使用热光源傅里叶变换红外焦平面阵列以1微米像素分辨率进行快速离体生物诊断成像。

Rapid biodiagnostic ex vivo imaging at 1 μm pixel resolution with thermal source FTIR FPA.

作者信息

Findlay C R, Wiens R, Rak M, Sedlmair J, Hirschmugl C J, Morrison Jason, Mundy C J, Kansiz M, Gough K M

机构信息

Department of Chemistry, University of Manitoba, Winnipeg MB, Canada R3T2N2.

出版信息

Analyst. 2015 Apr 7;140(7):2493-503. doi: 10.1039/c4an01982b.

DOI:10.1039/c4an01982b

PMID:25600495

Abstract

A recent upgrade to the optics configuration of a thermal source FTIR microscope equipped with a focal plane array detector has enabled rapid acquisition of high magnification spectrochemical images, in transmission, with an effective geometric pixel size of ∼1 × 1 μm(2) at the sample plane. Examples, including standard imaging targets for scale and accuracy, as well as biomedical tissues and microorganisms, have been imaged with the new system and contrasted with data acquired at normal magnification and with a high magnification multi-beam synchrotron instrument. With this optics upgrade, one can now conduct rapid biodiagnostic ex vivo tissue imaging in-house, with images collected over larger areas, in less time (minutes) and with comparable quality and resolution to the best synchrotron source FTIR imaging capabilities.

摘要

最近，对配备焦平面阵列探测器的热光源傅里叶变换红外显微镜的光学配置进行了升级，从而能够在透射模式下快速采集高倍光谱化学图像，在样品平面上的有效几何像素尺寸约为1×1μm²。使用新系统对包括用于尺度和精度的标准成像目标以及生物医学组织和微生物在内的示例进行了成像，并与在正常放大倍数下以及使用高倍多光束同步加速器仪器采集的数据进行了对比。通过此次光学升级，现在可以在室内进行快速的离体组织生物诊断成像，在更短的时间（几分钟）内采集更大面积的图像，并且质量和分辨率与最佳的同步加速器源傅里叶变换红外成像能力相当。

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使用热光源傅里叶变换红外焦平面阵列以1微米像素分辨率进行快速离体生物诊断成像。

Rapid biodiagnostic ex vivo imaging at 1 μm pixel resolution with thermal source FTIR FPA.

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