Miniature Magnetic Resonance Imaging System for in situ Monitoring of Bacterial Growth and Biofilm Formation

IEEE transactions on biomedical circuits and systems Pub Date : 2024-02-23 DOI:10.1109/TBCAS.2024.3369389

Qi Zhou;Shuhao Fan;Ka-Meng Lei;Donhee Ham;Rui P. Martins;Pui-In Mak

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Abstract

In situ monitoring of bacterial growth can greatly benefit human healthcare, biomedical research, and hygiene management. Magnetic resonance imaging (MRI) offers two key advantages in tracking bacterial growth: non-invasive monitoring through opaque sample containers and no need for sample pretreatment such as labeling. However, the large size and high cost of conventional MRI systems are the roadblocks for in situ monitoring. Here, we proposed a small, portable MRI system by combining a small permanent magnet and an integrated radio-frequency (RF) electronic chip that excites and reads out nuclear spin motions in a sample, and utilize this small MRI platform for in situ imaging of bacterial growth and biofilm formation. We demonstrate that MRI images taken by the miniature––and thus broadly deployable for in situ work––MRI system provide information on the spatial distribution of bacterial density, and a sequential set of MRI images taken at different times inform the temporal change of the spatial map of bacterial density, showing bacterial growth.

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用于现场监测细菌生长和生物膜形成的微型磁共振成像系统。

对细菌生长进行原位监测可大大有益于人类保健、生物医学研究和卫生管理。磁共振成像（MRI）在跟踪细菌生长方面有两大优势：通过不透明的样品容器进行非侵入式监测，以及无需对样品进行标记等预处理。然而，传统磁共振成像系统体积庞大、成本高昂，成为原位监测的障碍。在这里，我们提出了一种小型便携式核磁共振成像系统，它将小型永磁体和集成射频（RF）电子芯片结合在一起，可激发和读出样品中的核自旋运动，并利用这种小型核磁共振成像平台对细菌生长和生物膜形成进行原位成像。我们证明，微型核磁共振成像系统拍摄的核磁共振成像图像可提供细菌密度的空间分布信息，在不同时间拍摄的一组连续核磁共振成像图像可提供细菌密度空间图的时间变化信息，从而显示细菌的生长情况。

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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IEEE transactions on biomedical circuits and systems

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