Application of multi-channel differential optical density on fast detection of degree of traumatic dural hematoma

Q3 Medicine

Physics in Medicine Pub Date : 2019-06-01 DOI:10.1016/j.phmed.2019.100015

Huiquan Wang , Fang Xia , Songlin Yu , Zhe Zhao , Jinhai Wang

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引用次数: 0

Abstract

Due to the advantages of rapid and non-invasive detection of traumatic dural hematoma using near-infrared differential optical density method, this technology has become a hot research topic in tissue optics in recent years and has important applications in clinical emergency treatment. To further improve the detection accuracy of traumatic subdural hematoma degree, in this paper, a multi-channel differential optical density method was used to obtain the bilaterally-symmetric optical density data of brain. A calibration model with the optical absorption coefficient of the brain tissue and the differential optical density was established using the partial least squares method to predict intracranial epidural hematoma. Simulation results show that the average relative error of the absorption coefficient of dural hematoma using the prediction model was 11.16% and the average relative error on hematoma depth prediction was less than 1%. The model meets the demands of noninvasive traumatic subdural hematoma degree detection. By introducing multi-channel differential optical density method into the noninvasive detection of subdural hematoma, the effects of individual differences on the detection result could be eliminated significantly and the detection accuracy of traumatic subdural hematoma degree can be improved.

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多通道差分光密度在外伤性硬脑膜血肿程度快速检测中的应用

近红外差光密度法由于具有快速、无创检测外伤性硬脑膜血肿的优点，近年来成为组织光学领域的研究热点，在临床急诊治疗中有重要应用。为了进一步提高外伤性硬膜下血肿程度的检测精度，本文采用多通道差分光密度法获取脑双侧对称光密度数据。采用偏最小二乘法建立了脑组织光吸收系数和光密度差的校正模型，用于预测颅内硬膜外血肿。仿真结果表明，该预测模型对硬脑膜血肿吸收系数的平均相对误差为11.16%，对血肿深度预测的平均相对误差小于1%。该模型满足创伤性硬膜下血肿程度无创检测的要求。将多通道差分光密度法引入硬膜下血肿的无创检测中，可明显消除个体差异对检测结果的影响，提高外伤性硬膜下血肿程度的检测精度。

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

Physics in Medicine Physics and Astronomy-Instrumentation

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

12 weeks

期刊介绍： The scope of Physics in Medicine consists of the application of theoretical and practical physics to medicine, physiology and biology. Topics covered are: Physics of Imaging Ultrasonic imaging, Optical imaging, X-ray imaging, Fluorescence Physics of Electromagnetics Neural Engineering, Signal analysis in Medicine, Electromagnetics and the nerve system, Quantum Electronics Physics of Therapy Ultrasonic therapy, Vibrational medicine, Laser Physics Physics of Materials and Mechanics Physics of impact and injuries, Physics of proteins, Metamaterials, Nanoscience and Nanotechnology, Biomedical Materials, Physics of vascular and cerebrovascular diseases, Micromechanics and Micro engineering, Microfluidics in medicine, Mechanics of the human body, Rotary molecular motors, Biological physics, Physics of bio fabrication and regenerative medicine Physics of Instrumentation Engineering of instruments, Physical effects of the application of instruments, Measurement Science and Technology, Physics of micro-labs and bioanalytical sensor devices, Optical instrumentation, Ultrasound instruments Physics of Hearing and Seeing Acoustics and hearing, Physics of hearing aids, Optics and vision, Physics of vision aids Physics of Space Medicine Space physiology, Space medicine related Physics.