S. Sýkora scite author profile

Nuclear magnetic resonance (NMR) spectroscopy is a powerful analytical technique, but its low sensitivity and highly sophisticated, costly, equipment severely constrain more widespread applications. Here we show that a non-resonant planar transceiver microcoil integrated in a microfluidic chip (detection volume 25 nl) can detect different nuclides in the full broad-band range of Larmor frequencies (at 9.4 T from 61 to 400 MHz). Routine one-dimensional (1D) and two-dimensional (2D), homo-and heteronuclear experiments can be carried out using the broad-band coil set-up. Noteworthy, heteronuclear 2D experiments can be performed in a straightforward manner on virtually any combination of nuclides (from classical 1 H-13 C to more exotic combinations like 19 F-31 P) both in coupled and decoupled mode. Importantly, the concept of a non-resonant system provides magnetic fieldindependent NMR probes; moreover, the small-volume alleviates problems related to field inhomogeneity, making the broad-band coil an attractive option for, for example, portable and table-top NMR systems.

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Vibrational corrections in NMR spectra of oriented molecules

Sýkora¹,

Volt

Bösiger

et al. 1979

Journal of Magnetic Resonance (1969)

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Improving the Performance of High-Precision qNMR Measurements by a Double Integration Procedure in Practical Cases

Schoenberger

Menges

Bernstein³

et al. 2016

Anal. Chem.

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Quantitative (1)H NMR (qNMR) is a widely applied technique for compound concentration and purity determinations. The NMR spectrum will display signals from all species in the sample, and this is generally a strength of the method. The key spectral determination is the full and accurate determination of one or more signal areas. Accurate peak integration can be an issue when unrelated peaks resonate in an important integral region. We describe a "hybrid" approach to signal integration that provides an accurate estimation of signal area, removing the component(s) that may arise from unrelated peaks. This is achieved by using the most accurate integration method for the region and removing unwanted contributions. The key to this performing well, and in almost all cases, is the use of areas from deconvolved peaks. We describe this process and show that it can be very successfully applied to cases where the highest precision is required and for more common cases of NMR-based quantitation.

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Quantum theory and the bayesian inference problems

Sýkora

1974

J Stat Phys

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S. Sýkora

Technical Aspects of Fast Field Cycling

Multinuclear nanoliter one-dimensional and two-dimensional NMR spectroscopy with a single non-resonant microcoil

Vibrational corrections in NMR spectra of oriented molecules

Improving the Performance of High-Precision qNMR Measurements by a Double Integration Procedure in Practical Cases

Quantum theory and the bayesian inference problems

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