Different Influences of Lipofection and Electrotransfection on In Vitro Gene Delivery to Primary Cultured Cortex Neurons.

BACKGROUND: Many pain states are linked to central nervous system (CNS) diseases involving the dysfunction of dendritic arborization, making restoration a promising therapeutic strategy. Transfection of primary cortex neurons offers the possibility to study mechanisms which are important for the restoration of proper arborization. Its progress is, however, limited at present due to the lack of suitable gene transfer techniques. OBJECTIVE: To obtain better insight into the transfection potential of currently used techniques, 2 non-viral transfection methods, lipofection and gene electrotransfer (GET), were compared. STUDY DESIGN: This is a comparison study performed on cultured cells. METHODS: The transfection efficiency and neuronal viability, as well as the neuronal dendritic arborization after lipofection or GET, were compared. Primary cultured cortex neurons were transfected with the pEGFP-N1 plasmid, either using Lipofectamine 2000 (2, 3, or 4µL) or with electroporation, with our previously optimized protocol (200V/25 ms). RESULTS: Transfection efficiency and cell viability were inversely proportional for lipofection. The appropriate ratio of Lipofectamine and plasmid DNA provides optimal conditions for lipofection. Although GET offered higher transfection efficiency, it could not induce complex dendritic arborization, which made it unsuitable for in vitro gene transfer into cortex neurons. LIMITATIONS: Limitations include species variability and translational applicability for CNS diseases and pain states related to potential toxicity. CONCLUSIONS: Based on these findings, lipofection might be advantageous for in vitro application to primary cultured cortex neurons. Pain states, stress mediated pathogenesis, and certain CNS diseases might potentially utilize this important technique in the future as a therapeutic modality.

[Change of the content of chemical constituents and anti-oxidative action of the decoction of radix ginseng combined with Flos Lonicerae, radix Polygoni Multiflori and Radix Astragali].

Ginsenosides in the decoction of Radix Ginseng, Radix Ginseng with Flos Lonicerae, Radix Polygoni Multiflori or Radix Astragali have been investigated by high performance liquid chromatography (HPLC) and electrospray ionization mass spectrometric method (ESI-MS). Change of the content of ginsenosides was nonlinear in diverse combinative proportion of Radix Ginseng with Flos Lonicerae, while the stripping of ginsenosides was promoted by a small amount of Radix Polygoni Multiflori. In the combinative decoction of Radix Ginseng with Radix Astragali, ginsenosides contents were increased compared to single decoction of Radix Ginseng. Besides, ferric reducing antioxidant power (FRAP) method was developed for determination of the total antioxidative activity of n-butanol and water-soluble extracts from the decoction. The experimental results showed that antioxidative activity was better in the combinative decoction than that in single decoction, and the FRAP values of n-butanol extract were also greater compared with that of water extract.