A combination nanostructured matrix with metal Au nanoislands and semiconductor TiO 2 nanowires is presented to enhance both desorption and ionization efficiency in laser desorption/ionization (LDI) mass spectrometry. The heterostructure of Au nanoislands on TiO 2 nanowires was fabricated via (1) TiO 2 nanowire synthesis through a modified wetcorrosion method and (2) Au nanoisland formation through thermal annealing of a sputtered Au layer on the TiO 2 nanowires. Herein, the synergistic effect of this heterostructure for highly efficient ion production was experimentally elucidated in terms of the formation of high temperature on the surface of Au and the creation of a Schottky barrier at the Au−TiO 2 interface. Finally, four types of immunosuppressors were analyzed to demonstrate the improved ionization performance of the heterostructure for LDI mass spectrometry.
In
this work, medical diagnosis of sepsis was conducted via quantitative
analysis of lysophosphatidylcholine 16:0 (LPC 16:0) by using matrix-assisted
laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry
based on a parylene-matrix chip. In the first step, specific mass
peaks for the diagnosis of sepsis were searched by comparing MALDI-TOF
mass spectra of sepsis patient sera with healthy controls and pneumonia
patient sera. Two mass peaks at m/z = 496.3 and 518.3 were chosen as those that are specifically different
for sepsis sera to compare with healthy controls and pneumonia patient
sera. These mass peaks were identified to be protonated and sodium
adducts of LPC 16:0 by using tandem mass spectra (MS2 and
MS3) of purely synthesized LPC 16:0 and extracted LPC 16:0
from a healthy control and a sepsis patient. In the next step, a standard
curve for LPC 16:0 for the quantitative analysis of LPC 16:0 with
MALDI-TOF MS based on the parylene-matrix chip was prepared, and the
statistical correlation to the LC-MS analysis results was demonstrated
by using the Bland–Altman test and Passing–Bablok regression.
Finally, MALDI-TOF MS based on the parylene-matrix chip was used for
the quantification of LPC 16:0 with sera from patients with severe
sepsis and septic shock (n = 143), pneumonia patients
(n = 12), and healthy sera (n =
31). The sensitivity and the selectivity of medical diagnosis of sepsis
was estimated to be 97.9% and 95.5% by using MALDI-TOF MS based on
the parylene-matrix chip, respectively.
The physicochemical properties of nanostructured substrates significantly impact laser desorption/ionization mass spectrometry (LDI-MS) performance. Fundamental understanding of the substrate properties can provide insights into the design and development of an efficient LDI matrix. Herein, a hybrid matrix of nanoporous Au-modified TiO 2 nanowires (npAu-TNW) is developed to achieve enhanced LDI-MS performance. Its origin is investigated based on hybrid matrix properties including photo-thermal conversion and electronic band structure. Notably, further improvement is obtained in the npAu-TNW than in the pristine TNW and non-porous Au nanoisland-modified TNW (Au-TNW) hybrid, which is attributed to the laser-induced surface restructuring/ melting phenomenon. Noticeable surface restructuring/melting occurs in the npAu by laser exposure through efficient photo-thermal conversion of the highly porous npAu. At this instant of npAu structural changes, internal energy transfer from the npAu to the adsorbed analyte is promoted, which facilitates desorption. Moreover, strain is developed in situ in the TNW adjacent to the restructuring npAu, which distorts the TNW lattice. The strain development reduces recombination rates of charge carriers by introducing shallow trap levels in the bandgap, which enhances the ionization process. Ultimately, the high LDI-MS performance based on the npAu-TNW hybrid matrix is demonstrated by analyzing neurotransmitter.
Recently,
the parylene-matrix chip was developed for quantitative
analysis of small molecules less than 1 kDa. In this study, MALDI-TOF
MS based on the parylene-matrix chip was performed to clinically diagnose
intrahepatic cholangiocarcinoma (IHCC) and colorectal cancer (CRC).
The parylene-matrix chip was applied for the detection of small cancer
biomarkers, including N-methyl-2-pyridone-5-carboxamide
(2PY), glutamine, lysophosphatidylcholine (LPC) 16:0, and LPC 18:0.
The feasibility of MALDI-TOF MS based on the parylene-matrix chip
was confirmed via analysis of spot-to-spot and shot-to-shot reproducibility.
Serum metabolite markers of IHCC, N-methyl-2-pyridone-5-carboxamide
(2PY), and glutamine were quantified using MALDI-TOF MS based on the
parylene-matrix chip. For clinical diagnosis of CRC, two water-insoluble
(barely soluble) biomarkers, lysophosphatidylcholine (LPC) 16:0 and
LPC 18:0, were quantified. Finally, glutamine and LPC 16:0 were simultaneously
detected at a range of concentrations in sera from colon cancer patients
using the parylene-matrix chip. Thus, this method yielded high-throughput
detection of cancer biomarkers for the mixture samples of water-soluble
analytes (2PY and glutamine) and water-insoluble analytes (LPC 16:0
and LPC 18:0).
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