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Bruker Daltonics Announces Refrigerated 15 Tesla FTMS Magnet
Product News

Bruker Daltonics Announces Refrigerated 15 Tesla FTMS Magnet

Bruker Daltonics Announces Refrigerated 15 Tesla FTMS Magnet
Product News

Bruker Daltonics Announces Refrigerated 15 Tesla FTMS Magnet

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At the 2006 ASMS conference, Bruker Daltonics has announced tools to accelerate the detailed top-down characterization of proteins using the Company's apex®-Qe line of hybrid Fourier Transform mass spectrometers (Q-q-FTMS).

These top-down tools include the 15.0 Tesla (T) refrigerated (R-series) FTMS magnet, along with a proprietary method of charge deconvolution, based on maximum entropy and an advanced monoisotopic peak finder, called SNAP2™.

FTMS top-down methods of protein characterization are based on two key experimental capabilities: i) accurate molecular weight determination of the intact protein, and ii) fragmentation of the intact protein and analysis of the resulting complex mixture of fragments.

Both benefit from FTMS detection with simultaneous mass accuracy, dynamic range and ultra-high resolution.

Ultimate FTMS performance is largely governed by magnetic field strength. Dynamic range, mass measurement accuracy, and mass resolving power in FTMS improve dramatically with increasing magnetic field.

The actively-shielded 15.0T magnet, developed in collaboration with the affiliated Bruker BioSpin group, will enable researchers to investigate larger proteins by top-down analysis.

The 15T magnet is part of Bruker Daltonics' R-series of FTMS magnets that incorporate cryostats equipped with cryocooler refrigeration that replaces the conventional liquid nitrogen reservoir.

The geometry of the apex-Qe FTMS enables mass-selective efficient enrichment of low abundant protein species, which can then be investigated using a combination of fragmentation methods including CID, ECD, and/or IRMPD.

The resulting complex mass spectra are feature-rich and have high-information content on primary protein structure, as well as on important post-translational modifications.

The intrinsic complexity of, for example, ECD spectra requires sophisticated data processing tools that can effectively extract mass information.

To facilitate this, Bruker Daltonics has now implemented MaxEnt, a charge deconvolution method that is based on the Maximum Entropy algorithm, to calculate a neutral-based mass spectrum that is amenable to data analysis routines such as BioTools™.

Moreover, by combining the ion signals represented by multiple charge states, MaxEnt also improves the fidelity of isotopic distributions and increases the overall spectral signal-to-noise ratio.

Another challenge associated with the processing of top-down data is the extraction of monoisotopic masses from the experimentally observed isotopic profiles.

Bruker Daltonics has developed SNAP2, a peak-picking module that determines and extracts the monoisotopic mass information from high-resolution spectra of proteins and protein fragments, even when the monoisotopic mass peak cannot experimentally be observed.

The combination of these software features further strengthens the position of the apex-Qe as the preferred platform for detailed, ultra-high resolution top-down protein characterization.

"The ability to accurately extract monoisotopic peak information is crucial to analyzing feature-rich spectra from peptides and proteins," said Dr. Jon Amster, Professor of Chemistry at the University of Georgia.

"We are excited by the performance of the new SNAP2 algorithm and expect that it will significantly accelerate our biological MS efforts."

The Amster Research Group in the Department of Chemistry uses a 9.4T apex-Qe in their laboratory for the investigation of complex biological samples.

ASMS 2006, the 54th American Society for Mass Spectrometry Conference will be held May 28 - June 1, 2006 in Seattle, Washington in the Washington State Convention & Trade Center.