The purpose of this work was to explore the feasibility of ethosomes for improving the anti-arthritic efficacy of topically administered tetrandrine, a bisbenzylisoquinoline alkaloid. Ethosomes were prepared by using ...The purpose of this work was to explore the feasibility of ethosomes for improving the anti-arthritic efficacy of topically administered tetrandrine, a bisbenzylisoquinoline alkaloid. Ethosomes were prepared by using the transmembrane pH-gradient loading method and characterized by mean diameter, morphology and entrapment efficiency. The prepared tetrandrine-loaded ethosomes exhibited spherical shape with about 78 nm of average diameter and entrapment efficiency of (52.87±3.81)%, whereas the liposomes had bigger size (99 nm) and higher entrapment efficiency (98.80±0.01)%. In addition, ethosomes exhibited favorable and enhanced penetration behavior as compared with liposomes. More importantly, tetrandrine-loaded ethosomes had a significantly better anti-adjuvant arthritis efficacy in rats compared to liposomes formulation, but no significant difference in the anti-arthritic efficacy between tetrandrine-loaded ethosomes and commercial dexamethasone ointment was observed. These results suggest that ethosomes would be a promising nanocarrier for topical delivery of tetrandrine across skin.展开更多
基金National Natural Science Foundation of China (Grant No. 81172990)National Development of Significant New Drugs of China (New Preparation and New Technology,Grant No. 2009zx09310-001)+1 种基金National Key Science Research Program of China (973 Program, Grant No. 2009CB930300)Innovation Team of Ministry of Education (Grant No. BMU20110263)
文摘The purpose of this work was to explore the feasibility of ethosomes for improving the anti-arthritic efficacy of topically administered tetrandrine, a bisbenzylisoquinoline alkaloid. Ethosomes were prepared by using the transmembrane pH-gradient loading method and characterized by mean diameter, morphology and entrapment efficiency. The prepared tetrandrine-loaded ethosomes exhibited spherical shape with about 78 nm of average diameter and entrapment efficiency of (52.87±3.81)%, whereas the liposomes had bigger size (99 nm) and higher entrapment efficiency (98.80±0.01)%. In addition, ethosomes exhibited favorable and enhanced penetration behavior as compared with liposomes. More importantly, tetrandrine-loaded ethosomes had a significantly better anti-adjuvant arthritis efficacy in rats compared to liposomes formulation, but no significant difference in the anti-arthritic efficacy between tetrandrine-loaded ethosomes and commercial dexamethasone ointment was observed. These results suggest that ethosomes would be a promising nanocarrier for topical delivery of tetrandrine across skin.
