Efficient delivery of small interfering RNA into injured spinal cords in rats by photomechanical waves

In the central nervous system, lack of axonal regeneration leads to permanent functional disabilities. In spinal cord injury (SCI), the over-expressions of intermediate filament (IF) proteins, such as glial fibrillary acidic protein (GFAP) and vimentin, are mainly involved in glial scar formation; these proteins work as both physical and biochemical barriers to axonal regeneration. Thus, silencing of these IF proteins would be an attractive strategy to treat SCI. In this study, we first attempted to deliver fluorescent probe-labeled siRNAs into injured spinal cords in rats by applying photomechanical waves (PMWs) to examine the capability of PMWs as a tool for siRNA delivery. Intense fluorescence from siRNAs was observed in much broader regions in the spinal cords with PMW application when compared with those with siRNA injection alone. Based on this result, we delivered siRNAs for GFAP and vimentin into injured spinal tissues in rats by applying PMWs. The treatment resulted in efficient silencing of the proteins at five days after SCI and a decrease of the cavity area in the injured tissue at three weeks after SCI when compared with those with siRNA injection alone. These results demonstrate the capability of PMWs for efficient delivery of siRNAs into injured spinal cords and treatment of SCIs.

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