Bone-Integrated Optical Microlasers for In-Vivo Diagnostic Biomechanical Performances

Volume 3: Biomedical and Biotechnology Engineering Pub Date : 2019-11-11 DOI:10.1115/imece2019-11406

O. Cavazos, M. Manzo, E. Ramírez-Cedillo, H. Siller

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引用次数: 1

Abstract

Bones experience mechanical loads on a daily basis. It is difficult to obtain biomechanical performances in-vivo measurements. When implants are integrated with bones after surgery, especially in aged individuals, their osseointegration can compromise the structural integrity of bones; for this reason, it is important to monitor the evolution of the mechanical properties of bones with some in-vivo diagnostic technique. In this study, we propose to integrate optical microsensing devices into bones. To simulate the working principle, a sensor is integrated with a 3-D printed bone. The sensing element is a dye-doped optical microlaser based on the morphology dependent resonance (MDR) shifts also called the whispering gallery mode phenomenon (WGM). When the microlaser is excited by a light source, the fluorescence from the dye couples with the optical resonances. These optical resonances are very sensitive to any perturbation of the microlasers’s morphology. Therefore, the local strain variation of the bone can be related to the shift of the optical resonances. This in-vivo technique monitors the biomechanical performance of bones with implants and prosthetics.

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骨集成光学微激光器用于体内诊断生物力学性能

骨骼每天都要承受机械负荷。很难获得生物力学性能的体内测量。当植入物在手术后与骨骼结合时，特别是在老年人中，它们的骨结合会损害骨骼的结构完整性;因此，利用体内诊断技术监测骨骼力学性能的演变是非常重要的。在本研究中，我们提出将光学微传感装置集成到骨骼中。为了模拟工作原理，传感器与3d打印骨骼集成在一起。传感元件是一种基于形态相关共振(MDR)位移的染料掺杂光学微激光器，也称为窃窃廊模式现象(WGM)。当微激光被光源激发时，染料的荧光与光学共振偶联。这些光学共振对微激光形态的任何扰动都非常敏感。因此，骨的局部应变变化可能与光学共振的位移有关。这种体内技术监测骨植入物和假肢的生物力学性能。

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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Volume 3: Biomedical and Biotechnology Engineering

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