AI‐Assisted Plasmonic Enhanced Colorimetric Fluidic Device for Hydrogen Peroxide Detection from Cancer Cells

Carolina del Real Mata, Sripadh Guptha Yedire, Mahsa Jalali, Roozbeh Siavash Moakhar, Tamer AbdElFatah, Jashandeep Kaur, Ziwei He, Sara Mahshid
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Abstract

Hydrogen peroxide (H2O2) is an essential molecule to various physiological processes and is commonly used for the detection and monitoring of glucose and cell viability. Furthermore, it is identified as a signal of oncogenic growth due to its widespread presence within the cancer cell environment. However, the low concentrations of H2O2 released by cancer cells' metabolism challenge current detection methods' capabilities and their practicality for translation to clinical applications. Colorimetric assays with simple readouts are a promising solution, provided that their sensitivity and rapidity in detecting H2O2 improve. Here, a plasmonic enhanced nanopatterned platform is proposed coupled with an Amplex Red assay to monitor the color change of H2O2 released from cancer cells. The nanopatterned platform embedded into a multiplexed microfluidic device enhances the kinetics of the reaction ≈7 times. This approach has reached a limit of detection of 1 pm when tested in breast (MCF‐7) and prostate (PC‐3) cancer media. The collected color images are processed and analyzed by a machine learning algorithm that categorizes them into “high” or “low‐to‐no” concentrations of H2O2 with 91% accuracy. This study is a step toward developing a device for highly sensitive H2O2 detection that is easily adaptable, user‐friendly, portable, and automated.

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用于检测癌细胞过氧化氢的人工智能辅助质子增强比色流体装置
过氧化氢(H2O2)是各种生理过程中不可或缺的分子,通常用于检测和监控葡萄糖和细胞活力。此外,由于过氧化氢广泛存在于癌细胞环境中,因此被确定为致癌生长的信号。然而,癌细胞新陈代谢释放的 H2O2 浓度很低,这对当前检测方法的能力及其转化为临床应用的实用性提出了挑战。如果能提高检测 H2O2 的灵敏度和快速性,那么具有简单读数的比色检测法不失为一种有前途的解决方案。在此,我们提出了一种等离子体增强型纳米图案平台,该平台与 Amplex Red 检测法相结合,可监测癌细胞释放的 H2O2 的颜色变化。嵌入多路复用微流控装置的纳米图案平台可将反应动力学提高≈7 倍。在乳腺癌(MCF-7)和前列腺癌(PC-3)培养基中进行测试时,这种方法的检测极限为 1 pm。收集到的彩色图像由机器学习算法进行处理和分析,该算法将图像分为 "高 "或 "低至无 "浓度的 H2O2,准确率高达 91%。这项研究是朝着开发一种高灵敏度 H2O2 检测设备迈出的一步,这种设备适应性强、用户界面友好、便于携带且可实现自动化。
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