Reduction of RF-induced Sample Heating with a Scroll Coil Resonator Structure for Solid-state NMR Probes

Overview

Journal J Magn Reson

Publisher Elsevier

Date 2005 Feb 12

PMID 15705511

Citations 59

Authors

John A Stringer

Charles E Bronnimann

Charles G Mullen

Donghua H Zhou

Sara A Stellfox

Ying Li

Evan H Williams

Chad M Rienstra

Affiliations

Soon will be listed here.

Abstract

Heating due to high power 1H decoupling limits the experimental lifetime of protein samples for solid-state NMR (SSNMR). Sample deterioration can be minimized by lowering the experimental salt concentration, temperature or decoupling fields; however, these approaches may compromise biological relevance and/or spectroscopic resolution and sensitivity. The desire to apply sophisticated multiple pulse experiments to proteins therefore motivates the development of probes that utilize the RF power more efficiently to generate a high ratio of magnetic to electric field in the sample. Here a novel scroll coil resonator structure is presented and compared to a traditional solenoid. The scroll coil is demonstrated to be more tolerant of high sample salt concentrations and cause less RF-induced sample heating. With it, the viable experimental lifetime of a microcrystalline ubiquitin sample has been extended by more than an order of magnitude. The higher B1 homogeneity and permissible decoupling fields enhance polarization transfer efficiency in 15N-13C correlation experiments employed for protein chemical shift assignments and structure determination.

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