Assessment of Rapid Hepatic Glycogen Synthesis in Humans Using Dynamic C Magnetic Resonance Spectroscopy

Overview

Journal Hepatol Commun

Specialty Gastroenterology

Date 2020 Mar 7

PMID 32140658

Citations 12

Authors

Stefan Stender

Vlad G Zaha

Craig R Malloy

Jessica Sudderth

Ralph J DeBerardinis

Jae Mo Park

Affiliations

Soon will be listed here.

Abstract

Carbon-13 magnetic resonance spectroscopy (MRS) following oral intake of C-labeled glucose is the gold standard for imaging glycogen metabolism in humans. However, the temporal resolution of previous studies has been >13 minutes. Here, we describe a high-sensitivity C MRS method for imaging hepatic glycogen synthesis with a temporal resolution of 1 minute or less. Nuclear magnetic resonance spectra were acquired from the liver of 3 healthy volunteers, using a C clamshell radiofrequency transmit and paddle-shaped array receive coils in a 3 Tesla magnetic resonance imaging system. Following a 15-minute baseline C MRS scan of the liver, [1-C]-glucose was ingested and C MRS data were acquired for an additional 1-3 hours. Dynamic change of the hepatic glycogen synthesis level was analyzed by reconstructing the acquired MRS data with temporal resolutions of 30 seconds to 15 minutes. Plasma levels of C-labeled glucose and lactate were measured using gas chromatography-mass spectrometry. While not detected at baseline C MRS, [1-C]-labeled α-glucose and β-glucose and glycogen peaks accumulated rapidly, beginning as early as ~2 minutes after oral administration of [1-C]-glucose. The [1-C]-glucose signals peaked at ~5 minutes, whereas [1-C]-glycogen peaked at ~25 minutes after [1-C]-glucose ingestion; both signals declined toward baseline levels over the next 1-3 hours. Plasma levels of C-glucose and C-lactate rose gradually, and approximately 20% of all plasma glucose and 5% of plasma lactate were C-labeled by 2 hours after ingestion. We observed rapid accumulation of hepatic [1-C]-glycogen following orally administered [1-C]-glucose, using a dynamic C MRS method with a temporal resolution of 1 minute or less. Commercially available technology allows high temporal resolution studies of glycogen metabolism in the human liver.

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