There will be numerous important applications to record physiological signals during strenuous exercise. Many researchers aim for that but it’s still difficult to exclude exercise-induced interference. Long-term exercise will regulate cardiac autonomic system and other physiological signals, reduce blood pressure and retard aging. Further, it will affect cerebral function after interrupting autonomic system activity. This discourse successfully established animal model of recording electroencephalogram and electrocardiogram during exercise. The developed technique will offer a way to study the interaction of cerebral cortex and heart during exercise in rats. Purpose: With continuous recording and analyzing the system of rats, we could explore the interaction of brain and cardiac autonomic system during exercise; also, we could attempt to observe distinction of hypertension and aging. Methods: All experiments were carried out on 8 and 60 weeks Wistar-Kyoto and spontaneously hypertension rats. After seven days from the electrodes and electrocardiogram were implanted, continuous electroencephalogram (EEG) and electrocardiogram (ECG) were recorded during treadmill exercise in rats. Effects of the exercise on the physiological parameters were assessed using two-way analysis of variance (ANOVA) and t-test with repeated measures. When indicated by a significant F statistic, regional differences were isolated using post hoc comparisons by the Fisher’s least-significant difference test. Statistical significance was assumed for p < 0.05. Values are expressed as means ? SEM. Results: Compared with each groups, treadmill exercise resulted significant difference in mean power frequency (F=22.412), alpha (F=113.260), beta (F=34.732), delta (F=23.049) and theta power (F=22.521) of the EEG, and R-R interval (F=45.721), HF (F=56.503), LF (F=139.613) and LF/HF (F=56.500) of EEG. Such changes quickly reversed when the treadmill exercise was stopped. Conclusion: Rats were more attention and alertness and lower sleepiness and cardiac autonomic function during exercise. At beginning of exercise, the increase of cortical activity was faster than heart response. Autonomic function of elderly rat declined appreciably during exercise. There was outstanding expression of theta power during exercise in hypertension rats. After further attestation it may be the predictor of affecting hypertension.