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Testing someone’s VO2max allows you to measure how much oxygen they burn at any given heart rate during exercise, giving them the most precise estimation of caloric burn during their workout. This is proven by the Fick equation. Which is the calculation of oxygen consumption. By testing it ones VO2max they will be able to monitor the success of their current training program. Given a case study in EXSC 510 in regards to Jordan Smith and why the exercise physiology lab discovered his VO2max was 45ml/kg/min leaves one to believe he is an average middle aged guy (assumed) who is somewhat active. I will start out by explaining how he got to his current exercise tolerance. Then explain how the test could vary if the test was conducted at altitude and Jordan lives at sea-level.
There are many things that are taken into consideration when testing ones VO2max. First, gender is a huge variable. It’s been proven that a males VO2max is typically 40-60% higher than women (Howley & Powers, 2018). The difference being, the variance in bodyweight and lean body mass. Therefore research shows that the average untrained male has a VO2max of about 45ml/kg/min. Secondly, training in different temperatures changes the results. High temperatures lead to two complications, hypothermia and dehydration. Increased body temperature leads to reduced muscle strength, which means the muscle’s capability to contract continually over long periods of time (Howley ; Powers, 2018). High body temperature results a decrease in blood movement to the heart as blood gathers in the extremities. Oxygenated blood can’t get back to the muscles if the heart isn’t getting as much blood. Dehydration causes a reduction in VO2max. In layman’s terms means that the body can’t use oxygen as proficiently to provide energy.
When bringing Jordan back into the equation and seeing his VO2max results are 45ml/kg/min this would make me believe that either he is just an average guy who doesn’t workout much or that he lives at sea-level and his VO2max was tested at a higher elevation.
The atmospheric pressure and air temperature also increase with altitude. A good example is if you take a trained runner at sea level that is currently untrained, it’s much harder for them to get back the aerobic power they used to have. Therefore reduced oxygen, is the result of cardiac output at elevation. The lower atmospheric pressure causes the alveolar pressure to be less. Which, reduces the pressure incline for oxygen dispersion between the alveolus and pulmonary capillary blood. In turn reducing the atmospheric pressure. Also, it means that VO2max decreases faster at higher altitudes because of the desaturation of hemoglobin and cardiac output. This affects the cardiovascular responses since the blood is carrying less oxygen per minute to keep up. If we base Jordan’s VO2max on the fact that it was tested at a much higher altitude we can assume that he is much more active than stated previously. Therefore if he regularly does exercise he will have to reduce the intensity at altitude.
Even though it seems that strength and the ability to perform brief, powerful activities are not particularly affected by altitude, long-standing aerobic exertion is hindered at higher altitudes. Consequently, powerful efficient training engaged in at higher altitudes must be trained for and will take time. VO2max can definitely be applied as a training tool when someone is wanting to perform at a much higher rate at sea-level. Hence, why a lot of runners train at higher elevations. It can help a competitor increase that highly desirable competitive lead!

Powers, S.K., Howley, T.K. (2018). Exercise Physiology: Theory and Application to Fitness and Performance. New York, New York: McGraw Hill Education.

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