The exploration of space will require ever-increasing exposure to microgravity environments. The human response to this exposure has been categorized and mitigated via countermeasures, principally exercise. However, additional constraints to future mission design minimizes the allotted space and modalities for exercise, creating a risk for psychological fatigue, a reduction in motivation, and a suite of other categorical factors that could, taken together, present a risk for reduced adherence to the countermeasures and/or mission performance. Thus, the current study will examine the effects of a virtual reality (VR) intervention on spaceflight-validated exercise protocols using a prototype rowing ergometer designed to operate within the constraints of future long-duration exploration missions (LDEM). The Integrated Resistance and Aerobic Training (dubbed “SPRINT”) protocol will be used in conjunction with a combination flywheel and resistance training device (M-MED) utilized in prior bedrest studies. The SPRINT protocol trades exercise duration for intensity, providing similar benefits to existing countermeasures while reducing time spent on exercise. The M - MED permits resistance training on the muscles most effected by microgravity exposure on the same device used to train cardiovascular function, thus reducing the volume and weight requirements of the exercise countermeasure. It is upon this framework that we will add the VR rowing simulation. VR has shown to be a lightweight, reliable, and enjoyable technology in numerous studies, while exergaming has been shown to improve measures of motivation and adherence. We will create a rowing simulation that can integrate with a rowing ergometer and any exercise protocol, and then implement it on the M-MED with SPRINT. The simulation will feature virtual teammates, virtual competitors, and other gaming mechanisms that encourage a user to maintain a prescribed heart rate intensity in a way that aims to maximize factors a...