ratio of 1:12, cholesterol/lipid ratio of 1:10, hydration temperature of 40 °C, sonication power and time of 400 W and 5 min. The EE, DL and particle size of the optimized DPLs were 97.60 ± 0.03%, 7.09 ± 0.22% and 93.06 ± 0.72 nm, respectively. DPLs had good dilution stability under the physiological conditions over 24 h. In addition, DPLs were found to enter tumor cells via different pathways and released DTX from the prodrug to induce apoptosis. Taken together, the optimized formulation and process were found to be a simple, stable and applicable method for the preparation of DPLs that could successfully escape from lysosomes.

Reduction-sensitive Paclitaxel Prodrug Self-assembled Nanoparticles with Tetrandrine Effectively Promote Synergistic Therapy Against Drug-sensitive and Multidrug-resistant Breast Cancer.

Codelivery of multiple drugs with complementary anticancer mechanisms by nanocarriers offers an effective strategy to treat cancers. Herein, conjugation (PTX-SS-VE) of paclitaxel (PTX) to vitamin E succinate (VE) self-assembled nanoparticles were used to load tetrandrine (TET) for combinational treatment against breast carcinoma. The ratio of PTX-SS-VE and TET was optimized. Compared with PTX, the TET/PTX-SS-VE coloaded nanoparticles (TPNPs) demonstrated superior cytotoxicity against both MCF-7 cells and MCF-7/Adr cells. TPNPs were facilitated to release PTX and TET under a highly reductive environment in tumor cells through the in vitro simulative release study. Cell apoptosis study and Western blotting analysis exhibited TPNPs could significantly increase cell apoptosis via modulating the levels of Bcl-2 protein and Caspase-3, which might be triggered by excess cellular reactive oxygen species (ROS) production through an intracellular ROS detection test. Cellular uptake study showed that TET could increase PTX accumulation in MCF-7/Adr cells but not in MCF-7 cells, which explained stronger synergetic efficacy of TPNPs on MCF-7/Adr cells. Overall, encapsulation of hydrophobic drugs, such as TET, in reduction-sensitive PTX-SS-VE nanoparticles provides a prospective strategy to effectively overcome the multidrug resistance of tumor cells in a synergistic manner. Such a uniquely small molecular weight prodrug-nanocarrier opens up new perspectives for the development of nanomedicines.

Paclitaxel-Paclitaxel Prodrug Nanoassembly as a Versatile Nanoplatform for Combinational Cancer Therapy.

Recently, nanomedicine without drug carriers has attracted many pharmacists' attention. A novel paclitaxel-s-s-paclitaxel (PTX-s-s-PTX) conjugate with high drug loading (∼78%, w/w) was synthesized by conjugating paclitaxel to paclitaxel by using disulfide linkage. The conjugate could self-assemble into uniform nanoparticles (NPs) with 1,1-dioctadecyl-3,3,3,3-tetramethylindotricarbocyanine iodide (DiR) encapsulated within the core of PTX-s-s-PTX NPs for photothermal therapy (PTT). The DiR-loaded self-assembled nanoparticles (DSNs) had a mean diameter of about 150 nm and high stability in biological condition. A disulfide bond is utilized as a redox-responsive linkage to facilitate a rapid release of paclitaxel in tumor cells. DSNs indicated significant cytotoxicity as a result of the synergetic chemo-thermal therapy. DSNs were featured with excellent advantages, including high drug loading, redox-responsive releasing behavior of paclitaxel, capability of loading with photothermal agents, and combinational therapy with PTT. In such a potent nanosystem, prodrug and photothermal strategy are integrated into one system to facilitate the therapy efficiency.

A unique highly hydrophobic anticancer prodrug self-assembled nanomedicine for cancer therapy.

In contrast with common thought, we generated highly hydrophobic anticancer prodrug self-assembled nanoparticles without the aid of surface active substances, based on the conjugation of docetaxel to d-α-tocopherol succinate. The reduction-sensitive prodrug was synthesized with a disulfide bond inserted into the linker and was compared with a control reduction-insensitive prodrug. The morphology and stability of self-assembled nanoparticles were investigated. Cytotoxicity and apoptosis assays showed that the reduction-sensitive nanoparticles had higher anticancer activity than the reduction-insensitive nanoparticles. The reduction-sensitive nanoparticles exhibited favorable in vivo antitumor activity and tolerance compared with docetaxel Tween80-containing formulation and the reduction-insensitive nanoparticles. Taken together, the unique nanomedicine demonstrated a number of advantages: (i) ease and reproducibility of preparation, (ii) high drug payload, (iii) superior stability, (iv) prolonged circulation, and (v) improved therapeutic effect. This highly reproducible molecular assembly strategy should motivate the development of new nanomedicines.

Aflatoxin B1 Detection Using a Highly-Sensitive Molecularly-Imprinted Electrochemical Sensor Based on an Electropolymerized Metal Organic Framework.

A sensitive electrochemical molecularly-imprinted sensor was developed for the detection of aflatoxin B1 (AFB1), by electropolymerization of p-aminothiophenol-functionalized gold nanoparticles in the presence of AFB1 as a template molecule. The extraction of the template leads to the formation of cavities that are able to specifically recognize and bind AFB1 through π-π interactions between AFB1 molecules and aniline moities. The performance of the developed sensor for the detection of AFB1 was investigated by linear sweep voltammetry using a hexacyanoferrate/hexacyanoferrite solution as a redox probe, the electron transfer rate increasing when the concentration of AFB1 increases, due to a p-doping effect. The molecularly-imprinted sensor exhibits a broad linear range, between 3.2 fM and 3.2 µM, and a quantification limit of 3 fM. Compared to the non-imprinted sensor, the imprinting factor was found to be 10. Selectivity studies were also performed towards the binding of other aflatoxins and ochratoxin A, proving good selectivity.