This proposal focuses on the development and validation of glutamine-derived 11C isotopomers for positron emission tomography. Specifically, the 1- and 5-positions of exogenously administered glutamine have different metabolic fates, depending on the dominant mechanisms of conversion present. We will therefore synthesize both L-[1-11C]glutamine ([1-11C]gln) and L-[5-11C]glutamine ([5-11C]gln), and investigate their use in detecting the isocitrate dehydrogenase mutation (IDHm), seen in several benign and malignant clinical diseases including low-grade glioma (LGG). Improved diagnosis of LGG would address a major challenge that neuro-radiologists, neuro-oncologists, radiation oncologists and neuro-surgeons encounter frequently, namely differentiating glial tumor from other brain entities. Patients with IDH-mutant (IDHm) glioma harbor the oncometabolite 2-hydroxyglutarate (2HG), which represents a promising way to detect LGG. We are motivated by a recent report establishing rapid conversion of exogenous glutamine to 2HG in IDHm lesions, representing a way to sequester the 11C radionuclide. The central hypothesis of this proposal is that a positron- labelled metabolic precursor of 2HG, [1-11C]gln, can be used to detect IDHm. We further predict significant advantages in using [1-11C]gln versus the reported [5-11C]gln isotopomer, based on the suppression of background signals related to tricarboxylic acid (TCA) cycle metabolism. When validated, this approach would set the stage for clinical use of [1-11C]gln PET in evaluating LGG and other IDHm lesions. We propose a multi-PI and interdisciplinary collaboration to validate [1-11C]gln PET as an IDHm-specific tool and perform the first patient studies using [1-11C]gln to further support the methodology. We will first develop the first radiosynthesis of [1-11C]gln, via adaptation of reported methods using [11C]CO2 and [11C]CN-. We will then compare the accumulation of [1-11C]gln to that of [5-11C]gln in IDHm versus IDH-wildtype (IDHwt) cells, both in vitro and in vivo (Specific Aim 1). In Specific Aim 2, all regulatory work and site approvals needed to study [1-11C]gln at UCSF will be accomplished. In Specific Aim 3, we will translate [1-11C]gln under the Radioactive Drug Research Committee (RDRC) program and study its performance in patients suffering from LGG. While this application focuses on LGG, a clinically translatable IDHm-specific tracer would revolutionize the workup and management of a large variety of clinically relevant lesions. Furthermore, robust methods to synthesize and evaluate amino-acid derived 11C isotopomers will dramatically improve the ability of PET to detect metabolic reprogramming in human disease.