This study introduced sandwich-structured copperglass substrates for standardization of laser desorption and plasma ionization. For standardized quantitative analysis, cavities were constructed which allow better reproducibility in droplet deposition and for laser application. Applying the diode laser, molten substrate material is incorporated into the glass, being trapped inside. Therefore, this method can be separated from laser ablation, achieving high ion signals without ablating material from the surface. Flexible microtube plasma (FμTP) was selected as the ionization source, this being the first time that laser desorption and FμTP ionization are coupled. This laser−plasma interface was applied to the detection of cholesterol, which showed a significantly improved limit of detection of 0.46 ng and linear dynamic range of 3 orders of magnitude in positive ion mode compared to other (ambient air mass spectrometry) methods. The main reason was the change of phase on the copper surface. The dehydrated molecule [M-H 2 O+H] + was the base peak of the spectrum and no further dissociation or fragmentation was observed. Blood plasma was spiked with cholesterol. In a 1:100 chloroform dilution, the presence of the plasma was neglectable and led to the same detection limits and linear dynamic range as in the cholesterol standard. No sample preparation or internal standards were needed for calibration. The physical effects of the surface modification were investigated, including the calculation of the laser beam waist to simplify the comparison and reproducibility of results.
Ionization
mechanisms of different lipid classes and other hydrophobic
compounds have been evaluated in an ambient air laser-desorption flexible
microtube plasma ionization (LD-FμTPi) setup, without sample
manipulation. Lipids require a minimum laser fluency of 27 W/mm2 for efficient desorption and detection, providing the possibility
for temperature-programmed laser desorption of different lipid classes.
The flexible microtube plasma (FμTP) produces oxygen addition
to double bonds, even to polyunsaturated molecules. The characteristic
fragmentation pattern of phospholipids consisting of the neutral loss
of the phosphocholine head group was verified. The formation of dimers
due to hydrogen bonding and dispersion forces was observed as well.
In this sense, soft ionization capabilities of the FμTP were
proven in both ion modes. Ambient air mass spectrometry methods often
suffer from decreased reproducibility, for instance, due to changing
atmospheric conditions or sensitive positioning of the ion source.
It was shown that neutrals become increasingly unstable above a distance
of 7 ± 1 mm to the spectrometer’s inlet, providing estimates
for the free volume in LD-FμTPi MS. In this sense, no guided
transport is required. The ion plume ejected from the plasma can be
altered by applying a bias voltage to the copper substrate. Ions can
be detected at −950 V, 300 V (negative ion mode) and −400
V, 900 V (positive ion mode), respectively. The ions are guided through
an internal electric field gradient of the FμTP that arises
from charged capillary walls, ideal for ion detection. In conclusion,
this makes the method fast, robust, and flexible.
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