Optical spectroscopy for in vivo medical diagnosis—a review of the state of the art and future perspectives

IF 5 Q1 ENGINEERING, BIOMEDICAL
J. Kim, D. Wales, Guang‐Zhong Yang
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引用次数: 31

Abstract

When light is incident to a biological tissue surface, combinations of optical processes occur, such as reflection, absorption, elastic and non-elastic scattering, and fluorescence. Analysis of these light interactions with the tissue provides insight into the metabolic and pathological state of the tissue. Furthermore, in vivo diagnosis of diseases using optical spectroscopy enables in situ rapid clinical decisions without invasive biopsies. For in vivo scenarios, incident light can be delivered in a highly localized manner to tissue via optical fibers, which are placed within the working channels of minimally invasive clinical tools, such as endoscopes. There has been extensive development in the accuracy and specificity of these optical spectroscopy techniques since the earliest in vivo examples were published in the academic literature in the early ‘90s, and there are now commercially available systems that have undergone medical and clinical trials. In this review, several types of optical spectroscopy techniques (elastic optical scattering spectroscopy, fluorescence spectroscopy, Raman spectroscopy, and multimodal spectroscopy) for the diagnosis and monitoring of diseases states of tissue in an in vivo setting are introduced and explored. Examples of the latest and most impactful works for each technique are then critically reviewed. Finally, current challenges and unmet clinical needs are discussed, followed by future opportunities, such as point-based spectroscopies for robot-guided surgical interventions.
光谱学在体内医学诊断中的应用——技术现状和未来展望综述
当光入射到生物组织表面时,发生光学过程的组合,例如反射、吸收、弹性和非弹性散射以及荧光。对这些光与组织的相互作用的分析提供了对组织代谢和病理状态的深入了解。此外,使用光学光谱对疾病进行体内诊断能够在没有侵入性活检的情况下进行原位快速临床决策。对于体内场景,入射光可以通过光纤以高度局部化的方式传递到组织,光纤放置在微创临床工具(如内窥镜)的工作通道内。自从90年代初最早的体内实例发表在学术文献中以来,这些光谱技术的准确性和特异性已经得到了广泛的发展,现在已经有经过医学和临床试验的商用系统。在这篇综述中,介绍和探索了几种类型的光谱技术(弹性光学散射光谱、荧光光谱、拉曼光谱和多峰光谱),用于在体内环境中诊断和监测组织的疾病状态。然后对每种技术的最新和最具影响力的作品的例子进行批判性的回顾。最后,讨论了当前的挑战和未满足的临床需求,以及未来的机会,如机器人引导手术干预的基于点的光谱学。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
9.40
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