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通过浸泡全氟碳液体使软骨外植体中的 T 弛豫和磁化传递稳定化。

Stabilization of T relaxation and magnetization transfer in cartilage explants by immersion in perfluorocarbon liquid.

机构信息

Laboratory of Clinical Investigation, National Institute on Aging, National Institutes of Health, Baltimore, Maryland.

出版信息

Magn Reson Med. 2019 May;81(5):3209-3217. doi: 10.1002/mrm.27650. Epub 2019 Jan 22.

DOI:10.1002/mrm.27650
PMID:30667088
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6687396/
Abstract

PURPOSE

Magnetic resonance imaging of ex vivo cartilage measures parameters such as T and magnetization transfer ratio (MTR), which reflect structural changes associated with osteoarthritis. Samples are often immersed in aqueous solutions to prevent dehydration and to to improve susceptibility matching. This study sought to determine the extent to which T and MTR changes are attributable to immersion alone and to identify immersion conditions to minimize this confounding factor.

METHODS

T and MTR were measured before and after immersion for up to 24 hours at 4°C. Bovine nasal and articular cartilage and human articular cartilage were studied. Experimental groups included undisturbed immersion in Fluorinert FC-770, a susceptibility-matched, hydrophobic liquid with minimal tissue penetration, and immersion in Fluorinert, Dulbecco's phosphate-buffered saline (DPBS), or saline, with removal from the magnet between scans. F and H-MRI were used to detect cartilage penetration by Fluorinert and swelling, respectively.

RESULTS

Saline and DPBS immersion rapidly increased T , wet weight and cartilage volume and decreased MTR, suggesting increased water content for all cartilage types. Fluorinert-immersed samples exhibited minimal changes in T or MTR. No ingress of Fluorinert was detected after 2 weeks of continuous immersion at 4°C.

CONCLUSION

Ex vivo quantitative MR studies of cartilage may be confounded by the effects of immersion in aqueous solution, which may be comparable to or larger than effects attributed to pathology. These effects may be mitigated by immersion in perfluorocarbon liquids such as Fluorinert FC-770.

摘要

目的

离体软骨的磁共振成像可测量 T1 和磁化转移率(MTR)等参数,这些参数反映了与骨关节炎相关的结构变化。样本通常浸泡在水溶液中,以防止脱水并改善磁化率匹配。本研究旨在确定 T1 和 MTR 变化在多大程度上仅归因于浸泡,并确定浸泡条件以最小化这一混杂因素。

方法

在 4°C 下,最多浸泡 24 小时前后测量 T1 和 MTR。研究了牛鼻软骨和关节软骨以及人关节软骨。实验组包括在 Fluorinert FC-770 中不受干扰的浸泡,这是一种具有最小组织穿透性的顺磁性匹配疏液,以及在 Fluorinert、杜氏磷酸盐缓冲盐水(DPBS)或盐水中的浸泡,在扫描之间从磁体中取出。F 和 H-MRI 分别用于检测 Fluorinert 对软骨的穿透和肿胀。

结果

盐水和 DPBS 浸泡迅速增加 T1、湿重和软骨体积,降低 MTR,表明所有软骨类型的含水量增加。Fluorinert 浸泡的样本 T1 或 MTR 变化最小。在 4°C 连续浸泡 2 周后未检测到 Fluorinert 进入。

结论

离体软骨的定量磁共振研究可能会受到浸泡在水溶液中的影响的干扰,这种影响可能与归因于病理学的影响相当或更大。这些影响可以通过浸泡在全氟碳液体(如 Fluorinert FC-770)中得到缓解。

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