Hyperpolarized [1,3-13C2 ]ethyl acetoacetate is a novel diagnostic metabolic marker of liver cancer.

An increased prevalence of liver diseases such as hepatitis C and nonalcoholic fatty liver results in an augmented incidence of the most common form of liver cancer, hepatocellular carcinoma (HCC). HCC is most often found in the cirrhotic liver and it can therefore be challenging to rely on anatomical information alone when diagnosing HCC. Valuable information on specific cellular metabolism can be obtained with high sensitivity thanks to an emerging magnetic resonance (MR) technique that uses 13C labeled hyperpolarized molecules. Our interest was to explore potential new high contrast metabolic markers of HCC using hyperpolarized 13C-MR. This work led to the identification of a class of substrates, low molecular weight ethyl-esters, which showed high specificity for carboxyl esterases and proved in many cases to possess good properties for signal enhancement. In particular, hyperpolarized [1,3-13C2 ]ethyl acetoacetate (EAA) was shown to provide a metabolic fingerprint of HCC. Using this substrate a liver cancer implanted in rats was diagnosed as a consequence of an ∼4 times higher metabolic substrate-to-product ratio than in the surrounding healthy tissue, (p=0.009). Unregulated cellular uptake as well as cosubstrate independent enzymatic conversion of EAA, made this substrate highly useful as a hyperpolarized 13C-MR marker. This could be appreciated by the signal-to-noise (SNR) obtained from EAA, which was comparable to the SNR reported in a literature liver cancer study with state-of-the-art hyperpolarized substrate, [1-13C]pyruvate. Also, the contrast-to-noise (CNR) in the EAA based metabolic ratio images was significantly improved compared with the CNR in equivalent images reported using [1-13C]pyruvate.

[(11)C]-Acetoacetate PET imaging: a potential early marker for cardiac heart failure.

UNLABELLED: The ketone body acetoacetate could be used as an alternate nutrient for the heart, and it also has the potential to improve cardiac function in an ischemic-reperfusion model or reduce the mitochondrial production of oxidative stress involved in cardiotoxicity. In this study, [(11)C]-acetoacetate was investigated as an early marker of intracellular damage in heart failure. METHODS: A rat cardiotoxicity heart failure model was induced by doxorubicin, Dox(+). [(14)C]-Acetoacetate, a non-positron (ß-) emitting radiotracer, was used to characterize the arterial blood input function and myocardial mitochondrial uptake. Afterward, [(11)C]-acetoacetate (ß+) myocardial PET images were obtained for kinetic analysis and heart function assessment in control Dox(-) (n=15) and treated Dox(+) (n=6) rats. The uptake rate (K1) and myocardial clearance rate (k2or kmono) were extracted. RESULTS: [(14)C]-Acetoacetate in the blood was increased in Dox(+), from 2 min post-injection until the last withdrawal point when the heart was harvested, as well as the uptake in the heart and myocardial mitochondria (unpaired t-test, p <0.05). PET kinetic analysis of [(11)C]-acetoacetate showed that rate constants K1, k2 and kmono were decreased in Dox(+) (p <0.05) combined with a reduction of 24% of the left ventricular ejection fraction (p <0.001). CONCLUSION: Radioactive acetoacetate ex vivo analysis [(14)C], and in vivo kinetic [(11)C] studies provided evidence that [(11)C]-acetoacetate can assess heart failure Dox(+). Contrary to myocardial flow reserve (rest-stress protocol), [(11)C]-acetoacetate can be used to assess reduced kinetic rate constants without requirement of hyperemic stress response. The proposed [(11)C]-acetoacetate cardiac radiotracer in the investigation of heart disease is novel and paves the way to a potential role for [(11)C]-acetoacetate in cardiac pathophysiology.

A dual tracer PET-MRI protocol for the quantitative measure of regional brain energy substrates uptake in the rat.

We present a method for comparing the uptake of the brain's two key energy substrates: glucose and ketones (acetoacetate [AcAc] in this case) in the rat. The developed method is a small-animal positron emission tomography (PET) protocol, in which (11)C-AcAc and (18)F-fluorodeoxyglucose ((18)F-FDG) are injected sequentially in each animal. This dual tracer PET acquisition is possible because of the short half-life of (11)C (20.4 min). The rats also undergo a magnetic resonance imaging (MRI) acquisition seven days before the PET protocol. Prior to image analysis, PET and MRI images are coregistered to allow the measurement of regional cerebral uptake (cortex, hippocampus, striatum, and cerebellum). A quantitative measure of (11)C-AcAc and (18)F-FDG brain uptake (cerebral metabolic rate; µmol/100 g/min) is determined by kinetic modeling using the image-derived input function (IDIF) method. Our new dual tracer PET protocol is robust and flexible; the two tracers used can be replaced by different radiotracers to evaluate other processes in the brain. Moreover, our protocol is applicable to the study of brain fuel supply in multiple conditions such as normal aging and neurodegenerative pathologies such as Alzheimer's and Parkinson's diseases.

Mild experimental ketosis increases brain uptake of 11C-acetoacetate and 18F-fluorodeoxyglucose: a dual-tracer PET imaging study in rats.

Brain glucose and ketone uptake was investigated in Fisher rats subjected to mild experimental ketonemia induced by a ketogenic diet (KD) or by 48 hours fasting (F). Two tracers were used, (11)C-acetoacetate ((11)C-AcAc) for ketones and (18)F-fluorodeoxyglucose for glucose, in a dual-tracer format for each animal. Thus, each animal was its own control, starting first on the normal diet, then undergoing 48 hours F, followed by 2 weeks on the KD. In separate rats on the same diet conditions, expression of the transporters of glucose and ketones (glucose transporter 1 (GLUT1) and monocarboxylic acid transporter (MCT1)) was measured in brain microvessel preparations. Compared to controls, uptake of (11)C-AcAc increased more than 2-fold while on the KD or after 48 hours F (P < 0.05). Similar trends were observed for (18)FDG uptake with a 1.9-2.6 times increase on the KD and F, respectively (P < 0.05). Compared to controls, MCT1 expression increased 2-fold on the KD (P < 0.05) but did not change during F. No significant difference was observed across groups for GLUT1 expression. Significant differences across the three groups were observed for plasma beta-hydroxybutyrate (beta-HB), AcAc, glucose, triglycerides, glycerol, and cholesterol (P < 0.05), but no significant differences were observed for free fatty acids, insulin, or lactate. Although the mechanism by which mild ketonemia increases brain glucose uptake remains unclear, the KD clearly increased both the blood-brain barrier expression of MCT1 and stimulated brain (11)C-AcAc uptake. The present dual-tracer positron emission tomography approach may be particularly interesting in neurodegenerative pathologies such as Alzheimer's disease where brain energy supply appears to decline critically.

PET study of 11C-acetoacetate kinetics in rat brain during dietary treatments affecting ketosis.

Normally, the brain's fuel is glucose, but during fasting it increasingly relies on ketones (beta-hydroxybutyrate, acetoacetate, and acetone) produced in liver mitochondria from fatty acid beta-oxidation. Although moderately raised blood ketones produced on a very high fat ketogenic diet have important clinical effects on the brain, including reducing seizures, ketone metabolism by the brain is still poorly understood. The aim of the present work was to assess brain uptake of carbon-11-labeled acetoacetate (11C-acetoacetate) by positron emission tomography (PET) imaging in the intact, living rat. To vary plasma ketones, we used three dietary conditions: high carbohydrate control diet (low plasma ketones), fat-rich ketogenic diet (raised plasma ketones), and 48-h fasting (raised plasma ketones). 11C-acetoacetate metabolism was measured in the brain, heart, and tissue in the mouth area. Using 11C-acetoacetate and small animal PET imaging, we have noninvasively quantified an approximately seven- to eightfold enhanced brain uptake of ketones on a ketogenic diet or during fasting. This opens up an opportunity to study brain ketone metabolism in humans.

[11C] acetoacetate utilization by breast and prostate tumors: a PET and biodistribution study in mice.

PURPOSE: A significant positive correlation has been observed between ketone body availability and their uptake by tumor cells. Our objective was to evaluate [11C]acetoacetate as a potential tracer of ketone body utilization by breast and prostate tumors and to compare it with [11C]acetate. METHODS: Biodistribution studies were performed with [11C]acetoacetate and [11C]acetate in mice bearing breast or prostate tumors. The percentage of the injected dose accumulated per gram of tissue was determined. These results were complemented by dynamic positron emission tomography (PET) imaging of the radiotracer uptake and dosimetry calculations. RESULTS: [11C]Acetoacetate uptake was optimal between 5 and 30 min, with maximal uptake of 2.72, 2.42, 2.54, and 2.19% injected dose (%ID)/g for MC7-L1, MC4-L2, PC3, and LN-CaP tumors respectively. Tumor retention for [11C]acetoacetate tended to be higher than [11C]acetate, but this did not reach statistical significance. [11C]Acetate uptake was reached within 15 min with optimal uptake of 1.25, 2.30, and 0.96%ID/g for MC7-L1, MC4-L2, and PC-3 tumors, respectively. CONCLUSIONS: We observed a moderate uptake of [11C]acetoacetate in breast and prostate tumors with low background activity due to rapid elimination of this tracer. Further studies are warranted to determine if this tracer can detect slow-growing breast and prostate cancers in the clinical setting.

Monte Carlo spreadsheet modeling of stable isotope biosynthesis.

Metabolic physiologists often introduce stable isotopes, atoms containing additional neutrons, into molecules during biosynthesis. This tags the newly synthesized material by altering its mass. Monte Carlo analysis is implemented on a popular spreadsheet to analyze this process. An example is provided where acetoacetate is synthesized by condensation of two acetate moieties. The precursor acetate is present as a mixture of natural, and 13C enriched, acetate. Monte Carlo spreadsheet modeling captures the complexity of the multi-species isotope biosynthesis by repetitively performing multiple simultaneous Boolean calculations. The effects of increasing the number of molecules synthesized on the goodness of fit of between model and an exact analytical solution is illustrated.

Substrate selection in the isolated working rat heart: effects of reperfusion, afterload, and concentration.

A study of substrate selection in the isolated heart was made using 13C NMR isotopomer analysis, a method that unequivocally identifies relative substrate utilization. This technique has several advantages over conventional approaches used to study this problem. It detects the labeling of metabolic end-products present in tissue, as opposed to more indirect methods such as measurement of respiratory quotient, arteriovenous differences, or specific activity changes in the added substrate. It also has advantages over methods such as 14CO2 release, which may involve dilution of label with unlabeled pools before CO2 release. Furthermore, it can measure the relative oxidation of up to four substrates in a single experiment, which other labeling techniques cannot conveniently achieve. Substrate selection was considered in light of its effects on myocardial efficiency and recovery from ischemia. A mixture of four substrates (acetoacetate, glucose, lactate, and a mixture of long chain fatty acids), present at physiological concentration (0.17, 5.5, 1.2, and 0.35 mM, respectively), was examined. This is the first use of such a mixture in the study of substrate selection in an isolated organ preparation. At these concentrations, it was found that fatty acids supplied the majority of the acetyl-CoA (49%), and a substantial contribution was also provided by acetoacetate (23%). This suggests that the ketone bodies are a more important substrate than generally considered. Indeed, normalizing the relative utilizations on the basis of acetyl-CoA equivalents, ketone bodies were by far the preferred substrate. The relative lactate oxidation was only 15%, and glucose oxidation could not be detected. No change in utilization was detected after 15 min of ischemia followed by 40 min of reperfusion. The change in substrate selection with afterload was examined, to mimic the stress-related changes in workload found with ischemia. Only minor changes were found. Substrate selection from the same group of substrates, but employing concentrations observed during starvation, was also assessed. This represents the state during which most clinical treatments and evaluations are performed. In this case, acetoacetate was the most used substrate (78%), with small and equal contributions from fatty acids and endogenous substrates; the oxidation of lactate was suppressed.

Transport of beta-hydroxybutyrate and acetoacetate along rat nephrons: a micropuncture study.

The transport of ketone bodies across the luminal membrane of the nephron was studied by means of micropuncture techniques in rats in normal acid-base state. The concentration of beta-hydroxybutyrate (beta-HB) and acetoacetate (AcAc) in plasma, tubular fluid and urine was measured by an ultramicromethod using enzymatic cycling. At endogenous plasma ketone body concentration, approximately 80% of the filtered load of beta-HB and AcAc was reabsorbed in the proximal convoluted tubule, the remaining fraction being almost completely reabsorbed between the late proximal convoluted and the distal tubule; under these conditions, the urinary excretion of ketone bodies was less than 1% of the filtered load. A progressive elevation to steady-state levels of plasma beta-HB resulted in a progressive reduction of the fractional reabsorption of beta-HB and AcAc in the proximal convoluted tubule, which means that reabsorption of ketone bodies in this nephron segment is saturable. No net secretion of ketone bodies could be demonstrated along the nephron even at the highest plasma ketone body concentrations reached. In clearance experiments, the capacity of the rat kidney for reabsorbing both beta-HB and AcAc was found to be limited by a maximal tubular capacity (Tm). The data suggest that, in the young Wistar rat nephron, most of the reabsorption of ketone bodies is carrier mediated.

Positron emission tomography study of 11C-acetoacetate uptake in a freezing lesion in cat brain, as correlated with 11C-tyrosine and 18F-fluorodeoxyglucose uptake, and with proton magnetic resonance imaging.

Using 11C-ACAC, 11C-TYR, and 18FDG as tracers, brain uptake of these substrates was studied in cat brain with a freezing lesion, by PET, at 1 day to 3 weeks after injury. Also MRI was conducted. Although the MRI scans depicted the morphological changes, such as edema formation, the PET studies of the brain uptake of substrates visualized the pattern of changes, which in the fresh lesion was largely governed by impairment of the BBB, but in the chronic lesion they were indicative of the proliferation of reactive cells in the process of tissue repair and edema resolution.

Effect of insulin on ketone body clearance studied by a ketone body "clamp" technique in normal man.

The effect of elevated plasma insulin concentration (55 +/- 2 mU/l) on peripheral clearance and production of total ketone bodies was determined using 3-14C-acetoacetate tracer infusions. Nine normal subjects were studied twice, once during insulin infusion (20 mU.m-2.min-1), once during basal plasma insulin concentrations (controls). Blood total ketone body concentrations (sum of acetone, acetoacetate and beta-hydroxybutyrate) were maintained in both studies at 2 mmol/l by feedback-controlled sodium acetoacetate infusions. The coefficient of variation of total ketone body concentrations during the two clamp studies was 10 and 11% respectively. The sodium acetoacetate infusion rate required during the clamp was 55 +/- 4% higher during hyperinsulinaemia than in controls (p less than 0.005). This was due to increased total ketone body clearance (8.4 +/- 0.7 vs 6.7 +/- 0.4 ml.kg-1.min-1, p less than 0.015), and to enhanced suppression of ketone body production (p less than 0.01). Hyperketonaemia alone decreased ketone body production by 42% and diminished ketone body clearance by 46%, the former being enhanced, the latter being in part antagonised by insulin. Since the plasma insulin concentrations were within those observed in patients treated for diabetic ketoacidosis, the data suggest that the antiketotic effect of insulin therapy results in part from an increase in peripheral ketone body disposal.

Some histological and metabolic properties of an isolated perfused rat brain preparation with special reference to monoamine metabolism.

A method is described for perfusing the rat head which results in perfusion of the brain, its covering and the bony skull only. Dye and latex injection studies showed that there was no perfusion of extracranial tissue and thus it was not necessary to remove the lower jaw and facial tissues as described by previous authors. Perfusion with fluorescein demonstrated that the whole brain was perfused. Light microscopy after two hours of perfusion revealed no deterioration in brain-structure. Electron microscopy showed a small increase in the extracellular space and the perivascular space with good preservation of subcellular organelles. Glucose and acetoacetate removal were very similar to those reported for the adult rat in vivo as measured by arterio-venous differences. The concentrations of 5-hydroxytryptamine, dopamine and noradrenaline are maintained at values close to those in vivo during a 2-hr perfusion with a basal medium and the preparation will maintain linear rates of 5-hydroxytryptamine synthesis for 2 h when the medium contains L-tryptophan and tranylcypromine, at rates similar to those measured in vivo. The rate of uptake of L-tryptophan into the brain is similar to that reported after L-tryptophan loading in vivo. The histological and metabolic properties of the preparation are close to those observed in vivo. The method could provide a way in which monoamine metabolism in particular could be studied using an experimental model closer in its properties to the in vivo situation than tissue preparations such as slices or homogenates.