磁共振兼容型生物人工肝的新进展。

New advances in MR-compatible bioartificial liver.

机构信息

Department of Biomedical Engineering, University of North Carolina at Chapel Hill, Chapel Hill, NC 27599-7575, USA.

出版信息

NMR Biomed. 2012 Mar;25(3):427-42. doi: 10.1002/nbm.1633. Epub 2011 Feb 20.

DOI:10.1002/nbm.1633

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4332620/

Abstract

MR-compatible bioartificial liver (BAL) studies have been performed for 30 years and are reviewed. There are two types of study: (i) metabolism and drug studies using multinuclear MRS; primarily short-term (< 8 h) studies; (ii) the use of multinuclear MRS and MRI to noninvasively define the features and functions of BAL systems for long-term liver tissue engineering. In the latter, these systems often undergo not only modification of the perfusion system, but also the construction of MR radiofrequency probes around the bioreactor. We present novel MR-compatible BALs and the use of multinuclear MRS ((13)C, (19)F, (31)P) for the noninvasive monitoring of their growth, metabolism and viability, as well as (1)H MRI methods for the determination of flow profiles, diffusion, cell distribution, quality assurance and bioreactor integrity. Finally, a simple flexible coil design and circuit, and life support system, are described that can make almost any BAL MR-compatible.

摘要

磁共振兼容型生物人工肝脏（BAL）研究已经进行了 30 年，现对其进行综述。有两种类型的研究：（i）使用多核 MRS 进行代谢和药物研究；主要是短期（<8 h）研究；（ii）使用多核 MRS 和 MRI 无创性定义 BAL 系统的特征和功能，用于长期的肝脏组织工程。在后一种情况下，这些系统不仅经常需要修改灌注系统，而且还需要在生物反应器周围构建磁共振射频探头。我们介绍了新型磁共振兼容型 BAL 以及使用多核 MRS（(13)C、(19)F、(31)P）进行其生长、代谢和活力的无创监测，以及（1）H MRI 方法用于确定流动轮廓、扩散、细胞分布、质量保证和生物反应器完整性。最后，描述了一种简单的灵活线圈设计和电路以及生命支持系统，几乎可以使任何 BAL 都具有磁共振兼容性。

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