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NMR supersequences and multiple receivers in small molecule analysis

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Join us on Tuesday, November 3, to find out how significant gains in both speed and sensitivity can be achieved in well-designed NOAH (NMR by ordered acquisition using 1H detection) supersequences.

18 Oct 2020
Edward Carter
Publishing / Media

Expert insights

Dr. Eriks Kupce, principal scientist at Bruker UK

Join Dr. Eriks Kupce, principal scientist at Bruker UK, as he introduces the concept of constructing NMR supersequences from modules that are simple modifications of conventional NMR sequences. The proposed method is based on the 'domino principle' - the output of the previous module must match the input of the following module.

In this webinar, Kupce will show that significant gains in both speed and sensitivity can be achieved in well-designed NOAH (NMR by ordered acquisition using 1H detection) supersequences. Furthermore, such supersequences can be constructed with a particular application in mind, for instance, establishing the structure of small molecules from a single measurement. Combining NOAH with the use of multiple receivers and multi-nuclear detection offers further enhancements.

Register here

Key learning objectives:

  • Learn how to construct supersequences
  • How to set up NOAH experiments
  • How to process the NOAH data

Who should attend?

  • Students and postdocs who wish to learn about new and emerging techniques in NMR spectroscopy
  • Group leaders and lab technicians who wish to improve the efficiency of their research and facilities

Certificate of attendance

All webinar participants can request a certificate of attendance including a learning outcomes summary for continuing education purposes.

This webinar will run on Tuesday, November 3, at:

  • 16:00 GMT
  • 17:00 CEST
  • 08:00 PDT
  • 11:00 EDT

Register for this webinar here>>

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NMR and EPR SpectroscopyNuclear magnetic resonance (NMR) spectroscopy is used to resolve the local chemical environment of atomic nuclei with spin, revealing information on molecular structure, dynamic processes and chemical reactions of organic molecules, from proteins to synthetics. Electron paramagnetic resonance (EPR) also known as electron spin resonance (ESR) spectroscopy is used to detect and quantify paramagnetic species in a sample, including free radicals as transition metal ions. By immersing the sample in a strong magnetic field, both NMR and EPR spectrometers probe the sample with either radio waves or microwaves respectively. A range of benchtop, solid-state and time domain NMR spectrometers & EPR spectrometers are available, as well as NMR tubes, NMR solvents, software, coils, and magnets. Find the best NMR & EPR equipment in our peer-reviewed product directory: compare products, check customer reviews and receive pricing direct from manufacturers.SpectroscopySpectroscopy is a technique that analyzes the interaction of light with matter to study molecular properties, concentrations, and structural information. Widely used in chemical, pharmaceutical, and environmental analysis, spectroscopy offers insights into molecular composition and helps identify unknown compounds. It plays a key role in quality control, research, and diagnostics. Browse our peer-reviewed product directory to compare spectroscopy tools, read reviews, and get prices directly from manufacturers.Molecular DiagnosticsMolecular diagnostics use an individual’s genetic code and gene expression to diagnose and monitor diseases. The technique is used increasingly in the field of infectious diseases and oncology, as well as areas such as coagulation, HLA typing and pharmacogenomics. Molecular diagnostics plays a pivotal role in personalized medicine.

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NMR supersequences and multiple receivers in small molecule analysis