Matrix-assisted laser desorption time-of-flight mass spectrometry has been used to produce quasi-molecular ion signals from underivatized mixed-base single-stranded DNA oligomers ranging from 10 to 67 nucleotides in length. These results were obtained with a new matrix material, 3-hydroxypicolinic acid (3-hydroxypyridine-2-carboxylic acid) which showed significant improvement over many previously reported matrices studied in terms of mass range available, signal-to-noise ratio, and the ability to analyze mixed-base oligomers. The desorption and simultaneous ionization was by pulsed laser light at 10 to 50 mJ/cm2, studied at 266, 308, and 355 nm. Spectra taken at 266 nm provided the smallest amounts of doubly charged and dimer ions--characteristics desirable for DNA sequencing by this technology. Negative-ion spectra were uniformly superior to positive-ion spectra. This new matrix also is quite effective for molecular weight determinations of peptides and proteins in both positive- and negative-ion modes.
Small-diameter carbon nanotubes (CNTs) are shown to enable exceptionally fast transport of water vapor under a concentration gradient driving force. Thanks to this property, membranes having sub-5 nm CNTs as conductive pores feature outstanding breathability while maintaining a high degree of protection from biothreats by size exclusion.
A new methodology, matrix-enhanced secondary ion mass spectrometry (ME-SIMS), is reported for the molecular analysis of biomaterials. The technique applies static secondary ion mass spectrometry (SSIMS) techniques to samples prepared in a solid organic matrix similar to sample preparations used in matrix-assisted laser desorption/ionization (MALDI). Molecular ions are observed in this ion beam sputtering of organic mixtures for peptides and oligonucleotides up to masses on the order of 10 000 Da. This matrix-enhanced SIMS exhibits substantial increases in the ionization efficiency of selected analyte molecules compared to conventional SSIMS processes. Thus, higher mass peptides, proteins, and nucleic acids become accessible to near-surface analysis by ion beam techniques, and subpicomole sensitivity has been demonstrated. A number of matrices were examined for their efficiency in ME-SIMS applications, and these initial matrix studies focused on common MALDI matrices and their isomers. The results of this survey indicate that 2,5-dihydroxybenzoic acid provides the best general enhancement of molecular secondary ions emitted from analyte/matrix mixtures.
Studies relating the magnesium (Mg) content of calcified skeletons to temperature often report unexplained deviations from the signature expected for inorganically grown calcite. These "vital effects" are believed to have biological origins, but mechanistic bases for measured offsets remain unclear. We show that a simple hydrophilic peptide, with the same carboxyl-rich character as that of macromolecules isolated from sites of calcification, increases calcite Mg content by up to 3 mole percent. Comparisons to previous studies correlating Mg content of carbonate minerals with temperature show that the Mg enhancement due to peptides results in offsets equivalent to 7 degrees to 14 degrees C. The insights also provide a physical basis for anecdotal evidence that organic chemistry modulates the mineralization of inorganic carbonates and suggest an approach to tuning impurity levels in controlled materials synthesis.
Matrix-assisted laser desorption with concomitant ionization (MALDI) in conjunction with time-of-flight mass spectrometry (TOF-MS) has been used to analyze underivatized random-base single-stranded DNA (ssDNA) oligomers ranging from 10 to 89 nucleotides in length by embedding them in a solid matrix of 3-hydroxypicolinic acid. At 355-nm desorption wavelength, mass spectra of positive and negative ions measured by reflecting and linear time-of-flight mass spectrometers are compared. Results from the linear system show the ionization yield is approximately equal for each polarity. Metastable ion decay is significant for the larger ssDNA oligomer ions, which results in a decrease in signal intensity and the broadening of mass peaks. In order to obtain an acceptable signal-to-noise ratio on a reflecting TOF system, a higher laser irradiance is needed, which consequently causes further degradation of mass resolution. With the apparent advantages of better sensitivity and mass resolution, it is concluded that a linear TOF system is better suited for the mass spectrometric analysis of ssDNA oligomers larger than about a 25-mer. The current system permits one-base resolution up to about a 40-mer. Mass accuracy for a 20-mer or smaller is within +/- 0.05%. Comparison of mass spectra from 5-ns and 35-ps pulse widths at the same energy density shows no significant differences. Mechanisms for oligonucleotide ion production in these experiments are discussed.
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