Effect of chemical enhancers on percutaneous absorption of daphnetin in isopropyl myristate vehicle across rat skin in vitro

Daphnetin: A bioactive natural coumarin with diverse therapeutic potentials

Daphnetin (DAP), a coumarin derivative extracted from Daphne species, is biologically active phytochemical with copious bioactivities including anti-inflammatory, anti-oxidant, neuroprotective, analgesic, anti-pyretic, anti-malarial, anti-bacterial, anti-arthritic, neuroprotective, hepatoprotective, nephroprotective, and anti-cancer activities. A wide range of studies have been conducted exploring the significance and therapeutic potential of DAP. This study reviewed various databases such as NCBI, PubMed, Web of Science, Scopus and Google Scholar for published research articles regarding the sources, synthesis, and various bioactivities of DAP using different key words, including but not limited to “pharmacological activities,” “sources,” “neuroprotective effect,” “synthesis,” “cancer,” “anti-inflammatory effect” of “daphnetin.” Furthermore, this review encompasses both in-vivo and in-vitro studies on DAP for treating various diseases. A comprehensive review of the literature revealed that the DAP had a promising pharmacological and safety profile, and could be employed as a pharmaceutical moiety to treat a variety of illnesses including microbial infections, cancer, arthritis, hepatic damage, inflammation and neurological anomalies. The current review intends to provide an in-depth focus on all pharmacological activities and therapeutic approaches for the pharmaceutical and biomedical researchers.

Development of Saikosaponin D Liposome Nanocarrier with Increased Hepatoprotective Effect Against Alcoholic Hepatitis Mice

The mortality rate of ethanol induced liver disease has substantially raised to alert level with an increasing use of alcohol, but development of definite hepatoprotective drug is still challenging. The efficacy of Saikosaponin D, one of the natural herbal medicine has been studied in different diseases. Nonetheless, its clinical application is restricted by poor bioavailability, stability and solubility. This study sought to develop a Saikosaponin D loaded liposome via thin film hydration method. The surface morphology, encapsulation efficiency and drug loading capacity were detected with transmission electron microscopy and HPLC, in vitro dissolution was via dialysis method, but efficacy and safety evaluation was through pharmacokinetics, while the assessment of hepatoprotective activity on alcohol induced acute hepatitis mice models was conducted. The optimized liposomes showed significant greater therapeutic effect on liver, through decreased serum levels of alanine transaminase (ALT) and aspartate transaminase (AST), malondialdehyde (MDA), tumor necrosis factor alpha (TNF-α), total cholesterol (TC) and triglyceride (TG) in liver homogenate. In contrast, levels of glutathione peroxidase (GSH-Px) and total superoxide dismutase (T-SOD) were increased significantly. Pathological study exhibited remarkable alteration of hepatitis liver architecture to almost normal state after administration of Saikosaponin D liposome. The increased hepatoprotective effect of Saikosaponin D liposome was observed during the attenuation of alcoholic hepatitis in mice, which might be ascribable to the anti-oxidative and anti-inflammatory properties of the drug. This study provides a theoretical basis for developing advanced system of Saikosaponin D delivery for the promotion of the therapeutic effects of the liposome against various kinds of diseases.

[Pharmaceutical Properties of Anti-inflammatory Analgesic Patches Using Acrylic Polymer]

The mock patches were prepared with novel acrylic polymers as adhesive layer where biphenyl-4-ylacetic acid (BAA) or 2-(2-fluorobiphenyl-4-yl) propanoic acid (FPA) was used as model active pharmaceutical ingredients (APIs). In addition, the mock patches were formulated with typical ester ingredients for transdermal dosage forms. The molecular state of the model APIs in the adhesive layer was observed by polarized microscope and microscopic Raman spectroscopy, which contains both conventional and low frequency (LF) region. Crystallization behavior would be depended on the interaction between API and polymers in the adhesive layer. In particular, LF Raman measurement was useful to discriminate API polymorphs. The pharmaceutical properties including dissolution and skin permeation of APIs were also evaluated for mock patches. The drug release and transdermal permeation were enhanced with the ester ingredients such as isopropyl myristate and diethyl sebacate due to their diffusion to the test solution or the skin stratum corneum as well as reducing the interaction between API and polymers. Further, the tack strength was not changed, but the peel strength was weakened by the additives. Thus, the adhesive properties were controllable by formulation with the additives. These findings could enable to evaluate the interaction between API and the polymers for adhesive layer and select the appropriate polymer and additives for used APIs when designing the drug products.

Enhancement in the Transdermal and Localized Delivery of Honokiol Through Breast Tissue

Honokiol is a natural phenolic anti-cancer compound isolated from an extract of seed cones from Magnolia grandiflora. This study investigated the transdermal delivery of honokiol using various enhancement methods and to explore the potential of honokiol to treat breast cancer directly via delivery through mammary papilla. Poration of dermatomed human skin with microneedles significantly increased the delivery of honokiol by nearly 3-fold (97.81 ± 18.96 μg/cm²) compared with passive delivery (32.56 ± 5.67 μg/cm²). Oleic acid was found to be the best chemical penetration enhancer, increasing the delivery almost 27-fold (868.06 ± 100.91 μg/cm²). Addition of oleic acid also resulted in better retention of drug in the porcine mammary papilla (965.41 ± 80.26 μg/cm²) compared with breast skin (294.16 ± 8.49 μg/cm²). Anti-cancer effect of honokiol was demonstrated with the decrease in the release of cytokine IL-6 and further suppression of Ki-67 proliferative protein. In addition, the topical honokiol formulation investigated was found to be safe and non-irritant. In summary, both microneedles and chemical enhancers can improve the absorption of honokiol through skin. Directly applying honokiol on mammary papilla is a potential administration route which can increase localized delivery into breast tissue.

Novel dendritic derivatives of unsaturated fatty acids as promising transdermal permeation enhancers for tenofovir

Novel dendritic ester derivatives of unsaturated fatty acids as potential transdermal permeation enhancers.