Abstract
A new mass spectrometric imaging approach based on laser activated electron tunneling (LAET) was described and applied to analysis of endogenous metabolites of plant leaves. LAET is an electron-directed soft ionization technique. Compressed thin films of semiconductor nanoparticles of bismuth cobalt zinc oxide were placed on the sample plate for proof-of-principle demonstration because they can not only absorb ultraviolet laser but also have high electron mobility. Upon laser irradiation, electrons are excited from valence bands to conduction bands. With appropriate kinetic energies, photoexcited electrons can tunnel away from the barrier and eventually be captured by charge deficient atoms present in neutral molecules. Resultant unpaired electron subsequently initiates specific chemical bond cleavage and generates ions that can be detected in negative ion mode of the mass spectrometer. LAET avoids the co-crystallization process of routinely used organic matrix materials with analyzes in MALDI (matrix assisted-laser desorption ionization) analysis. Thus uneven distribution of crystals with different sizes and shapes as well as background peaks in the low mass range resulting from matrix molecules is eliminated. Advantages of LAET imaging technique include not only improved spatial resolution but also photoelectron capture dissociation which produces predictable fragment ions.
Highlights
We describe the new application of a newly developed soft ionization approach based on laser activated electron tunneling (LAET)[15,16,17] from semiconductor nanoparticles of bismuth cobalt zinc oxide
These nanoparticles can absorb UV irradiation and have high electron mobility. Nanoparticles such as gold, titanium dioxide, carbon nanotubes and zinc oxide have been used as inorganic matrix materials for MALDI and SALDI MS analysis for many years[18,19,20,21,22], research efforts have been focused only on their roles as energy mediators
Compared with other approaches for direct tissue analysis, LAET offers the opportunities for endogenous metabolites of plants to be ionized and dissociated from biological context without background peaks
Summary
We describe the new application of a newly developed soft ionization approach based on laser activated electron tunneling (LAET)[15,16,17] from semiconductor nanoparticles of bismuth cobalt zinc oxide. These nanoparticles can absorb UV irradiation and have high electron mobility. This work is aimed to demonstrate the roles of photo-generated electrons in ionization of biological molecules. It is applied as a new avenue for imaging of endogenous metabolites present in plant leaves
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