Blue-LIRIC in the rabbit cornea: efficacy, tissue effects, and repetition rate scaling

• Main Authors: Huang, R. (Author), Huxlin, K.R (Author), Knox, W.H (Author), Savage, D. (Author), Wozniak, K. (Author), Yu, D. (Author), Zheleznyak, L. (Author)
• Format: Article
• Language: English
• Published: Optica Publishing Group (formerly OSA) 2022
• Subjects: Blue lasers; Collagen; Ex-vivo; High repetition rate; High resolution transmission electron microscopy; In-vivo; Laser induced refractive index; Light transmission; Low repetition rate; Non-invasive way; Refractive index; Refractive index changes; Repetition rate; Scalings; Tissue
• Online Access: View Fulltext in Publisher

 Laser-induced refractive index change (LIRIC) is being developed as a non-invasive way to alter optical properties of transparent, ophthalmic materials including corneas ex vivo and in vivo. This study examined the optical and biological effects of blue-LIRIC (wavelengths 400-405 nm) of ex-vivo rabbit corneas. Following LIRIC treatment at low and high repetition rates (8.3 MHz and 80 MHz, respectively), we interferometrically measured optical phase change, obtained transmission electron microscopy (TEM) micrographs, and stained histological sections with collagen hybridizing peptides (CHP) to assess the structural and organizational changes caused by LIRIC at different repetition rates. Finally, we performed power and scan speed scaling experiments at three different repetition rates (1 MHz, 8.3 MHz, and 80 MHz) to study their impact on LIRIC efficacy. Histologic co-localization of CHP and LIRIC-generated green autofluorescence signals suggested that collagen denaturation had occurred in the laser-irradiated region. TEM imaging showed different ultrastructural modifications for low and high repetition rate writing, with discrete homogenization of collagen fibrils at 80 MHz, as opposed to contiguous homogenization at 8.3 MHz. Overall, this study confirmed that LIRIC efficacy can be dramatically increased, while still avoiding tissue ablation, by lowering the repetition rate from 80 MHz to 8.3 MHz. Modeling suggests that this is due to a higher, single-pulse, energy density deposition at given laser powers during 8.3 MHz LIRIC. © 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement