Student Led Discussion

Luz Bueno

29 Oct 202413:46

Summary

TLDRThis review delves into the body’s energy systems, focusing on the phosphagen system, which powers high-intensity activities for up to 10 seconds, and glycolysis, which supports efforts from 10 seconds to 2 minutes. It highlights key biochemical processes, including ATP production and substrate usage. The aerobic system, engaged after 2 minutes, further emphasizes the citric acid cycle and fat oxidation. Practical applications, such as work-to-rest ratios for training, including high-intensity interval training and combination training, are discussed to optimize performance while considering the potential drawbacks for strength and power athletes.

Takeaways

💪 The phosphagen system provides immediate energy for high-intensity efforts lasting up to 10 seconds.
🔬 Key reactions in the phosphagen system involve ATP hydrolysis and the ATP-PC pathway, producing ATP and creatine.
⏳ Substrates in the phosphagen system are depleted within 5 to 30 seconds and can be replenished in 3 to 5 minutes of rest.
⚡ Glycolysis activates from 10 seconds to 2 minutes of exercise, converting blood glucose into ATP and pyruvate.
📉 Glycolysis produces a net gain of 2 ATP after using 2 ATP in the initial steps.
🍬 Glycogenolysis utilizes muscle glycogen for energy, resulting in a higher ATP yield (3 ATP) compared to glycolysis.
🌬️ Aerobic energy systems are engaged after 2 minutes of exercise, utilizing the Krebs cycle and fat oxidation.
🔄 Pyruvate is converted to acetyl-CoA, entering the Krebs cycle to generate NADH, FADH, and ATP.
📊 Different work-to-rest ratios optimize training for specific energy systems, such as 1:12 for the phosphagen system.
🚀 HIIT can enhance both aerobic and anaerobic fitness but may negatively affect strength and power if not balanced correctly.

Q & A

What is the phosphagen system and its primary role in energy production?
-The phosphagen system is an anaerobic energy system used during the first 10 seconds of high-intensity exercise, primarily providing energy through the hydrolysis of ATP and creatine phosphate.
How does ATP hydrolysis occur in the phosphagen system?
-ATP hydrolysis involves the breakdown of one ATP molecule and water, yielding one ATP, one phosphagen, a hydrogen ion, and energy.
What is the role of creatine kinase in the ATP-PC system?
-Creatine kinase catalyzes the reaction where ADP and creatine phosphate convert into ATP and creatine, facilitating rapid ATP regeneration.
What process occurs during glycolysis, and what are its main outputs?
-Glycolysis converts glucose into two pyruvate molecules, producing two NADH and a net gain of two ATP, while consuming two ATP in the initial steps.
What happens to pyruvate at low versus high exercise intensity?
-At low intensity, pyruvate enters the citric acid (Krebs) cycle, while at high intensity, it is converted into lactate, which can be recycled to the liver for glucose production.
How does glycogenolysis differ from glycolysis?
-Glycogenolysis breaks down muscle glycogen into glucose-1-phosphate and requires only one ATP, leading to a net gain of three ATP during subsequent glycolysis.
What is the significance of the citric acid cycle in aerobic energy production?
-The citric acid cycle produces NADH, FADH2, and ATP, which are essential for the electron transport chain, maximizing ATP production during aerobic metabolism.
How do substrates deplete in the phosphagen system during exercise?
-Substrates in the phosphagen system deplete by 50-70% within 5 to 30 seconds of high-intensity exercise and are typically replenished after 3 to 5 minutes of rest.
What are the recommended carbohydrate intake guidelines for recovery after exercise?
-It is recommended to consume 7 to 10 grams of carbohydrates per kilogram of body weight within two hours post-exercise to replenish energy stores.
What are the work-to-rest ratios for targeting different energy systems during interval training?
-For the phosphagen system, a work-to-rest ratio of 1:12 to 1:20 is recommended. Fast glycolysis uses a ratio of 1:3 to 1:5, while the oxidative system utilizes a ratio of 1:3 to 1:4.