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用于太赫兹波段非侵入性宫颈癌诊断的基于超紧凑型超材料的生物传感器的设计与验证

Design and validation of ultra-compact metamaterial-based biosensor for non-invasive cervical cancer diagnosis in terahertz regime.

作者信息

Hamza Musa N, Tariqul Islam Mohammad, Lavadiya Sunil, Ud Din Iftikhar, Sanches Bruno, Koziel Slawomir, Islam Md Shabiul

机构信息

Department of Physics, College of Science, University of Raparin, Sulaymaniyah, Iraq.

Department of Electrical, Electronic and Systems Engineering, Faculty of Engineering and Built Environment, Universiti Kebangsaan Malaysia, UKM Bangi, Selangor, Malaysia.

出版信息

PLoS One. 2025 Feb 3;20(2):e0311431. doi: 10.1371/journal.pone.0311431. eCollection 2025.

DOI:10.1371/journal.pone.0311431
PMID:39899558
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11790148/
Abstract

Cervical cancer belongs to the most dangerous types of cancers posing considerable threat to women's survival. It is most often diagnosed in the advanced stages as precancerous lesions are often symptom-free and difficult to identify. Microwave imaging, especially in terahertz (THz) range, is a convenient and noninvasive cancer detection tool. It enables characterization of biological tissues and discrimination between healthy and malignant ones. This study presents a novel triple-band biosensor based on metamaterials (MTMs). By leveraging unique properties of MTMs, the proposed biosensor operates as a perfect absorber. It exploits resonant modes in the THz spectrum to achieve remarkable sensitivity. Meticulous selection of the sensor geometry and dimensions enables efficient miniaturization. Meanwhile, utilization of frequency-domain data to detect refractive index changes improves resolution of cancerous tissue identification. Extensive numerical investigations corroborate its ability to carry out reliable early-stage cervical cancer diagnosis. This includes identification of the spatial extent of the malignant tissue. Excellent electrical properties of the sensor are accompanied by its compact size, which is highly desirable for non-invasive and portable applications.

摘要

宫颈癌是最危险的癌症类型之一,对女性的生存构成了相当大的威胁。由于癌前病变通常没有症状且难以识别,宫颈癌最常被诊断为晚期。微波成像,尤其是太赫兹(THz)波段的成像,是一种便捷且无创的癌症检测工具。它能够对生物组织进行表征,并区分健康组织和恶性组织。本研究提出了一种基于超材料(MTMs)的新型三波段生物传感器。通过利用超材料的独特特性,所提出的生物传感器可作为完美吸收体工作。它利用太赫兹光谱中的共振模式来实现显著的灵敏度。对传感器几何形状和尺寸的精心选择能够实现高效的小型化。同时,利用频域数据检测折射率变化可提高癌组织识别的分辨率。大量的数值研究证实了其进行可靠的早期宫颈癌诊断的能力。这包括识别恶性组织的空间范围。该传感器优异的电学性能与其紧凑的尺寸相伴,这对于无创和便携式应用来说是非常理想的。

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