Monitoring soft tissue coagulation by optical spectroscopy

Biophotonics-Riga Pub Date : 2017-12-07 DOI:10.1117/12.2297091

A. Lihachev, I. Lihacova, H. Heinrichs, J. Spigulis, T. Trebst, M. Wehner

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Abstract

Laser tissue welding (LTW) or laser tissue soldering (LTS) is investigated since many years for treatment of incisions, wound closure and anastomosis of vessels [1, 2]. Depending on the process, a certain temperature in the range between 65 °C to 85 °C must be reached and held for a few seconds. Care has to be taken not to overheat the tissue, otherwise necrosis or tissue carbonization may occur and will impair wound healing. Usually the temperature is monitored during the process to control the laser power [3]. This requires either bulky equipment or expensive and fragile infrared fibers to feed the temperature signal to an infrared detector. Alternatively, changes in tissue morphology can be directly observed by analysis of spectral reflectance. We investigate spectral changes in the range between 400 nm to 900 nm wavelength. Characteristic spectral changes occur when the temperature of tissue samples increase above 70 °C which is a typical setpoint value for temperature control of coagulation. We conclude that simple spectroscopy in the visible range can provide valuable information during LTS and LTW and probably replace the delicate measurement of temperature. A major advantage is that optical measurements can be performed using standard optical fibers and can be easily integrated into a surgical tool.

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用光谱学监测软组织凝固

激光组织焊接(LTW)或激光组织焊接(LTS)用于治疗切口、伤口闭合和血管吻合已有多年的研究[1,2]。根据工艺的不同，必须达到65°C到85°C之间的一定温度，并保持几秒钟。必须注意不要使组织过热，否则可能发生坏死或组织碳化，从而影响伤口愈合。通常在加工过程中通过监测温度来控制激光功率[3]。这需要笨重的设备或昂贵易碎的红外纤维将温度信号馈送到红外探测器。或者，通过分析光谱反射率可以直接观察到组织形态的变化。我们研究了400 nm到900 nm波长范围内的光谱变化。当组织样品的温度高于凝固温度控制的典型设定值70℃时，会发生特征光谱变化。我们得出结论，在可见光范围内的简单光谱可以提供有价值的信息，并可能取代精密的温度测量。主要优点是光学测量可以使用标准光纤进行，并且可以很容易地集成到手术工具中。

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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Biophotonics-Riga

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