Abstract
Hepatocellular carcinoma (HCC) is one of the leading causes of cancer-related deaths. Imaging plays a crucial role in the early detection of HCC, although current methods are limited in their ability to characterize liver lesions. Most recently, deuterium metabolic imaging (DMI) has been demonstrated as a powerful technique for the imaging of metabolism in vivo. Here, we assess the metabolic flux of [6,6'-(2) H(2) ] fructose in cell cultures and in subcutaneous mouse models at 9.4 T. We compare these rates with the most widely used DMI probe, [6,6'-(2) H(2) ] glucose, exploring the possibility of developing (2) H fructose to overcome the limitations of glucose as a novel DMI probe for detecting liver tumors. Comparison of the in vitro metabolic rates implies their similar glycolytic metabolism in the TCA cycle due to comparable production rates of (2) H glutamate/glutamine (glx) for the two precursors, but overall higher glycolytic metabolism from (2) H glucose because of a higher production rate of (2) H lactate. In vivo kinetic studies suggest that HDO can serve as a robust reporter for the consumption of the precursors in liver tumors. As fructose is predominantly metabolized in the liver, deuterated water (HDO) produced from (2) H fructose is probably less contaminated from whole-body metabolism in comparison with glucose. Moreover, in studies of the normal liver, (2) H fructose is readily converted to (2) H glx, enabling the characterization of (2) H fructose kinetics. This overcomes a major limitation of previous (2) H glucose studies in the liver, which were unable to confidently discern metabolic flux due to overlapped signals of (2) H glucose and its metabolic product, (2) H glycogen. This suggests a unique role for (2) H fructose metabolism in HCC and the normal liver, making it a useful approach for assessing liver-related diseases and the progression to oncogenesis.