Advanced Functional Materials Journal Cover

Franz Lab Publishes Electrical Stimulation Article

Source

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In May the Regenerative Neurorehabilitation lab published the article, Advanced Materials in Wireless, Implantable Electrical Stimulators that Offer Rapid Rates of Bioresorption for Peripheral Axon Regeneration. 

Abstract

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"Injured peripheral nerves typically exhibit unsatisfactory and incomplete functional outcomes, and there are no clinically approved therapies for improving regeneration. Post-operative electrical stimulation (ES) increases axon regrowth, but practical challenges, from the cost of extended operating room time to the risks and pitfalls associated with transcutaneous wire placement, have prevented broad clinical adoption. This study presents a possible solution in the form of advanced bioresorbable materials for a type of thin, flexible, wireless implant that provides precisely controlled ES of the injured nerve for a brief time in the immediate post-operative period. Afterward, rapid, complete, and safe modes of bioresorption naturally and quickly eliminate all of the constituent materials in their entirety, without the need for surgical extraction. The unusually high rate of bioresorption follows from the use of a unique, bilayer enclosure that combines two distinct formulations of a biocompatible form of polyanhydride as an encapsulating structure, to accelerate the resorption of active components and confine fragments until complete resorption. Results from mouse models of tibial nerve transection with re-anastomosis indicate that this system offers levels of performance and efficacy that match those of conventional wired stimulators, but without the need to extend the operative period or to extract the device hardware."  .

Scientific Illustrations

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encapsulation illustrations

Figure 1. Controlled-bioresorbable, wireless electrical stimulator. a) Exploded view schematic illustration of the device structure. b) Schematic illustration of the complete device, with nerve cuff interface. c) Image of a wireless electrical stimulator and magni?ed view of the hot-pressed PLGA cuff and Mg electrode. d) Electromagnetic simulation of the radio frequency behavior of the wireless electrical stimulator with various Mg thickness.

encapsulation illustrations

 

Special Mention

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A very special thank you to Dom D'Andrea, whose hard work and scientific illustrations [seen above] enhance our efforts and publishing endeavors.  

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