Oxygen-guided Supervised Exercise Therapy (MOMET)

The long-term goal of this research is to improve mobility, functional independence, and quality of life in patients with peripheral artery disease (PAD) by developing conservative interventions. PAD is a manifestation of atherosclerosis, which produces blockages in the leg arteries, and results in insufficient blood flow to the legs. PAD results in significant gait deficits and an overall sedentary lifestyle. The investigators' prior work showed that the biochemical (oxidative stress and mitochondrial dysfunction) and histological (myofiber degeneration and fibrosis) characteristics of PAD muscles are altered compared to controls. These myopathic changes are due to cycles of ischemia and reperfusion, and they correlate to functional limitations (walking distance and calf muscle strength). Limb ischemia from PAD is the most common disorder treated within the vascular surgery service of the Omaha Veterans Affairs Medical Center. The most effective treatment for increasing the distances that patients with PAD can walk is supervised exercise therapy (SET). However, SET uses pain onset to guide exercise intensity and rest cycles. These repeated bouts of ischemia/reperfusion could cause further pathological damage to muscle myofibers and oxidative processes. Such adverse effects of ischemia may explain why not all patients improve with SET. Preventing cycles of ischemia-reperfusion during SET can improve walking performance without further muscle biochemistry damage in patients with PAD. The investigators propose using hemodynamic responses to modulate exercise intensity and prevent ischemia during SET. Muscle oxygen-guided supervised exercise therapy (M-SET) can prevent ischemia onset and thus preserve muscle mass and function during exercise therapy in patients with PAD. The aims are:

Aim 1: To determine the exercise outcomes of an M-SET versus a standard SET session in patients with PAD. Aim 2: To determine the acute effect of M-SET versus standard SET on oxidative stress and inflammation in patients with PAD. Aim 3: To determine the effect of 12 weeks of M-SET versus standard SET on exercise outcomes, muscle biochemistry, and subject-reported preference in patients with PAD.

The investigators will measure exercise outcomes during one session each of M-SET (using StO2 on the calf to modulate exercise) and SET, in 12 patients with PAD using a cross-over design. Exercise outcomes will be assessed by the total distance patients walked during the session, metabolic cost, metabolic equivalents of the task, physical activity enjoyment, and rate of perceived exertion. In Aim 2, oxidative stress will be measured using peripheral blood mononuclear cells before and after each exercise session (SET and M-SET) in all patients. During the standard SET session, subjects will walk until claudication pain becomes severe and the participant needs to stop. Then subjects will rest until claudication pain subsides. Afterward, subjects will walk again, repeating the cycle for up to 50 minutes. M-SET will use an StO2 threshold that is 15% lower level than baseline StO2 levels. Subjects will stop walking once they reach the threshold and rest until StO2 levels return to baseline. Then, subjects will begin walking again, repeating this cycle for 50 total minutes (including walking and rest). Patients from Aims 1 and 2 will be randomly assigned to either a 12-week M-SET or standard SET (6 per group) program. Training will be performed three times weekly as described above. Subjects will be evaluated before and after the intervention to capture initial and absolute walking distances and 7-day physical activity. Muscle biochemistry will be quantified using mitochondrial function, mitochondrial oxidative dynamics, and reactive oxygen species production before and after training. Results will support a full clinical trial and rehabilitation recommendations.