Defense against oxidative stress in Caenorhabditis elegans by dark tea.

Dark tea, rich in nutricines including tea polyphenols and free amino acids, is a kind of post-fermented tea. The potential application of nutricines against oxidative damage and senescence, which drives animal health maintenance and disease prevention, has attracted considerable interest. In this study, the effect of dark tea and its effects on longevity and defense against oxidative stress was investigated in the Caenorhabditis elegans (C. elegans) model. Under normal conditions, dark tea extended the lifespan without significant impairment of propagation. It also improved the motility, alleviated the fat accumulation and apoptosis. Additionally, orally administered dark tea could significantly decrease the level of reactive oxygen species (ROS) and resulted in a superior lifespan in H2O2-induced oxidative stressed C. elegans. In antioxidant assays in vitro, dark tea was found to be rich in strong hydroxyl, DPPH and ABTS+ free radical scavenging capacity. Interestingly, mRNA sequence analyses further revealed that dark tea may catalyze intracellular relevant oxidative substrates and synthesize antioxidants through synthetic and metabolic pathways. These results suggest that dark tea is worth further exploration as a potential dietary supplement for the maintenance of animal health and the prevention of related diseases.

Reverse screening approach to identify potential anti-cancer targets of dipyridamole.

Dipyridamole (DIP) inhibits thrombus formation when given chronically, and causes vasodilation over a short time. To date, DIP can increase the anticancer drugs (5-fluorouracil, methotrexate, piperidine, vincristine) concentration in cancer cells and hence enhance the efficacy of treatment cancer. The inhibition of DIP may result in increased 5-fluorouracil efficacy and diminish the drug side effects. But the actual molecular targets remain unknown. In this study, reverse protein-ligands docking, and quantum mechanics were used to search for the potential molecular targets of DIP. The quantum mechanics calculation was performed by using Gaussian 03 program package. Reverse pharmacophore mapping was used to search for potential molecular target candidates for a given small molecule. The docking study was used for exploring the potential anti-cancer targets of dipyridamole. The two predicted binders with the statistically significant prediction are dihydropyrimidine dehydrogenase (DPD) (PDB Id: 1GTE) and human spindle checkpoint kinase Bub1 (PDB Id: 3E7E). Structure analysis suggests that electrostatic interaction and hydrogen bonding play an important role in their binding process. The strong functional linkage of DIP and 5FU supports our prediction. In conclusion, these results generate a tractable set of anticancer proteins. The exploration of polypharmacology will provide us new opportunities in treating systematic diseases, such as the cancers. The results would generate a tractable set of anticancer target proteins for future experimental validations.

Proniosome-derived niosomes for tacrolimus topical ocular delivery: in vitro cornea permeation, ocular irritation, and in vivo anti-allograft rejection.

The objective of this study was to develop proniosome-derived niosomes for topical ophthalmic delivery of Tacrolimus (FK506). The FK506 loaded proniosomes containing poloxamer 188 and lecithin as surfactants, cholesterol as a stabilizer, and minimal amount of ethanol and trace water reconstituted to niosomes prior to use. The stability of FK506 loaded proniosomes was assessed, and the morphology, size, zeta potential, surface tension, and entrapment efficiency of the derived niosomes were characterized, indicating they were feasible for instillation in the eyes. The in vitro permeation of FK506 through the freshly excised rabbit cornea, the cumulative permeation amount of FK506 from niosomes, and the drug retention in the cornea all exhibited significant increase as compared to 0.1% FK506 commercial ointments. The in vivo ocular irritation test of 0.1% FK506 loaded niosomes instilled 4 times per day in rat eyes for 21 consecutive days showed no irritation and good biocompatibility with cornea. The in vivo anti-allograft rejection assessment was performed in a Sprague-Dawley (SD) rat corneal xenotransplantation model. The results showed treatment with 0.1% FK506 loaded niosomes delayed the occurrence of corneal allograft rejection and significantly prolonged the median survival time of corneal allografts to13.86±0.80days as compared with those treated with 1% Cyclosporine (CsA) eye drops, drug-free niosomes, or untreated. In conclusion, the proniosome-derived niosomes may be a promising vehicle for effective ocular drug delivery of FK506.

Percutaneous delivery of econazole using microemulsion as vehicle: formulation, evaluation and vesicle-skin interaction.

This project was carried out to exploit the feasibility of using microemulsion (ME) as an alternative carrier for percutaneous delivery econazole nitrate (ECN) and elucidate the underlying mechanism of permeation enhancement. The ME was developed based on Labrafil M 1944 Cs as oil phase, Solutol HS15 and Span 80 as surfactants, Transcutol P as cosurfactant and water as aqueous phase. The solubility of ECN was firstly determined for screening the ingredients of the system. Pseudo-ternary phase diagrams were constructed to formulate ME and select surfactant and cosurfactant. Central composite design-response surface methodology (CCD-RSM) was utilized to optimize the formulation of ME. The ECN loaded ME was characterized in terms of morphology, particle size and size distribution, pH value, refractive index, viscosity and conductivity, and storage stability of the ECN loaded ME was assayed. Percutaneous permeation of ECN from ME in vitro through rat skin was investigated in comparison with PBS aqueous suspension (1%, w/w), and results showed that ME enhanced drug retention in the skin and permeation through the skin, the enhancement of ME on skin deposition was further visualized through fluorescent-labeled ME by confocal laser scanning microscope (CLSM). The action mechanism of ME on improving percutaneous delivery was studied by performing a pretreatment test. It can speculate that ME does not simply behave as enhancer but it also acts as drug carrier. Furthermore, ME-skin interaction was elucidated through transmission electron microscope (TEM), and attenuated total reflectance fourier-transform infrared (ATR-FTIR). TEM was performed to visualize the micro morphological change of skin. ATR-FTIR was carried out to investigate the molecular vibrations of the components of stratum corneum (SC). The results indicate that the ME system may be a promising vehicle for percutaneous delivery of ECN.