Describe the advantage of the Bohr effect during intense exercise - AQA - A-Level Biology - Question 6 - 2020 - Paper 1

Referring to Figure 3, the cyclist reached VT at 10 minutes into the exercise. This is identified by the point where the increase in pO2 breathed out occurs without a corresponding rise in pCO2.

At the time of VT, let's assume pO2 is 12.5 kPa and pCO2 is 7.5 kPa, resulting in a ratio calculated as:

$ext{Ratio} = \frac{pO2}{pCO2} = \frac{12.5}{7.5} \approx 1.67$

Thus, the ratio of pO2 to pCO2 at this moment is approximately 1.675:1.

One physiological change is an increase in breathing rate. As exercise intensity increases, the body requires more oxygen and needs to expel more CO2. An increased breathing rate enhances gas exchange, enabling more efficient removal of CO2 from the bloodstream, thus preventing a significant rise in pCO2 levels during heightened activity.

According to Figure 4, muscle fibres have a limited amount of phosphocreatine available to rapidly regenerate ATP. Once the phosphocreatine stores are depleted, ATP production becomes limited, restricting sustained high-intensity efforts.

Figure 4 indicates that GW1516 promotes the development of slow muscle fibres at rest, which could enhance endurance at the cost of overall muscle power and performance. Such alteration would provide athletes with an unfair advantage, leading to its prohibition in competitive sports to maintain fairness.

Overuse of EPO can lead to an excessively high haematocrit level, making the blood more viscous. This increased viscosity can strain the heart, block coronary arteries, and also lead to clot formation, significantly raising the risk of a heart attack.