Effects of Breathing Training and Nitrate on Exercise at Simulated Altitude

Description

This study is designed to test whether two non-drug interventions-respiratory muscle training (RMT) and dietary nitrate supplementation-can improve exercise performance and tolerance when oxygen levels are lower than normal, such as at moderate altitude.

When people exercise in low-oxygen environments, the body must work harder to deliver enough oxygen to the muscles. This can lead to faster fatigue and reduced endurance. Strengthening the breathing muscles and improving blood vessel function may help the body adapt better to these conditions. This study will explore how RMT and nitrate supplementation, either alone or together, affect breathing, blood flow, and exercise capacity.

Why This Study Is Being Done:

Researchers want to find out whether strengthening the breathing muscles through RMT, and increasing nitric oxide in the body through nitrate (found naturally in beetroot juice), can make it easier to exercise when oxygen is limited. Nitric oxide helps widen blood vessels and improve oxygen delivery to muscles. The goal is to learn if these approaches can help healthy adults perform better in low-oxygen conditions and whether combining them produces a greater benefit than using either one alone.

Who Will Participate:

Healthy, recreationally active adults will take part in this study. Participants will not have any known heart, lung, or metabolic disease. They will be randomly assigned to one of four groups:

Breathing training plus nitrate supplement

Breathing training plus placebo

Sham (fake) breathing training plus nitrate supplement

Sham (fake) breathing training plus placebo

What Participants Will Do:

Each participant will complete testing before and after a 4- to 6-week intervention period. During the intervention:

Participants in the RMT group will use a handheld breathing trainer several times per week to strengthen their breathing muscles.

Participants in the nitrate group will drink a small amount of concentrated beetroot juice daily.

Those in the sham groups will use a very low-resistance breathing device or a placebo drink that looks and tastes the same but contains no nitrate.

Before and after training, participants will perform exercise tests on a stationary bicycle both at normal oxygen levels and at simulated altitude inside a controlled environmental chamber. Testing will measure:

How long participants can exercise before becoming fatigued.

Oxygen use (VO₂), heart rate, breathing, and blood pressure during exercise.

Breathing muscle strength and endurance.

Oxygen levels in the blood and muscles.

Study Goals and Measurements:

Researchers will compare how exercise performance and physiological responses change with each treatment. The main goal is to see whether RMT and nitrate supplementation increase exercise tolerance at simulated altitude. Secondary goals include understanding how these interventions affect breathing patterns, oxygen use efficiency, and cardiovascular function during exercise.

Why This Study Matters:

This research will help scientists and health professionals understand how to improve physical performance and resilience when oxygen is limited. The findings could be useful for:

Pilots, military personnel, and athletes who train or work at altitude.

Patients with conditions that make breathing or exercise difficult, such as heart or lung disease.

Future spaceflight or aerospace medicine applications, where oxygen availability can vary.

Safety and Ethics:

All participants will give written informed consent before joining the study. The study has been reviewed and approved by the Institutional Review Board for the Protection of Human Subjects in Research at Embry-Riddle Aeronautical University. All research procedures will follow the ethical principles outlined in the Declaration of Helsinki.

Expected Impact:

The results will show whether combining breathing training with nitrate supplementation can serve as a simple, non-pharmacological strategy to improve tolerance to low-oxygen environments. This could lead to better performance strategies for athletes, aviators, and others who face hypoxic or high-altitude conditions, as well as inform clinical approaches for patients who struggle with exercise intolerance.