Alaa Sabeeh Shanshool , Saeed Ziaee , Mohammad Ali Ansari , Valery V. Tuchin
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引用次数: 0
Abstract
Advanced laser methods have recently been used in human and animal head tissues for functional and molecular imaging. Combining these approaches with various probes and nanostructures gives up a new path for theranostic applications in brain tissues. The diverse optical properties of head tissues such as the scalp, skull, cerebrospinal fluid, and brain tissues result in considerable photon scattering and absorption. Diffusion of photons inside head tissues decreases the optical imaging quality and limits the optical resolutions of cellular and neural treatments. Tissue optical clearing (TOC) was set up more than a century ago to make tissue transparent by immersing it in liquids with a matching RI as the tissue. This approach has lately gained popularity in the field of brain imaging. The physical fundamentals of optical clearing (OC) procedures for brain tissue, such as RI matching with chemical agents, dehydration, delipidation, decalcification, hyperhydration, and innovative hybrid brain OC methods, are explored here. This study covers critical issues such as choosing the best brain OC methods and optimizing wavelength and laser energy to control tissue optical properties. Here, innovative ways for decreasing photon scattering based on immersion procedures and induced heating tunnels are discussed. In addition, simulation methods of photon migration in brain tissues (based on random approaches) are investigated, paving the way for the proper brain OC strategy. Finally, the limitations of this method for in vivo applications are discussed, as well as possible applications in cranial implants, optogenetics, laser brain stimulation, and functional optical imaging.
最近,先进的激光方法已被用于人类和动物头部组织的功能和分子成像。将这些方法与各种探针和纳米结构相结合,为脑组织中的治疗应用开辟了一条新路。头皮、颅骨、脑脊液和脑组织等头部组织的光学特性各不相同,会产生大量光子散射和吸收。光子在头部组织内的扩散会降低光学成像质量,限制细胞和神经治疗的光学分辨率。早在一个多世纪前,就有人提出了组织光学清除(TOC)方法,通过将组织浸泡在与组织相匹配 RI 的液体中,使组织变得透明。这种方法最近在脑成像领域大受欢迎。本文探讨了脑组织光学清除(OC)程序的物理基本原理,如与化学试剂的 RI 匹配、脱水、脱脂、脱钙、超水化以及创新的混合脑 OC 方法。这项研究涵盖了一些关键问题,如选择最佳的脑OC方法,优化波长和激光能量以控制组织的光学特性。这里讨论了基于浸泡程序和诱导加热隧道的减少光子散射的创新方法。此外,还研究了光子在脑组织中迁移的模拟方法(基于随机方法),为正确的脑OC策略铺平了道路。最后,还讨论了这种方法在应用方面的局限性,以及在颅骨植入、光遗传学、激光脑刺激和功能光学成像方面的可能应用。
期刊介绍:
Progress in Quantum Electronics, established in 1969, is an esteemed international review journal dedicated to sharing cutting-edge topics in quantum electronics and its applications. The journal disseminates papers covering theoretical and experimental aspects of contemporary research, including advances in physics, technology, and engineering relevant to quantum electronics. It also encourages interdisciplinary research, welcoming papers that contribute new knowledge in areas such as bio and nano-related work.