Fats

Question 1

Types of fat & function of fat

Answer 1

Simple

• Triglycerides (most abundant
  
  • Has glycerol back bone & methyl group

Compound

• Phospholipids
• Lipoproteins

Derived lipids

• Made up of both simple and compounds
  
  • Cholesterols

Saturated

• Single bond
• Solid at room temperature

Unsaturated

• Double bond ( H on same side)
• Liquid at room temperature

Trans fat

• Not essential
• Double bond (H on opposite side)

Function of fat

• Energy provision
• Fat oxidation in aerobic metabolism

Question 2

Fat vs CHO

Answer 2

• Fat stores are very large compared to CHO stores

- Fat contains about 50x more energy than CHO

Question 3

Fat consumption in western societies

Answer 3

• Important to identify the type of fat

- Saturated fat levels below 10% of total energy intake

Question 4

Fat sources

Answer 4

• Adipose tissue

- Muscle - intramuscular triglycerides

Question 5

How do we get ATP from fat?

Answer 5

Fat Oxidation

1. Lipolysis 
2. Removal of FAs from adipose tissue 
3. Transport of fat into the blood stream 
4. Transport of FAs into the muscle 
5. Transport of FAs into the mitochondria 
6. Oxidation of FAs in beta-oxidation and TCA cycle

Question 6

What happens before oxidation can occur

Answer 6

Mobilised - triglycerides are split into glycerol and fatty acids so that FAs can be transported
Oxidation - then transported into the mitochondria

Question 7

What is lipolysis

Answer 7

• The breakdown of triglycerides to fatty acids and glycerol

- For each triglycerides there are 3 fatty acids

Question 8

What is the hormone sensitive lipase and what other hormones affect it

Answer 8

Responsible for splitting triglycerides into fatty acids and glycerol

HSL

• Epinephrine: Activates HSL and stimulates breakdown of triglycerides
• Insulin: Down regulates HSL and slows triglyceride breakdown

Question 9

What happens to the fatty acid after triglyceride has been broken down

• Rest
• Exercise

Answer 9

During rest

• 70% of of the fatty acids stay in the adipose tissue
• Undergo Reesterification - reform triglycerides

During Exercise 
- Increased lipolysis 
- Increased catecholamine- epinephrine 
- Increased fatty acid availability 
Transported into the blood to be used by other tissues

Question 10

What happens to the glycerol

Answer 10

• Glycerol is released from lipolysis into the blood stream to the liver (gluconeogenesis)
• Gluconeogenic substrate to form new glucose

Question 11

What happens to the fatty acids after lipolysis & explain fat oxidation

Answer 11

Fatty acids need to be removed and transported into the blood

1. The removal of fatty acids from adipose tissue required the transporter protein albumin. Fatty acid transport from adipocyte is dependent on:
   - The amount of albumin in the blood
   The available binding sites on the albumin protein itself
   - As well as blood flow to the adipose tissue
2. Transport of fatty acids into muscle cells
   - Intramuscular triglycerides
3. Transport of fatty acids into the mitochondria
   - Transported into the mitochondria by the compound carnitine and eventually ends up as fatty acyl CoA
4. Beta-oxidation
   - Series of reactions resulting in Acetyl CoA
5. TCA cycle
   - Series of reactions occurring in the mitochondria that result in energy provision
6. Electron transport chain
   - A process involving the transfer of electrons that drives the synthesis of ATP

Question 12

What are the limitations of fatty acids being used in the muscle cell.

Answer 12

• Lipolysis
• Removal of FAs from adipose tissue (requires enough blood flow)
• Transport of fat into the blood stream (need transporter protein to be at the cell membrane to help fatty acids into the muscle)
• Transport of FAs into the muscle
• Transport of FAs into the mitochondria (complex process)
• Oxidation of FAs in beta-oxidation and TCA cycle

Question 13

Fat oxidation in exercise

- Fat and CHO oxidation

Answer 13

CHO and fat oxidized (broken down) as a mixture relative contribution of either substrate dictated by a number of factors:

• Exercise intensity
• Exercise duration
• Diet
• Aerobic fitness levels
• CHO intake prior to exercise

Substrate use

• Relative proportion of each substrate - CHO & fat
• Expired gas fractions of oxygen and CO2 along with air volume to indirectly determine VO2 and VCO2 and ultimately energy expenditure
• RQ = 0.7 (predominantly fat oxidation)
• RQ = 1.0 (predominantly CHO oxidation)

Exercise duration
- Fat oxidation increases as exercise duration increases due to the reduction in muscle glycogen

Question 14

Fat oxidation and exercise intensity

• Maximal rate of fat oxidation
• High intensities
• Why do fat oxidation rate drop during high intensity exercise

Answer 14

• Low intensity exercise: Fat oxidation predominate fuel source
• From LOW to MODERATE intensity exercise fat oxidation levels increase
• Around 60% exercise intensity there is a gradual decrease in fat oxidation
• Around 75% exercise intensity there is a dramatic decrease in fat oxidation

Maximal rate of fat oxidation
- 65% VO2 max

High intensities

• Fat oxidation is inhibited and the contribution of fat is negligible
• Low fat oxidation BUT lipolysis rate are still high

Why do fat oxidation rate drop during high intensity?
- Reduction in blood flow to adipose tissue = Decreased removal of FA from adipose tissue
- Lactate accumulation which ↑ Reesterification rates
exercise

Low plasma fatty acids level during high intensity exercise
- Only partially explains the low fat oxidation rate

Question 15

Endurance Training Adaptation

• fat oxidation and aerobic capacity during endurance training influences
• BENEFITS of improved FA use?

Answer 15

Fat oxidation and aerobic capacity 
Endurance training influences 
- Substrate availability 
    * Greater use of fat 
        \+ Sparing glycogen stores 
    * Greater contribution of fat to overall energy expenditure 
- Exercise capacity 

Endurance training adaptations

• Increased mitochondria
• Increased capillary density
• Increased transporter ability

What are some of the BENEFITS of improved FA use?

• Exercise capacity increases
• Muscle glycogen sparing
• Blood glucose sparing
• When using fat, less lactate produced

Question 16

CHO and fat oxidation

- CHO 1 hr prior to exercise

Answer 16

Fatty acid oxidation is directly regulated by carbohydrate metabolism during exercise

CHO 1 hr prior to exercise - Increases insulin - reduction of fatty acid availabiliy (reduces lipolysis) - 30% less fat oxidation when compared to no CHO feeding

• Reduced lipolysis
• Reduced plasma fatty acid availability
• inhibitory effect on carnitine dependent fatty acid transport into mitochondria

Question 17

Fat intake

• Fasting
• Short term high-fat diet
• Long term high-fat diet

Answer 17

Fasting

• Increases availability of lipids = increased oxidation
• Liver and muscle glycogen stores suffer - reduced performance and fatigue resistance

Short term high-fat diet
- 3-5 days
Increased availability of lipids - Reduced glycogen stores - reduced performance and fatigue resistance

Long term high-fat diet

• Increased fat oxidation?
  
  • Don’t have enough evidence
• Effect on performance?
  
  • Unclear

Question 18

Fat intake recommendations

Answer 18

1. Performance & Health
2. Requires an accurate dietary assessment!!!
3. 20 to 35% of energy intake
   - <10% of exergy from saturated fats
   - Remaining from mono-and polyunsaturated
4. Modify & tailor to individual
   - Health risk profiles
   - Blood lipid profiles
   - Hypertension