Tissue Eng
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We have developed a matrix-mediated transfection system to deliver plasmids to human keratinocytes. The matrix is a soluble, self-hardening fibrin matrix (Tissucol), Baxter) that has been used clinically. Recently it has been shown that full thickness burn wounds can be successfully treated with a keratinocyte fibrin glue suspension. ⋯ We obtained successful transfection rates of these cells (up to a 100-fold increase compared to controls containing no EGF expression plasmid) in vitro. After transplantation to full thickness wounds on athymic mice we were able to show a 180-fold increase in EGF concentration compared to controls, which persisted over the entire 7-day monitored period, decreasing from 180 to 20 pg/mL at day seven. This unique approach indicates the possible utility to combine a matrix for cell transplantation with a transfection system to release therapeutic proteins in vitro and in vivo.
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Comparative Study
A new strategy to produce sustained growth of central nervous system axons: continuous mechanical tension.
Although a primary strategy to repair spinal cord and other nerve injuries is to bridge the damage with axons, producing axons of sufficient length and number has posed a significant challenge. Here, we explored the ability of integrated central nervous system (CNS) axons to grow long distances in response to continuous mechanical tension. Neurons were plated on adjacent membranes and allowed to integrate, including the growth of axons across a 50-microm border between the two membranes. ⋯ This is the first evidence that the center portion of synapsed CNS axons can exhibit sustained "stretch-induced growth." This may represent an important growth mechanism for the elongation of established white matter tracts during development. We also found by doubling the stretch rate to 7 microm/5 min that the axon bundles could not maintain growth and disconnected in the center of the gap by 3 days of stretch, demonstrating a tolerance limit for the rate of axonal growth. We propose that this newfound stretch-induced growth ability of integrated CNS axons may be exploited to produce transplant materials to bridge extensive nerve damage.