Abstract
Hyperpolarized [1‐13C] pyruvate MRS can measure cardiac pyruvate dehydrogenase (PDH) flux in vivo through 13C‐label incorporation into bicarbonate. Using this technology, substrate availability as well as pathology have been shown to modulate PDH flux. Clinical protocols attempt to standardize PDH flux with oral glucose loading prior to scanning, while rodents in preclinical studies are usually scanned in the fed state. We aimed to establish which strategy was optimal to maximize PDH flux and minimize its variability in both control and Type II diabetic rats, without affecting the pathological variation being assessed. We found similar variances in the bicarbonate to pyruvate ratio, reflecting PDH flux, in fed and fasted/glucose‐loaded animals, which showed no statistically significant differences. Furthermore, fasting/glucose loading did not alter the low PDH flux seen in Type II diabetic rats. Overall this suggests that preclinical cardiac hyperpolarized magnetic resonance studies could be performed either in the fed or in the fasted/glucose‐loaded state. Centres planning to start new clinical studies with cardiac hyperpolarized magnetic resonance in man may find it beneficial to run small proof‐of‐concept trials to determine whether metabolic standardizations by oral or intravenous glucose load are beneficial compared with scanning patients in the fed state.
Highlights
The heart catabolizes a mix of fatty acids (FAs), glucose, lactate and ketone bodies to meet its high energy demand.[1]
Fasting plasma glucose and insulin levels were very variable in the Type II diabetes mellitus (T2DM) group, which resulted in a highly variable homeostatic model assessment of insulin resistance (HOMA‐IR) score (Figure 2C), reflecting different degrees of insulin resistance in the nine T2DM rats
We compared the in vivo cardiac metabolism of [1‐13C] pyruvate in the T2DM model with control animals both in the fed state and 30 min after an intravenous glucose challenge delivered to a fasted animal
Summary
The heart catabolizes a mix of fatty acids (FAs), glucose, lactate and ketone bodies to meet its high energy demand.[1]. (PDH) complex links glycolysis with the tricarboxylic acid (TCA) cycle and high levels of acetyl‐CoA derived from FA oxidation inhibit this multi‐enzyme complex both allosterically and via the activation of PDH kinases, which reversibly phosphorylate and inhibit PDH. PDH is dephosphorylated by PDH phosphatases, which are activated by calcium, by magnesium and by insulin signalling. This dephosphorylation and activation of PDH is impaired in in the diabetic heart.[5] In the diabetic heart impaired insulin signalling leads to inhibition of PDH activity through upregulation of PDH kinases.[6] Inactivation of PDH with continued flux through glycolysis controls the switch between aerobic and anaerobic glucose metabolism, which occurs, for example, in cardiac ischemia.[7]
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