Doxorubicin Encapsulated in TPGS-Modified 2D-Nanodisks Overcomes Multidrug Resistance.

Multidrug resistance (MDR) is regarded as a main obstacle for effective chemotherapy, and P-glycoprotein (P-gp)-mediated drug efflux has been demonstrated to be the key factor responsible for MDR. In this study, a novel pH-responsive hybrid drug delivery system was developed by conjugating d-α-tocopheryl polyethylene glycol 1000 succinate (TPGS), a kind of P-gp inhibitor, on the surface of laponite nanodisks to overcome MDR. The prepared LM-TPGS display excellent colloidal stability, a high encapsulation efficiency of doxorubicin (DOX), and a pH-responsive drug release profile. In vitro experiments verified that LM-TPGS/DOX could exhibit significantly enhanced therapeutic efficacy in treating DOX-resistant breast cancer cells (MCF-7/ADR) through inhibiting the activity of P-gp-mediated drug efflux and effectively accumulating DOX within cancer cells. In vivo results revealed that LM-TPGS/DOX outstandingly suppressed MCF-7/ADR tumors with low side effects. Therefore, the high drug payload, enhanced inhibition efficacy to drug-resistant cells, and low side effects make the LM-TPGS/DOX a promising nanoplatform to reverse MDR for effective chemotherapy.

Fabrication of TPGS-Stabilized Liposome-PLGA Hybrid Nanoparticle Via a New Modified Nanoprecipitation Approach: In Vitro and In Vivo Evaluation.

PURPOSE: In this study, a new modified nanoprecipitation approach that more efficient and simpler than conventional approach was developed to synthesize D-alpha-Tocopheryl polyethylene glycol 1000 succinate stabilized liposome-PLGA hybrid nanoparticle, loaded with simvastatin (ST-TLPN). METHODS: The optimum formulation was screened via investigation of the impact of TPGS mass within polymeric core and lipid shell on the physicochemical properties of nanoparticles respectively. FTIR, and drug release of ST-TLPN were also systematically determined. Finally, the cellular internalization was evaluated using the murine macrophage cell line, in vivo pharmacokinetic behavior and antiatherogenic efficacies were elaborately examined in atherosclerotic rabbit models. RESULTS: With the weight ratio of TPGS-to-PLGA in organic phase of 30% and TPGS-to-lipid in aqueous phase of 35%, ST-TLPN exhibited core-shell structure, sub-100 nm size, EE% of over 90% and a slow release profile. The excellent cellular uptake was displayed in RAW264.7 cell line. Improved pharmacokinetic behavior, and enhanced antiatherogenic efficacy of ST-TLPN in the model animals were also revealed compared with ST-loaded PLGA nanoparticles. CONCLUSION: These findings suggest the modified nanoprecipitation method holds great potential for fabricating LPN, aided by the multiple functions of TPGS. And the prepared TLPN is a promising delivery system for use in the pharmaceutical field.

Binary Polymeric Surfactant Mixtures for the Development of Novel Loteprednol Etabonate Nanomicellar Eyedrops.

The treatment of several ocular inflammatory conditions affecting different areas of the ocular globe involves the administration of topical ophthalmic formulations containing corticosteroids. This research was aimed at evaluating the solubilising efficacy of 5.0% w/w of different binary mixtures of commercial amphiphilic polymeric surfactants with the purpose of obtaining nanomicellar solutions containing a high amount of loteprednol etabonate (LE). The selected LE-TPGS/HS nanomicelles, containing 0.253 mg/mL of the drug, had a small size (=13.57 nm) and uniform distribution (Polydispersity Index = 0.271), appeared completely transparent and perfectly filterable through 0.2 µm membrane filter, and remained stable up to 30 days at 4 °C. The critical micellar concentration (CMCTPGS/HS) was 0.0983 mM and the negative value of the interaction parameter between the polymeric-surfactant-building unit (ßTPGS/HS = -0.1322) confirmed the ability of the polymeric surfactants to interact, favouring the dissolution of LE into nanomicelles. The disappearance of the endothermic peak of LE in the DSC analysis confirmed the interactions of LE with the polymeric surfactants. LE-TPGS/HS produced in vitro LE which sustained diffusion for 44 h (more than 40% of encapsulated LE). Furthermore, the lack of a significant cytotoxic effect on a sensitive corneal epithelial cell line makes it a candidate for further biological studies.

Vitamin E D-alpha-tocopheryl polyethylene glycol 1000 succinate-conjugated liposomal docetaxel reverses multidrug resistance in breast cancer cells.

OBJECTIVES: Multidrug resistance (MDR) remains a primary challenge in breast cancer treatment. In the present study, D-alpha-tocopheryl polyethylene glycol 1000 succinate (TPGS)-coated docetaxel-loaded liposomes were developed as a novel drug delivery system to reverse MDR and enhance breast cancer therapy compared with the traditional liposomes, DSPE-mPEG-coated liposomes (stealth liposomes) and commercial Taxotere® . KEY FINDINGS: Liposomes were prepared by thin - film dispersion method. Evaluations were performed using human breast cancer MCF-7 and resistant MCF-7/ADR cells. The reversal multidrug-resistant effect was assessed by P-gp inhibition assay, cytotoxicity, cellular uptake and apoptosis assay. RESULTS: The TPGS-chol-liposomes were of an appropriate particle size (140.0 ± 6.0 nm), zeta potential (-0.196 ± 0.08 mv), high encapsulation efficiency (99.0 ± 0.9) and favourable in vitro sustained release. The TPGS-coated liposomes significantly improved cytotoxicity and increased the intracellular accumulation of docetaxel in both types of breast cancer cells. The TPGS-coated liposomes were confirmed to induce apoptosis via a synergistic effect between docetaxel and TPGS. It was demonstrated that TPGS enhanced the intracellular accumulation of drug by inhibiting overexpressed P-glycoprotein. CONCLUSIONS: The TPGS-conjugated liposomes showed significant advantages in vitro compared with the PEG-conjugated liposomes. The TPGS-conjugated liposomes could reverse the MDR and enhance breast cancer therapy.

A thorough analysis of the effect of surfactant/s on the solubility and pharmacokinetics of (S)-zaltoprofen.

Until now, there are no publications about the preformulation studies on (S)-zaltoprofen ((S)-ZPF). Hence, we first investigated the solubility of (S)-ZPF, screened solubilizers and performed the pharmacokinetic study of (S)-ZPF in the presence of the solubilizers. The measurement of the solubility of (S)-ZPF in 26 different solvents was carried out, including d-alpha tocopheryl polyethylene glycol 1000 succinate (TPGS), 2-hydroxypropyl-ß-cyclodextrin (HPCD), and mixtures of individual solvent. The plasma concentration of (S)-ZPF and the amount of (S)-ZPF retained in stomach were determined after oral (35.0 mg/kg) and intravenous (5.0 mg/kg) administration. The solubility of (S)-ZPF showed an increase of 484-fold in TPGS compared to its aqueous solubility. There was a significant increase of AUC0-24   h for pure (S)-ZPF in the TPGS group (813.59 ±â€¯64.17 µg⋅h/ml) in comparison with AUC0-24   h in the HPCD group (595.57  ±â€¯71.76 µg⋅h/ml) and water group (465.57 ±â€¯90.89 µg⋅h/ml). In addition, the Tmax of (S)-ZPF in the TPGS group was 2 h, much faster than that in the HPCD or water groups (5.50 or 5.67 h, respectively). This suggested that TPGS played a significant role in the increase of solubility and bioavailability of (S)-ZPF.

Progress in microRNA delivery.

MicroRNAs (miRNAs) are non-coding endogenous RNAs that direct post-transcriptional regulation of gene expression by several mechanisms. Activity is primarily through binding to the 3' untranslated regions (UTRs) of messenger RNAs (mRNA) resulting in degradation and translation repression. Unlike other small-RNAs, miRNAs do not require perfect base pairing, and thus, can regulate a network of broad, yet specific, genes. Although we have only just begun to gain insights into the full range of biologic functions of miRNA, their involvement in the onset and progression of disease has generated significant interest for therapeutic development. Mounting evidence suggests that miRNA-based therapies, either restoring or repressing miRNAs expression and activity, hold great promise. However, despite the early promise and exciting potential, critical hurdles often involving delivery of miRNA-targeting agents remain to be overcome before transition to clinical applications. Limitations that may be overcome by delivery include, but are not limited to, poor in vivo stability, inappropriate biodistribution, disruption and saturation of endogenous RNA machinery, and untoward side effects. Both viral vectors and nonviral delivery systems can be developed to circumvent these challenges. Viral vectors are efficient delivery agents but toxicity and immunogenicity limit their clinical usage. Herein, we review the recent advances in the mechanisms and strategies of nonviral miRNA delivery systems and provide a perspective on the future of miRNA-based therapeutics.