Quantum coherence spectroscopy to measure dietary fat retention in the liver
Lucas Lindeboom, Robin A. de Graaf, Christine I. Nabuurs, Petronella A. van Ewijk, Matthijs K.C. Hesselink, Joachim E. Wildberger, Patrick Schrauwen, Vera B. Schrauwen-Hinderling
Lucas Lindeboom, Robin A. de Graaf, Christine I. Nabuurs, Petronella A. van Ewijk, Matthijs K.C. Hesselink, Joachim E. Wildberger, Patrick Schrauwen, Vera B. Schrauwen-Hinderling
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Resource and Technical Advance Hepatology Metabolism

Quantum coherence spectroscopy to measure dietary fat retention in the liver

Abstract

The prevalence of fatty liver reaches alarming proportions. Fatty liver increases the risk for insulin resistance, cardiovascular disease, and nonalcoholic steatohepatitis (NASH). Although extensively studied in a preclinical setting, the lack of noninvasive methodologies hampers our understanding of which pathways promote hepatic fat accumulation in humans. Dietary fat retention is one of the pathways that may lead to fatty liver. The low (1.1%) natural abundance (NA) of carbon-13 (13C) allows use of 13C-enriched lipids for in vivo MR studies. Successful implementation of such methodology, however, is challenging due to low sensitivity of 13C-magnetic resonance spectroscopy (13C-MRS). Here, we investigated the use of 1-dimensional gradient enhanced heteronuclear single quantum coherence (ge-HSQC) spectroscopy for the in vivo detection of hepatic 1H-[13C]-lipid signals after a single high-fat meal with 13C-labeled fatty acids in 5 lean and 6 obese subjects. Postprandial retention of orally administered 13C-labeled fatty acids was significant (P < 0.01). Approximately 1.5% of the tracer was retained in the liver after 6 hours, and retention was similar in both groups (P = 0.92). Thus, a substantial part of the liver fat can originate directly from storage of meal-derived fat. The ge-HSQC can be used to noninvasively reveal the contribution of dietary fat to the development of hepatic steatosis over time.

Authors

Lucas Lindeboom, Robin A. de Graaf, Christine I. Nabuurs, Petronella A. van Ewijk, Matthijs K.C. Hesselink, Joachim E. Wildberger, Patrick Schrauwen, Vera B. Schrauwen-Hinderling

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Figure 4

Results from the in vivo experiments.

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Results from the in vivo experiments. (A and B) Typical example of the t...
(A and B) Typical example of the total lipid spectrum, acquired with STEAM (stimulated echo acquistion mode) 1H-MRS, and the concomitant 13C-edited lipid spectrum, acquired with the ge-HSQC (heteronuclear single quantum coherence) sequence. As no decoupling was applied, two lipid CH2 peaks are visible, which are separated by approximately 127 Hz. (C) The total IHL (intrahepatic lipid) pool (g/kg ww) for both lean (n = 5) and obese (n = 6) subjects at 1,5, 3.0, 4.5, and 6.0 hours after a high-fat meal. Total IHL did not change after the meal (repeated-measures ANOVA, P = 0.35). (D) The absolute concentration of 13C lipids (g/kg ww) in the liver is plotted in time, showing retention of 13C-labeled fatty acids after the meal (repeated-measures ANOVA, P < 0.01).