Background: Cognitive flexibility plays a critical role in daily life, both acute aerobic (AE) and resistance exercise (RE) have been recognized as effective ways to increase cognitive flexibility and brain-related P3 amplitudes. Given that the American College of Sports Medicine recommends the many benefits of both AE and RE, and both are necessary to participate, investigating the effects of acute concurrent exercise (CE; defined as combining both aerobic and resistance exercise) on cognitive flexibility and P3 amplitude becomes an issue worth to be explored. In addition, exercise-induced lactate may be associated with the improvement of cognitive performance. However, no study examined the mediating effect of lactate between acute exercise and cognitive flexibility. Therefore, the purpose of this study was to investigate the effects of acute CE on cognitive flexibility, P3 amplitudes, and lactate, compared with AE. Additionally, the mediation of lactate between acute exercise and both cognitive flexibility and P3 amplitudes has also been examined. Methods: 78 young adults (mean age 22.82 ± 1.80 years) were recruited and randomly assigned to CE, AE, and reading control (RC) groups. Group CE finished 12-minutes of AE and about 13-minutes of RE at moderate intensity. Group AE finished 25-minutes of moderate AE. Both exercise groups were asked to warm up for 5-minutes before exercise and cool down for 5-minutes after exercise. Group RC finished 35 minutes of magazine reading. Cognitive flexibility and P3 amplitudes were measured before and after intervention in each group, and lactate was measured before, during, and after an intervention. Results: Compared with the group RC, the response time of both group CE and AE were significantly shorter in all cognitive flexibility conditions. There was no significant difference in the accuracy among groups. Compared with group RC, P3 amplitudes of group CE were higher in the heterogeneous condition, and P3 amplitudes of group AE were significantly higher in the switch condition. Lactate of group CE was significantly larger than group AE and RC. Group AE significantly released larger lactate than group RC. The indirect effects of lactate were significant between groups and cognitive flexibility in both heterogeneous and switch conditions, but not in the homogeneous and non-switch conditions. The indirect effects of lactate between groups and P3 amplitudes were not significant in all cognitive flexibility conditions. Conclusion: The present study expands the existing literature by demonstrating that acute CE has a positive effect on cognitive flexibility, and the benefit is similar to acute AE. Both acute CE and AE can recruit and distribute more attentional resources into higher cognitive-demand conditions. Lactate plays a mediating role between acute exercise and cognitive flexibility, and the mediating effect of acute CE is higher than acute AE which may cause by a higher lactate concentration of acute CE. The mediator between acute exercise and P3 amplitudes needs to be further clarified.