Abstract
MALDI mass spectrometry imaging (MALDI-MSI) is a widely used technique to map the spatial distribution of molecules in sectioned tissue. The technique is based on the systematic generation and analysis of ions from small sample volumes, each representing a single pixel of the investigated sample surface. Subsequently, mass spectrometric images for any recorded ion species can be generated by displaying the signal intensity at the coordinate of origin for each of these pixels. Although easily equalized, these recorded signal intensities, however, are not necessarily a good measure for the underlying amount of analyte and care has to be taken in the interpretation of MALDI-MSI data. Physical and chemical properties that define the analyte molecules’ adjacencies in the tissue largely influence the local extraction and ionization efficiencies, possibly leading to strong variations in signal intensity response. Here, we inspect the validity of signal intensity distributions recorded from murine cerebellum as a measure for the underlying molar distributions. Based on segmentation derived from MALDI-MSI measurements, laser microdissection (LMD) was used to cut out regions of interest with a homogenous signal intensity. The molar concentration of six exemplary selected membrane lipids from different lipid classes in these tissue regions was determined using quantitative nano-HPLC-ESI-MS. Comparison of molar concentrations and signal intensity revealed strong deviations between underlying concentration and the distribution suggested by MSI data. Determined signal intensity response factors strongly depend on tissue type and lipid species.Graphical abstract
Highlights
Combining the analytical benefits of mass spectrometric analysis with spatial information, mass spectrometry imaging (MSI) has evolved into an important analytical tool in a wideFabian Eiersbrock and Julian Orthen contributed to this work
Lipid classes strongly suffering from ion suppression effect (ISE) benefit the most from the boost in signal intensity provided by MALDI-2 in the form of additional protonated ions
MALDI-2-MSI measurements dedicated for subsequent laser microdissection (LMD) and lipid extraction were performed with undersampling conditions, using a pixel size of 30 μm and an ablated area of only about 15 μm in diameter
Summary
Combining the analytical benefits of mass spectrometric analysis with spatial information, mass spectrometry imaging (MSI) has evolved into an important analytical tool in a wideFabian Eiersbrock and Julian Orthen contributed to this work. Ion yields strongly depend on the chemical properties of the matrix and the analyte itself and on the overall composition of the sample [12, 14, 15]. Laser-induced postionization in a fine vacuum MALDI ion source (MALDI-2) has shown promising first results pointing towards a reduction in ISE in the analysis of membrane lipids [15, 25,26,27]. In this technique, a second laser pulse hits the evolving plume 10 μs after the initial MALDI event ca. Apart from ionization efficiencies, the physical and chemical properties of the underlying tissue can influence signal intensity by affecting analyte extraction into the matrix [30,31,32]
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