无创微波螺旋谐振器传感器在烧伤程度检测中的临床应用初步分析

IF 2.7 Q3 ENGINEERING, BIOMEDICAL Frontiers in medical technology Pub Date : 2022-04-05 DOI:10.3389/fmedt.2022.859498
P. Rangaiah, Bappaditya Mandal, E. Avetisyan, A. Chezhian, B. Augustine, M. Pérez, Robin Augustine
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引用次数: 3

摘要

欧洲“Senseburn”项目旨在开发一种智能、便携、无创的微波早期有效诊断工具,以评估烧伤的深度和程度。本工作的目的是设计和开发一种方便的无创微波传感器,用于分析烧伤人体皮肤的烧伤程度。采用带螺旋谐振器(SR)的磁耦合环探头,研制了柔性的生物相容性微波传感器。该传感器是通过精确了解集总元件特性(电阻(R),电感(L)和电容(C) RLC参数)来实现的。估计等效电路技术依赖于一种严格的方法,能够全面表征传感器(环路探头和SR)。采用CST studio suite, AWR microwave office对具有高品质因子(Q)的微波谐振器传感器进行了仿真,并在标准厚度为0.13 mm的RO 3003衬底上制作。该传感器是根据烧伤皮肤的介电特性变化来制备的。该传感器可检测介电常数变化范围(εr 3-38)。在(εr 3 ~ 38)的1.5 ~ 1.71 GHz范围内,传感器的响应良好。该传感器采用PDMS封装,具有生物相容性。传感器元件的尺寸为长(L) = 39mm,宽(W) = 34mm,厚(T) = 1.4 mm。软件算法是准备自动化过程烧伤分析。所提出的基于电磁谐振器的传感器提供了一种非侵入性技术,通过监测谐振频率的变化来评估烧伤程度。大多数结果是基于数值模拟的。本文根据仿真产生的信息,提出了独特的电路设置和传感器装置。传感器的临床验证将在我们未来的工作中进行,在那里我们将密切了解基于烧伤程度的传感器的实际功能。senseburn系统旨在支持医生无线收集受伤的重要信息,从而为烧伤患者提供有效的治疗,从而挽救生命。
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Preliminary Analysis of Burn Degree Using Non-invasive Microwave Spiral Resonator Sensor for Clinical Applications
The European “Senseburn” project aims to develop a smart, portable, non-invasive microwave early effective diagnostic tool to assess the depth(d) and degree of burn. The objective of the work is to design and develop a convenient non-invasive microwave sensor for the analysis of the burn degree on burnt human skin. The flexible and biocompatible microwave sensor is developed using a magnetically coupled loop probe with a spiral resonator (SR). The sensor is realized with precise knowledge of the lumped element characteristics (resistor (R), an inductor (L), and a capacitor (C) RLC parameters). The estimated electrical equivalent circuit technique relies on a rigorous method enabling a comprehensive characterization of the sensor (loop probe and SR). The microwave resonator sensor with high quality factor (Q) is simulated using a CST studio suite, AWR microwave office, and fabricated on the RO 3003 substrate with a standard thickness of 0.13 mm. The sensor is prepared based on the change in dielectric property variation in the burnt skin. The sensor can detect a range of permittivity variations (εr 3–38). The sensor is showing a good response in changing resonance frequency between 1.5 and 1.71 GHz for (εr 3 to 38). The sensor is encapsulated with PDMS for the biocompatible property. The dimension of the sensor element is length (L) = 39 mm, width (W) = 34 mm, and thickness (T) = 1.4 mm. The software algorithm is prepared to automate the process of burn analysis. The proposed electromagnetic (EM) resonator based sensor provides a non-invasive technique to assess burn degree by monitoring the changes in resonance frequency. Most of the results are based on numerical simulation. We propose the unique circuit set up and the sensor device based on the information generated from the simulation in this article. The clinical validation of the sensor will be in our future work, where we will understand closely the practical functioning of the sensor based on burn degrees. The senseburn system is designed to support doctors to gather vital info of the injuries wirelessly and hence provide efficient treatment for burn victims, thus saving lives.
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CiteScore
3.70
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审稿时长
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