Waters unveils Synapt G2-Si, an advanced ion mobility-enhanced research Mass Spectrometer
Waters has now introduced the Synapt G2-Si Mass Spectrometer. The company is also previewing its UNIFI CCS Research Edition and the new TransOmics Version 2.0 informatics products for the new SYNAPT G2-Si mass spectrometer and demonstrating their benefits for a variety of small molecule applications and cutting-edge Omics-focused research.
The product was unveiled at the 61st conference of the American Society of Mass Spectrometry (ASMS).
The Synapt G2-Si System integrates a third dimension of resolution and separation power into a new suite of untargeted and targeted LC/MS/MS workflows. The powerful new tool gives researchers a means with which to gain a deeper understanding of molecular biology and disease mechanisms, to develop the next generation of healthcare treatments or chemical materials, or to screen food products or environmental samples for contaminants.
The advanced Mass Spectrometer now combines the unique power of Travelling Wave (T-Wave) Ion Mobility Separations with new data acquisition and informatics technologies, and collision cross section (CCS) measurements to bring to the toughest analytical applications, unparalleled information and confidence at a level not possible by mass and chromatographic separation alone.
It is the first MS system to elevate CCS alongside retention time and mass to charge ratio (m/z) as a robust, reliable identification parameter in library-based screening.
“CCS measurements have the potential to transform the way people screen for known compounds, because unlike parameters like retention time, CCS values are unaffected by different matrices and chromatographic methods, and give you a much higher level of confidence that you found what you’re looking for,” said Dr Severine Goscinny, Belgium Scientific Institute for Public Health, Brussels, Belgium.
The collision cross section of a molecule is an important distinguishing feature that is directly related to its chemical structure and three-dimensional conformation in the gas-phase. Like molecular mass, this additional orthogonal property of a molecule through the use of high-efficiency T-wave ion mobility technology gives scientists increased coverage and clarity for profiling mixtures or gaining additional measurements with which they can investigate chemical structures or better confirm a molecule’s identity.
Integrating separation by CCS into targeted and untargeted experiments through new high-definition data-directed-analysis (HD-DDA) and high definition multiple reaction monitoring (HD-MRM) modes brings compelling benefits to the most challenging qualitative and quantitative applications.
These include the maximized time-of-flight (Tof) duty cycle and effective sensitivity - of up to 10x in MS/MS mode - for targeted discovery and quantitation, improved LC/MS/MS efficiency with a 40 per cent improvement in the numbers of proteins identified from an E. coli sample and the identification of more than 2,000 proteins from a HeLa sample, routine ultra-sensitive MS/MS assays with the benefit of high resolution and accurate mass for targeted quantification experiments, physical separation of interferences away from the molecule or transition of interest on the basis of their collision cross section for improved selectivity when working with very complex matrices, besides a new and faster 2.5KHz solid state laser combined with new software for improved spatial resolution (down to 15µm) for cleaner mass spectral data and greater image throughput when performing experiments with MALDI imaging and T-wave ion mobility.