Optical tweezers in biomedical research - progress and techniques.

Q3 Medicine

Journal of Medicine and Life Pub Date : 2024-11-01 DOI:10.25122/jml-2024-0316

Dharm Singh Yadav, Tudor Savopol

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引用次数: 0

Abstract

Optical tweezers, which leverage the forces exerted by radiation pressure, have emerged as a pivotal technique for precisely manipulating and analyzing microscopic particles. Since Arthur Ashkin's ground-breaking work in the 1970s and the subsequent development of the single-beam optical trap in 1986, the capabilities of optical tweezers have expanded significantly, enabling the intricate manipulation of biological specimens at the micro- and nanoscale. This review elucidates the foundational principles of optical trapping and their extensive applications in the biomedical sciences. The applications of optical tweezers in biomedicine are vast, ranging from the investigation of cellular mechanical properties, such as cell stretching, membrane elasticity, and stiffness, to single-molecule studies encompassing DNA and protein mechanics, protein-DNA interactions, molecular motor functions, and pathogen-host interactions. Advancement of optical tweezers in this field includes their integration with holography, fluorescence microscopy, microfluidics, and enhancements in force sensitivity and positional accuracy. These tools have profoundly impacted the study of cellular mechanics, drug discovery processes, and disease diagnostics, providing unparalleled insights into the biophysical mechanisms underlying health and pathology.

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生物医学研究中的光镊。进展和技术。

光镊利用辐射压力产生的力，已经成为精确操纵和分析微观粒子的关键技术。自从亚瑟·阿什金在20世纪70年代的开创性工作和1986年单光束光阱的后续发展以来，光镊的功能已经大大扩展，使生物标本在微纳米尺度上的复杂操作成为可能。本文综述了光捕获的基本原理及其在生物医学中的广泛应用。光镊在生物医学中的应用是广泛的，从细胞力学特性的研究，如细胞拉伸、膜弹性和刚度，到单分子研究，包括DNA和蛋白质力学、蛋白质-DNA相互作用、分子运动功能和病原体-宿主相互作用。光学镊子在这一领域的进步包括与全息技术、荧光显微镜、微流体技术的结合，以及力灵敏度和定位精度的提高。这些工具深刻地影响了细胞力学、药物发现过程和疾病诊断的研究，为健康和病理背后的生物物理机制提供了无与伦比的见解。

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

Journal of Medicine and Life Medicine-Medicine (all)

CiteScore

1.90

自引率

0.00%

发文量

202

期刊介绍： The Journal of Medicine and Life publishes peer-reviewed articles from various fields of medicine and life sciences, including original research, systematic reviews, special reports, case presentations, major medical breakthroughs and letters to the editor. The Journal focuses on current matters that lie at the intersection of biomedical science and clinical practice and strives to present this information to inform health care delivery and improve patient outcomes. Papers addressing topics such as neuroprotection, neurorehabilitation, neuroplasticity, and neuroregeneration are particularly encouraged, as part of the Journal''s continuous interest in neuroscience research. The Editorial Board of the Journal of Medicine and Life is open to consider manuscripts from all levels of research and areas of biological sciences, including fundamental, experimental or clinical research and matters of public health. As part of our pledge to promote an educational and community-building environment, our issues feature sections designated to informing our readers regarding exciting international congresses, teaching courses and relevant institutional-level events.