Controlling spatial optical illuminations in optogenetics using an angled optical fiber tip

• Published in: Optical fiber technology Vol. 88; p. 103988
• Main Authors: Karami, Fatemeh, Zibaii, Mohammad I., Layeghi, Azam
• Format: Journal Article
• Language: English
• Published: Elsevier Inc 01.12.2024
• Subjects: Angled tip fiber; Brain tissue; Optical scanning; Optogenetics; Spatial illumination; Optical scanning; Optogenetics; Spatial illumination; Brain tissue; Angled tip fiber
• ISSN: 1068-5200
• DOI: 10.1016/j.yofte.2024.103988

•An angled optical fiber probe based on a double-sided angled tip (DSAT) structure was designed.•Structure was simulated based on ray tracing method.•The DSAT provides four optical spots to simultaneous illumination of four different locations in the brain tissue.•The probe enables precise spatial control of light propagation in brain tissue for optogenetics applications. The advent of optogenetic tools has revolutionized neuroscience research through its spatiotemporally precise activation of specific neurons by illuminating light on opsin-expressing neurons. A long-standing challenge of in vivo optogenetics remains in delivering light to multiple brain sites simultaneously and maintaining high spatial resolution. Optical fiber-based technologies have been proposed to address these challenges. This work presents the fabrication and characterization of an innovative angled optical fiber probe based on a double-sided angled tip (DSAT) structure. A custom griding setup was used for the reproducible fabrication of a smooth DSAT probe. The designed probe enables precise spatial control of light propagation in brain tissue in which DSAT at angled tip 55° achieving a maximum lateral illumination position of ± 420 μm away from the optical axis and a peak irradiance of 478.5 mW/mm2, using a 5 mW of 473 nm laser light. Also, the designed DAST probe was simulated based on ray tracing method and obtained the practical tip angle to evaluate the propagation of light rays emitted from the DSAT at various input optical angles ranging from 0° to 12.5° to predict their irradiance and positions in the modelled tissue. The results indicate the probe generates two elliptical rings each containing two spots with higher optical concentration. Consequently, this device provides four optical spots with irradiance peaks that enable simultaneous illumination of four different locations in the brain tissue. Obtained experiment results are in good agreement with simulation results which can be used for multipoint illumination of brain tissue in optogenetics applications.