Imaging of glucose metabolism by 13C-MRI distinguishes pancreatic cancer subtypes in mice.
Shun KishimotoJeffrey R BrenderDaniel R CrooksShingo MatsumotoTomohiro SekiNobu OshimaHellmut MerklePenghui LinGalen ReedAlbert P ChenJan Henrik Ardenkjaer-LarsenJeeva MunasingheKeita SaitoKazutoshi YamamotoPeter L ChoykeJames MitchellAndrew N LaneTeresa Wm FanW Marston LinehanMurali C KrishnaPublished in: eLife (2019)
Metabolic differences among and within tumors can be an important determinant in cancer treatment outcome. However, methods for determining these differences non-invasively in vivo is lacking. Using pancreatic ductal adenocarcinoma as a model, we demonstrate that tumor xenografts with a similar genetic background can be distinguished by their differing rates of the metabolism of 13C labeled glucose tracers, which can be imaged without hyperpolarization by using newly developed techniques for noise suppression. Using this method, cancer subtypes that appeared to have similar metabolic profiles based on steady state metabolic measurement can be distinguished from each other. The metabolic maps from 13C-glucose imaging localized lactate production and overall glucose metabolism to different regions of some tumors. Such tumor heterogeneity would not be not detectable in FDG-PET.
Keyphrases
- papillary thyroid
- high resolution
- pet imaging
- squamous cell
- magnetic resonance imaging
- computed tomography
- adipose tissue
- blood glucose
- squamous cell carcinoma
- air pollution
- gene expression
- genome wide
- metabolic syndrome
- contrast enhanced
- dna methylation
- mass spectrometry
- photodynamic therapy
- high fat diet induced
- diffusion weighted imaging
- weight loss
- wild type