Background: Radiotherapy (RT) is one of common treatments for patients with thoracic cancers. During mediastinal radiation, heart is often included in the irradiation field and all components of the heart are susceptible to radiation-related oxidative stress damage. Exercise preconditioning has been shown to enhance the resistance of heart to radiation-induced myocardial injury. However, whether exercise intervention after irradiation would attenuate radiation-induced cardiotoxicity remains to be determined. The purpose of this study was to investigate the effects of exercise intervention after irradiation on radiation-induced myocardial dysfunction and related mechanisms were also explored in the animal model. Methods: A total of 18 adult male Wistar rats aged 7 to 8 week-old were randomly assigned to control (Ctrl), irradiation (IR), or exercise training after irradiation (IREx) groups (n=6 per group). The rats in IR and IREx received irradiation to the heart region once daily for 5 days with a dose of 5 Gy/day (total dose of 25 Gy). One week after irradiation, the rats in IREx underwent 60 min/day treadmill exercise training 5 days per week for 6 weeks. Cardiac functions were determined by non-invasive transthoracic echocardiogram performed at 4 weeks (time point 1, T1) and 7 weeks (time point 2, T2) post irradiation. Invasive hemodynamic measurements using in vivo pressure-volume analysis were performed after all interventions were completed. The rats were sacrificed immediately after invasive hemodynamic measurements and the hearts were removed en bloc. Oxidative stress was determined by reactive oxygen species (ROS) level. Antioxidant capacity was determined by analyzing mRNA expression levels of CuZnSOD and MnSOD. Myocardial remodeling and fibrosis were examined by analyzing collagen volume fraction (CVF) from Masson’s trichrome staining, and protein expression levels of MMP-2, MMP-9, type I and type III collagen using Western blotting. Results: Echocardiographic data showed that FS (p=0.01 and p=0.02 for T1 and T2, respectively), EF (both p=0.02 for T1 and T2), SV (both p=0.002 for T1 and T2), CO (p=0.01 and p=0.001 for T1 and T2, respectively), and EDV (p=0.05 and p=0.03 for T1 and T2, respectively) were significantly lower at T1 and T2, and IVRT was significantly longer (p<0.001) at T2 in IR group than those of Crtrl group. In IREx group, FS (p=0.02) and EF (p=0.01) were significantly higher, and ESV (p=0.04) was significantly lower at T2 compared to those of IR group. Pressure-volume analysis showed that +dP/dtmax (p=0.001) and -dP/dtmax (p=0.01) were significantly lower, and EDP (p<0.001) was significantly higher in IR group than those of Ctrl group. In IREx group, +dP/dtmax (p<0.001) and -dP/dtmax (p=0.002) were significantly higher, and EDP (p<0.001) was significantly lower than those of IR group. In IR group, the ROS level (p<0.05), CVF (p<0.001), type III collagen protein expression level (p=0.03) were significantly higher than those of Ctrl group, and MMP-2 protein expression level (p=0.04) was significantly lower than those of Ctrl group. IREx group demonstrated significantly lower ROS level (p<0.05) and CVF (p=0.003) compared to those of IR group. Expression levels of CuZnSOD (p=0.03) and MnSOD (p=0.02) were significantly higher in IREx than those of IR group. Conclusions: Exercise training after irradiation could attenuate radiation-induced cardiotoxicity and preserve cardiac function by reducing oxidative stress and improving antioxidant defense capacity of myocardium.