Purpose/Objective(s) Radiation therapy is commonly used for treatment of patients with intrathoracic malignancies, such as lung cancer, esophageal cancer, and lymphoma. Radiation-Induced Heart Disease (RIHD) is a major source of morbidity and mortality in patients receiving thoracic radiation. Therefore, there is an acute need for development of non-invasive approaches for detection of RIHD at a stage that offers potential for early intervention and reversibility. Cardiac mitochondrial dysfunction is a hallmark of radiation-induced cardiac injury. During aerobic respiration, pyruvate enters the tricarboxylic acid cycle and is metabolized into bicarbonate in mitochondria. We hypothesized that radiation-induced mitochondrial dysfunction results in decreased conversion of pyruvate to bicarbonate in the mitochondria and increased conversion to lactate in cytosol. We sought to non-invasively assess radiation-induced changes in mitochondrial myocardial metabolism by tracking the fate of hyperpolarized (HP) C-13 pyruvate utilization using Magnetic Resonance Spectroscopy (MRS). Materials/Methods Sprague-Dawley rats (n = 10) underwent baseline echocardiography and HP C-13 pyruvate MRS. Rats in the cardiac radiation group (n = 5) underwent image-guided cardiac radiation with cone-beam CT, to a total dose of 40 Gy in 5 fractions. All rats underwent repeat echocardiography and hyperpolarized C-13 pyruvate MRS one week later. Results For the first time, we have demonstrated feasibility of employing HP C-13 pyruvate MRS for detecting radiation-induced myocardial mitochondrial metabolic changes in a pre-clinical rat model. In the cardiac radiation group, C-13 pyruvate MRS demonstrated a statistically significant decrease in cardiac bicarbonate-to-lactate ratio compared to pre-radiation baseline (P = 0.02, one-tailed paired t-test), suggesting increased metabolism of pyruvate into lactate in the cytoplasm (at the expense of metabolism into bicarbonate in the mitochondria) due to mitochondrial dysfunction. No significant decrease in this ratio was observed in the non-irradiated, age matched controls (P = 0.90). No significant changes in left ventricular ejection fraction or global longitudinal strain were observed in either the cardiac irradiation or control group of rats at this time point. Conclusion Radiation-induced myocardial mitochondrial dysfunction is an early event and can be detected in vivo by hyperpolarized C-13 pyruvate MRS within 1 week after radiation, and prior to onset of echocardiographic changes. Due to its non-invasive nature, this technology has the potential to serve as a platform for building radiation-focused cardio-oncology programs for early detection and mitigation of radiation-induced cardiac injury in hundreds of thousands of patients receiving thoracic radiation annually.

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