Recovery.

Slides:

Advertisements

Similar presentations

Cardiovascular and Respiratory Systems Working Together

Advertisements

THE RECOVERY PROCESS.

The Recovery Process Excess Post Exercise Oxygen Consumption(EPOC): This is the excess oxygen consumed following exercise which is needed to replace ATP.

© RockyMountain HPC, Inc..  The energy systems rarely work in isolation  The body supplies energy continuously (hence ‘continuum’) as long as activity.

Aerobic Energy Systems

Energy systems.

A. Oxygen Deficit and EPOC Oxygen Deficit - The difference between the oxygen required during exercise and the oxygen supplied and utilized. Occurs at.

Exercise Metabolism.

September 2011 Training Effects – linked with Aerobic System At the end of this section, you should be able to: Define and explain the term Oxygen Deficit.

SAC 2 & 3 PREPARATION Interplay of energy systems Use of data to explain the relationships of E/S’s Fatigue mechanisms Recovery methods.

FATIGUE AND RECOVERY MECHANISMS. FATIGUE  Exercise induced reduction in the power-generating capacity of a muscle and an inability to continue activity.

Fatigue and Recovery. Fatigue Is the inability to continue with an activity at the same intensity, despite the desire to maintain intensity. Fatigue can.

THE RECOVERY PROCESS. The recovery process Imagine you have just run a marathon Write down what factors will influence how quickly the body can return.

Recovery Process.

PROF ASHRAF HUSAIN RESPIRATORY CHANGES DURING EXERCISE.

Energy systems Learning outcomes: All are able to demonstrate understanding of the relationship between OBLA and VO 2 max Most are able to explain the.

Anaerobic Energy Systems By: Stacey Perkins, Catherine Gordon, Kaitlyn Souter, Ben O’Brien.

Overview of Bioenergetics Lesson Interaction of the Energy Systems Interaction of the Energy Systems How Energy Systems work together How Energy Systems.

FATIGUE AND RECOVERY. FATIGUE Responses to exercise are individual. Causes of fatigue depend upon: The type, duration and intensity of exercise – aerobic.

Copyright © 2006 Lippincott Williams & Wilkins. Human Energy Transfer During Exercise Chapter 6.

Energy Systems for Exercise Energy Sources From Food: – CHO = 4 kcal – Fat = 9 kcal – Protein = 4 kcal For Exercise: ATP  ADP + P + energy (for muscle.

Section A: Exercise and Sport Physiology 5. The recovery process.

Energy Systems. Muscles require energy to work The energy required by muscles comes from a chemical compound called adenosine triophosphate (ATP) ATP.

The recovery process involves returning the body to its pre-exercise state! Complete Practical Task 8 pg 382/3 Record results Answerer questions 1-6.

Aerobic & Anaerobic Metabolism in Muscles. Objectives Recognize the importance of ATP as energy source in skeletal muscle. Understand how skeletal muscles.

Fatigue and Recovery. Defining fatigue How would you describe fatigue? “ A reduction in muscular performance or a failure to maintain expected power output”

WHAT IS ATP ? Carbohydrates, Fats and Protein – contain energy, however we can’t use it directly. These nutrients are used to form a chemical compound.

EDU2EXP Exercise & Performance 1 Energy Systems. EDU2EXP Exercise & Performance 2 Energy systems These are the three energy systems. 1. ATP-PC Energy.

Energy Systems Storage of Food Fuels in the Body.

KEY KNOWLEDGEKEY SKILLS  The characteristics of the two anaerobic (without oxygen) and aerobic (with oxygen) energy pathways.  The energy pathways used.

Edexcel Examinations A Level Physical Education A 9536

Muscle Fatigue Causes and Reduction.

Fatigue and recovery Processes FATIGUE AND RECOVERY PROCESSES  FATIGUE – Inability to maintain power output!  What are the feelings of fatigue?  Is.

AFTER COMPETITION RECOVERY

Oxygen Consumption and Excess Postexercise Oxygen Consumption Andrew Nasr Meyer Naidas Aaron Salazar Kevin Shreffler.

VCE PE Exam Preparation 2.

Relationship Between Power Input and Output. Aerobic and Output Power in Organisms that Depend on Blood to Deliver Oxygen.

Comparing the three energy systems 1) ATP-PC within the body's muscle mass there are between millimoles of ATP and PC. Which provide 15 – 20 kilojoules.

Chapter 4 Exercise Metabolism

Copyright © 2007 Lippincott Williams & Wilkins.McArdle, Katch, and Katch: Exercise Physiology: Energy, Nutrition, and Human Performance, Sixth Edition.

RECOVERY PROCESS. During muscular exercise, blood vessels in muscles dilate and blood flow is increased in order to increase the available oxygen supply.

Section A: Exercise and Sport Physiology 3. ATP resynthesis.

ENERGY SYSTEM INTERPLAY. Aerobic Provides energy for long duration events. Uses oxygen and glycogen. Efficient producer of energy.

 You are going to take notes on the following principles of training.  YOU will decide what is important and what is not.

Energy systems. Research task ●In groups of 3 you are to each research the 3 different energy systems ○Group member 1 is to research Anaerobic glycolysis.

Aerobic energy system. Specification Aerobic energy system – simplified biochemistry in the breakdown, release and regeneration of ATP in glycolosis,

Recovery Following Exercise

Exercise and the Body.

Chapter 4 Exercise Metabolism

Chapter 4: Exercise Metabolism

Energy systems Learning outcomes:

Fatigue and Recovery Unit 3 AOS 2.

Energy systems Learning outcomes:

PHED 3 Exercise Physiology Aerobic Energy System

Physiology Unit Structure

Chapter 13 BIOL 1400 Dr. Mohamad H. Termos

What is ATP? ATP is a chemical compound responsible for producing energy for work, which is provided by our diet. When ATP is broken down, energy is released.

Factors Affecting Performance

Fatigue and the Recovery Process

Energy Systems Exam Questions

Hover over a hexagon for more information

INTERVAL TRAINING.

Chapter 4: Acute Responses & o2 Uptake, Deficit & debt

Fueling physical activity and fatigue

Describe the differences between mRNA and tRNA

Oxygen Uptake Oxygen Debt Oxygen Deficit

Training the Energy Systems

Cardiovascular and Respiratory Systems Working Together

PHED 3 Exercise Physiology EPOC

Presentation transcript:

Recovery

Recovery PC stores deplete quickly in around 8 seconds. Pc stores replenished – 50% in 30 seconds and 100% after 3 minutes. Oxygen stored in myoglobin depleted after bouts of exhaustive exercise, but can be fully relinked within 3 minutes of rest or low intensity exercise.

After exercise Myoglobin lost stores of oxygen ATP, PC and glycogen stores may be depleted Lactic acid levels may be high. Potential exhaustion.

EPOC To return the body to pre-exercise state, energy is required. Continued aerobic production gives additional energy requirement. This is called EPOC – also known as oxygen debt and is the volume of oxygen required to return the body to post-exercise state. Oxygen consumption can be plotted against time to show the oxygen deficit – the amount of oxygen required to complete an activity entirely aerobically.

EPOC EPOC is always present, regardless of intensity of exercise. The size of oxygen deficit and EPOC may differ depending on the activity duration and intensity. During low-intensity aerobic activities there is a small oxygen deficit. During high-intensity anaerobic activities there is a large oxygen deficit.

2 stages of EPOC Fast component of recovery Slow component of recovery

Fast alactacid component Accounts for around 10% of EPOC. Volume of oxygen required to return the body to a pre-exercise state. Approx. 1-4 litres Replenishment of blood and muscle oxygen Resynthesises ATP and PC stores Done within 3 minutes.

Slow lactacid component After fast component, body enters the slow component. Oxygen required to complete the more complex and time-consuming jobs. Approx. 5-8 litres. Provision of energy to maintain ventilation, circulation and body temperature. Removal of lactic acid and replenishment of glycogen.

Implications of recovery on training Warm up Active recovery Cooling aids Intensity of training Work: relief ratios Strategies & tactics Nutrition