In the late 1970s, he was the first to use
magnetic resonance spectroscopy on a whole organ, the excised brain of a hedgehog.
Not exact matches
To map the minute landscape of molecules, at scales as tiny as just tenths of a nanometer, and help decipher their functions, structural biologists have long relied
on two tools: nuclear
magnetic resonance, or NMR,
spectroscopy and X-ray crystallography.
Unfortunately, nature is not always willing to easily part with its secrets, forcing scientists to rely
on sophisticated imaging technology — nuclear
magnetic resonance (NMR)
spectroscopy or mass spectrometry, for example — to decipher the molecular formula of newly discovered organic compounds so they can be replicated in the lab.
Important research in medicine and biology relies
on nuclear
magnetic resonance (NMR)
spectroscopy, but until now, it has been limited in spatial resolution and typically requires powerful microwave fields.
He used infrared
spectroscopy to verify the presence of water
on precursor lead - oleates, and nuclear
magnetic resonance to show that the lead oleate acted as a drying agent, grabbing water out of the solvent.
Nelson wlll present «A pilot study exploring metabolic dysfunction in trans - sexual women: Novel insight from
magnetic resonance spectroscopy» as part of the poster session «Metabolism and Diabetes»
on Wednesday, Nov. 18, from 1:30 PM to 2:30 PM EST in Rhode / Severn Room of the Crowne Plaza Annapolis Hotel.
He touches
on its various isotopes and alludes to their relevance in nuclear
magnetic resonance and Mossbauer
spectroscopy (later covered in detail by an Essex colleague Brian Fitzsimmons).
X-ray crystallography and, more recently, nuclear
magnetic resonance spectroscopy are the most common tools to see how the amino acids in a protein chain arrange themselves based
on their attractive and repulsive energies, but they say nothing about the forms the proteins may take along the way, Onuchic said.
Dr. Gore's research program is focused
on the development and application of imaging, especially
magnetic resonance imaging and
spectroscopy techniques, in clinical and basic science.
The technology brings together the power of nuclear
magnetic resonance spectroscopy, which yields a remarkable peek into molecular interactions, and the ability to re-create the extreme conditions found
on the tundra, in the deep ocean, or underground — conditions relevant to some of the biggest questions that scientists at DOE laboratories such as PNNL ask.
On the other hand, dynamic nuclear polarization of molecules via nitrogen vacancy centers has important applications in nuclear
magnetic resonance spectroscopy since it would greatly increase the standard sensitivity of current scanners.
For Mansfield, his postdoctoral work
on nuclear
magnetic resonance spectroscopy in doped metals gradually transitioned into scanning his first live human subject with the newly invented MRI technique.
He'd found his way from the University of Utrecht, in the Netherlands, where he'd done his PhD
on Nuclear
Magnetic Resonance (NMR)
spectroscopy, to Uppsala, in Sweden, where as a young post-doc he was learning X-ray crystallography from Alwyn Jones.
Proton
magnetic resonance spectroscopy (1H - MRS) was performed with a 1.5 T MR system
on a voxel in the bilateral ACC in 85 chronic pain patients and 20 age - matched normal control subjects.