Emily R. Bruce, Russell R. Kibbe, Emily C. Hector, David C. Muddiman
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引用次数: 0
Abstract
Infrared matrix-assisted laser desorption electrospray ionization (IR-MALDESI) uses an infrared laser to desorb neutral biomolecules with postionization via ESI at atmospheric pressure. The Gaussian profile of the laser with conventional optics results in the heating of adjacent nonablated tissue due to the energy profile being circular. A diffractive optical element (DOE) was incorporated into the optical train to correct for this disadvantage. The DOE produces a top-hat beam profile and square ablation spots, which have uniform energy distributions. Although beneficial to mass spectrometry imaging (MSI), it is unknown how the DOE affects the ability to perform quantitative MSI (qMSI). In this work, we evaluate the performance of the DOE optical train against our conventional optics to define the potential advantages of the top-hat beam profile. Absolute quantification of glutathione (GSH) was achieved by normalizing the analyte of interest to homoglutathione (hGSH), spotting a dilution series of stable isotope labeled glutathione (SIL-GSH), and analyzing by IR-MALDESI MSI with either the conventional optical train or with the DOE incorporated. Statistical comparison indicates that there was no significant difference between the quantification of GSH by the two optical trains as evidenced by similar calibration curves. Results support that both optical trains can be used for qMSI without a change in the ability to carry out absolute quantification but providing the benefits of the top-hat optical train (i.e., flat energy profile and square ablation spots)—for future qMSI studies.
红外基质辅助激光解吸电喷雾离子化(IR-MALDESI)利用红外激光解吸中性生物大分子,并在大气压下通过ESI进行后电离。由于能量曲线呈环形,传统光学器件的激光高斯曲线会导致加热邻近的非消融组织。为了纠正这一缺点,我们在光学系统中加入了衍射光学元件(DOE)。衍射光学元件产生了顶帽光束轮廓和方形烧蚀点,这些烧蚀点具有均匀的能量分布。虽然 DOE 有利于质谱成像(MSI),但 DOE 如何影响定量 MSI(qMSI)的能力尚不清楚。在这项工作中,我们评估了 DOE 光学系统与传统光学系统的性能,以确定顶帽光束轮廓的潜在优势。谷胱甘肽(GSH)的绝对定量是通过将相关分析物归一化为同型谷胱甘肽(hGSH),对稳定同位素标记的谷胱甘肽(SIL-GSH)稀释系列进行定点,然后使用传统光学系统或结合 DOE 的 IR-MALDESI MSI 进行分析实现的。统计比较结果表明,两种光学方法对谷胱甘肽的定量没有明显差异,相似的校准曲线也证明了这一点。研究结果表明,两种光学序列都可用于 qMSI,但绝对定量的能力不会改变,同时还能提供顶帽光学序列的优点(即平坦的能量曲线和方形烧蚀点)--供未来的 qMSI 研究使用。
期刊介绍:
The Journal of Mass Spectrometry publishes papers on a broad range of topics of interest to scientists working in both fundamental and applied areas involving the study of gaseous ions.
The aim of JMS is to serve the scientific community with information provided and arranged to help senior investigators to better stay abreast of new discoveries and studies in their own field, to make them aware of events and developments in associated fields, and to provide students and newcomers the basic tools with which to learn fundamental and applied aspects of mass spectrometry.