Hybrid electro-optical stimulation of the rat sciatic nerve induces force generation in the plantarflexor muscles

• Published in: Journal of neural engineering Vol. 9; no. 6; p. 066006
• Main Authors: Duke, Austin R, Peterson, Erik, Mackanos, Mark A, Atkinson, James, Tyler, Dustin, Jansen, E Duco
• Format: Journal Article
• Language: English
• Published: England IOP Publishing 01.12.2012
• Subjects: Activation; Animals; Body Temperature - physiology; Bursts; Damage; Electric Stimulation - methods; Electromyography; force generation; hybrid; infrared; Infrared Rays; Male; Muscle Contraction - physiology; Muscle, Skeletal - physiology; Muscles; Nerves; optical stimulation; Photic Stimulation; Rats; Rats, Sprague-Dawley; Risk; sciatic nerve; Sciatic Nerve - physiology; Stimulation; temperature; Trains
• ISSN: 1741-2560; 1741-2552
• DOI: 10.1088/1741-2560/9/6/066006

Objective. Optical methods of neural activation are becoming important tools for the study and treatment of neurological disorders. Infrared nerve stimulation (INS) is an optical technique exhibiting spatially precise activation in the native neural system. While this technique shows great promise, the risk of thermal damage may limit some applications. Combining INS with traditional electrical stimulation, a method known as hybrid electro-optical stimulation, reduces the laser power requirements and mitigates the risk of thermal damage while maintaining spatial selectivity. Here we investigate the capability of inducing force generation in the rat hind limb through hybrid stimulation of the sciatic nerve. Approach. Hybrid stimulation was achieved by combining an optically transparent nerve cuff for electrical stimulation and a diode laser coupled to an optical fiber for infrared stimulation. Force generation in the rat plantarflexor muscles was measured in response to hybrid stimulation with 1 s bursts of pulses at 15 and 20 Hz and with a burst frequency of 0.5 Hz. Main results. Forces were found to increase with successive stimulus trains, ultimately reaching a plateau by the 20th train. Hybrid evoked forces decayed at a rate similar to the rate of thermal diffusion in tissue. Preconditioning the nerve with an optical stimulus resulted in an increase in the force response to both electrical and hybrid stimulation. Histological evaluation showed no signs of thermally induced morphological changes following hybrid stimulation. Our results indicate that an increase in baseline temperature is a likely contributor to hybrid force generation. Significance. Extraneural INS of peripheral nerves at physiologically relevant repetition rates is possible using hybrid electro-optical stimulation.