INESC Technology and Science, Portugal; Physics and Astronomy Department, Faculty of Sciences, University of Porto, Portugal.
INESC Technology and Science, Portugal; Physics and Astronomy Department, Faculty of Sciences, University of Porto, Portugal.
Biochim Biophys Acta Gen Subj. 2018 May;1862(5):1209-1246. doi: 10.1016/j.bbagen.2018.02.008. Epub 2018 Feb 15.
The tip of an optical fiber has been considered an attractive platform in Biology. The simple cleaved end of an optical fiber can be machined, patterned and/or functionalized, acquiring unique properties enabling the exploitation of novel optical phenomena. Prompted by the constant need to measure and manipulate nanoparticles, the invention of the Scanning Near-field Optical Microscopy (SNOM) triggered the optimization and development of novel fiber tip microfabrication methods. In fact, the fiber tip was soon considered a key element in SNOM by confining light to sufficiently small extensions, challenging the diffraction limit. As result and in consequence of the newly proposed "Lab On Tip" concept, several geometries of fiber tips were applied in three main fields: imaging (in Microscopy/Spectroscopy), biosensors and micromanipulation (Optical Fiber Tweezers, OFTs). These are able to exert forces on microparticles, trap and manipulate them for relevant applications, as biomolecules mechanical study or protein aggregates unfolding.
This review presents an overview of the main achievements, most impactful studies and limitations of fiber tip-based configurations within the above three fields, along the past 10 years.
OFTs could be in future a valuable tool for studying several cellular phenomena such as neurodegeneration caused by abnormal protein fibrils or manipulating organelles within cells. This could contribute to understand the mechanisms of some diseases or biophenomena, as the axonal growth in neurons.
To the best of our knowledge, no other review article has so far provided such a broad view. Despite of the limitations, fiber tips have key roles in Biology/Medicine.
光纤的尖端在生物学中被认为是一个有吸引力的平台。光纤的简单切割端可以进行机械加工、图案化和/或功能化,获得独特的特性,从而利用新的光学现象。由于不断需要测量和操纵纳米粒子,扫描近场光学显微镜(SNOM)的发明引发了新型光纤尖端微加工方法的优化和发展。事实上,光纤尖端很快就被认为是 SNOM 的关键元素,通过将光限制在足够小的延伸部分来挑战衍射极限。因此,在新提出的“尖端实验室”概念的推动下,几种光纤尖端几何形状被应用于三个主要领域:成像(在显微镜/光谱学中)、生物传感器和微操作(光纤镊子,OFTs)。这些能够对微粒子施加力,捕获并操纵它们用于相关应用,如生物分子的机械研究或蛋白质聚集体的展开。
本文综述了过去 10 年来基于光纤尖端的配置在上述三个领域中的主要成就、最具影响力的研究和局限性。
OFTs 将来可能成为研究几种细胞现象的有价值的工具,例如由异常蛋白质纤维引起的神经退行性变,或在细胞内操纵细胞器。这有助于了解一些疾病或生物现象的机制,如神经元中的轴突生长。
据我们所知,到目前为止,还没有其他综述文章提供如此广泛的观点。尽管存在局限性,但光纤尖端在生物学/医学中具有关键作用。
