Optical waveguide properties of myelinated and unmyelinated nerve axons from ultraviolet to NIR wavelengths

Joint Event on 6^th International Conference on Photonics & 7^th International Conference on Laser Optics

July 31- August 02, 2017 Milan, Italy

Enayet Rahman and Iasonas F Triantis

University of London, UK

Scientific Tracks Abstracts: J Laser Opt Photonics

Abstract :

Statement of the Problem: Infrared Nerve Stimulation (INS) is becoming popular because of its potential to provide targeted stimulation. Recently it was claimed that myelin sheath can guide light (200 nm â�� 1300 nm), however propagation characteristics were not reported for wavelengths �»> 1500 nm, common in INS. We present them here for �» up to 2000 nm for both myelinated and unmyelinated nerve fibers. Methodology & Theoretical Orientation: Modal analysis was performed on the cross-section of the nerve fiber by solving Maxwellâ��s equations. The effective index (n_eff) of the first three modes was determined and the single mode operating wavelength range was determined for both myelinated and unmyelinated nerve fibers, using a 4-um diameter axon. The overall diameter of the myelinated fiber was 6.66 um. The refractive indices of the fiber cytoplasm, the myelin sheath, and the outside medium were set as 1.34, 1.44 and 1.38 respectively. Findings: The optical power propagating through unmyelinated fiber is confined by the index of the fiberâ��s cytoplasm (1.38) being higher than its surrounding (1.34). The effective indices of the first three propagating modes were determined and plotted in for 200nm â�¤ �» â�¤ 2000nm. It was found that the unmyelinated fiber is single-mode for �» > 1700 nm. In the myelinated fiber, optical power is confined within the myelin sheath (1.44). The effective indices of the myelinated fiber indicate that it supports more modes than the unmyelinated one and the myelin sheath operates in a single-mode condition for wavelengths longer than 1980 nm. This article determines light propagation characteristics of nerve fibers for a range of wavelengths, making it very useful for future INS designs. This study can also be useful in the field of interfacing brain using light.

Biography :

Enayet Rahman did his PhD in Photonics from City, University of London, United Kingdom. He has expertise in light tissue interaction, ultrasound and biphotonics. He is currently developing novel techniques on stimulation of nerve using combining electrical and optical stimulus. He is currently working as a Research Associate in the Research Centre for Biomedical Engineering in City, University of London, United Kingdom.