The skin delivery of tofacitinib citrate using transethosomes and hybridized ethosomes/nanostructured lipid carriers for vitiligo therapy: Dermatopharmacokinetics and in vivo assays.

Vitiligo is an autoimmune disease where its current treatment strategies are lengthy in course and do not guarantee complete cure. Tofacitinib citrate (JAK inhibitor) is a potential cure of vitiligo through halting JAK-STAT pathway preventing the destruction of melanocytes. The dermato-pharmacokinetics of the prepared transethosomes (Et) and the hybridized ethosomes/nanostructured lipid carriers (Eth/NLC), namely formulations; M.E-Cr and M.E-S.M, were evaluated. In addition, in vivo studies on C57/BL6 vitiligo mouse model were conducted to confirm effectiveness of Tofacitinib citrate delivery. The results unveiled that the transethosomes (359.46 ± 11.82 nm) were suitable for dermal delivery while M.E-Cr (179.64 ± 11.16 nm), a hybrid Eth/NLC formulation, was mostly suitable for transdermal delivery. Nevertheless, another hybrid formulation, M.E-S.M (253.60 ± 14.64 nm), was apt for both dermal and transdermal delivery. The histopathology confirmed re-pigmentation of mice skin where formulations Et and M.E-S.M showed severe pigmentation compared to the control healthy and induced mice. On the other hand, M.E-Cr showed mild pigmentation. Immunohistochemical assay was performed to evaluate infiltration of CD 8+T-lymphocytes where mild infiltration was observed. However, the systemic IFN-γ was significantly reduced in case of M.E-Cr and M.E-S.M. The present work proposed potential effective formulations to improve the treatment of vitiligo with potential reduction in the total therapeutic dose, drug's side effects, and treatment costs.

Chimeric HDAC inhibitors: Comprehensive review on the HDAC-based strategies developed to combat cancer.

Recently, molecular hybridization paradigm became an interesting and smart way to defeat the multifaceted cancer disease by a single molecular entity that acts via several mechanisms just like a magic bullet. Also, HDAC is an important epigenetic target in drug discovery, and the HDAC inhibitors showed successful pattern as cytotoxic agents. Because of their flexible structure activity relationship, it was easy to link them to other anticancer scaffolds. So, many dual action HDAC inhibitors have been developed and most of these hybrids have higher potency than the constituting parents in fighting of the cancer cells. This review describes potential applications of chimeric HDAC inhibitors, which simultaneously modulate not only HDAC but also multiple targets, in treatment of relapsing and drug-resistant cancers. We have nearly collected most of the reported dual action HDAC inhibitors yet to provide a comprehensive guide for the drug discovery process for developing more efficient anticancer agents.