Non-invasive screening of bladder cancer using digital microfluidics and FLIM technology combined with deep learning

IF 2 3区 物理与天体物理 Q3 BIOCHEMICAL RESEARCH METHODS Journal of Biophotonics Pub Date : 2024-06-28 DOI:10.1002/jbio.202400192
Wenhua Su, Chenyang Xu, Jinzhong Hu, Qiushu Chen, Yuwei Yang, Mingmei Ji, Yiyan Fei, Jiong Ma, Haowen Jiang, Lan Mi
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Abstract

Non-invasive screening for bladder cancer is crucial for treatment and postoperative follow-up. This study combines digital microfluidics (DMF) technology with fluorescence lifetime imaging microscopy (FLIM) for urine analysis and introduces a novel non-invasive bladder cancer screening technique. Initially, the DMF was utilized to perform preliminary screening and enrichment of urine exfoliated cells from 54 participants, followed by cell staining and FLIM analysis to assess the viscosity of the intracellular microenvironment. Subsequently, a deep learning residual convolutional neural network was employed to automatically classify FLIM images, achieving a three-class prediction of high-risk (malignant), low-risk (benign), and minimal risk (normal) categories. The results demonstrated a high consistency with pathological diagnosis, with an accuracy of 91% and a precision of 93%. Notably, the method is sensitive for both high-grade and low-grade bladder cancer cases. This highly accurate non-invasive screening method presents a promising approach for bladder cancer screening with significant clinical application potential.

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利用数字微流控技术、FLIM 技术和深度学习对膀胱癌进行无创筛查。
无创膀胱癌筛查对治疗和术后随访至关重要。这项研究将数字微流控(DMF)技术与荧光寿命成像显微镜(FLIM)相结合,用于尿液分析,并引入了一种新型无创膀胱癌筛查技术。首先,利用 DMF 对 54 名参与者的尿液脱落细胞进行初步筛选和富集,然后进行细胞染色和 FLIM 分析,以评估细胞内微环境的粘度。随后,采用深度学习残差卷积神经网络对 FLIM 图像进行自动分类,实现了高风险(恶性)、低风险(良性)和极低风险(正常)三类预测。结果显示与病理诊断高度一致,准确率为 91%,精确率为 93%。值得注意的是,该方法对高级别和低级别膀胱癌病例都很敏感。这种高度准确的无创筛查方法为膀胱癌筛查提供了一种前景广阔的方法,具有巨大的临床应用潜力。
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来源期刊
Journal of Biophotonics
Journal of Biophotonics 生物-生化研究方法
CiteScore
5.70
自引率
7.10%
发文量
248
审稿时长
1 months
期刊介绍: The first international journal dedicated to publishing reviews and original articles from this exciting field, the Journal of Biophotonics covers the broad range of research on interactions between light and biological material. The journal offers a platform where the physicist communicates with the biologist and where the clinical practitioner learns about the latest tools for the diagnosis of diseases. As such, the journal is highly interdisciplinary, publishing cutting edge research in the fields of life sciences, medicine, physics, chemistry, and engineering. The coverage extends from fundamental research to specific developments, while also including the latest applications.
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