Muscle Bio Week 2.docx

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Muscle Bio Week 2

***Week 2, Module 2: Exercise Intensity, Duration and Fuel Use***

Energy Systems of the Body

+-------------+-------------+-------------+-------------+-------------+
|   | **Exercise | **Exercise | **Fuel | **Other |
| | Duration** | Example** | Source** | notes:** |
+=============+=============+=============+=============+=============+
| *Phosphagen | 10 seconds | 100m sprint | Creatine | - Max |
| System* | or less | | phosphate | power |
| | | | | output |
| | | | | |
| | | | | - Short |
| | | | | supply |
+-------------+-------------+-------------+-------------+-------------+
| *Anaerobic | 1-2 minutes | - Set of | Glucose/gly | - More |
| Glycolysis* | | squats | cogen | supply |
| | | | | |
| | | - 400m | | - Lasts a |
| | | sprint | | bit |
| | | | | longer |
| | | | | |
| | | | | - Limited |
| | | | | by |
| | | | | lactate |
| | | | | product |
| | | | | ion |
+-------------+-------------+-------------+-------------+-------------+
| *Oxidative | 90 minutes | 10km race | Glucose/gly | - Low |
| Phosphoryla | | | cogen | \'power |
| tion | | | | \' |
| (carbs)* | | | | output |
+-------------+-------------+-------------+-------------+-------------+
| *Oxidative | Unlimited | Long | FFA and | - Not |
| Phosphoryla | | duration, | IMTG | useable |
| tion | | sustained | | for max |
| (lipids)* | | exercise | | power |
| | | | | output. |
+-------------+-------------+-------------+-------------+-------------+

- RBC have no mitochondria, so they rely solely on anaerobic
metabolism

- As exercise duration increases, it becomes are to produce max power
output.

- We cannot maintain max power output for more than a few seconds and
it is impossible to produce max power on fat fuels.

- Athletes will \"hit a wall\" when the body runs out of glycogen for
fuel.

- We only have enough glycogen stored for roughly 90 minutes of
exercise, when done at a high intensity.

- When the body swaps to fat for fuel, this is a slow process, as it
requires oxygen and isn\'t effective for someone doing high
intensity exercise

[Effects of Exercise Intensity and Duration on Fuel Use ]

- Rate of energy produced = rate of energy required

- When exercise occurs, fuel source is selected on what is going to
best match the rate of energy required.

- When the body has to switch to an alternate fuel source, it will
then affect the individuals ability to meet the required intensity.

- Intensity and duration of exercise determines the rate and amount of
energy needed to fuel said exercise

- Fats are more energy efficient and produced more energy per gram but
are slower to be broken down than carbs

- Fat see used during low intensity exercise as the rate of energy
demand is lower. Carbohydrates the preferred fuel source for when
energy is rapidly needed, however they produce less energy per gram.

- Absolute intensity of exercise: power output or speed, relative to
someone fitness level. Determines the total quantity of fuel used

- Relative intensity: power output or speed, relative to someone\'s
weight. Determines the proportions of fuel used.

- At rest and during low intensity exercise, fats give the major
proportion of energy requirements when in this state.

- Fats are energy dense, they can produce 129 ATP molecules from one
molecule of fatty acids compared to the 36 you get from glucose.

- In moderate intensity exercise, 50% of energy is still from fat.
However, at about 65% of VO2max, lipolysis reaches its limits. Past
this, fat use declines and glycogen takes over.

- One we reach a high exercise intensity, we swap to carb sources.
This is due to the need for fast energy and a decline in oxygen.

[Exercise Intensity and Fuel Selection ]

- The ***absolute intensity*** determines the total quantity of fuel
required: e.g., cycling at 500 W requires more fuel than cycling at
250 W

- The ***relative intensity*** determines the fuel mix (i.e., the
proportion of fat and CHO used by the working muscles): e.g.,
cycling at 85% of VO2max requires a greater proportion of CHO than
cycling at 25% of VO2max

*Rest and Low Intensity*

- At rest, ***free fatty acids** (**FFAs**), *which are produced from
the mobilisation and breakdown of triglycerides in adipose tissue
(via a process known as ***lipolysis***), satisfy the majority of
the energy requirements of skeletal muscle.\
At low exercise intensities, a small percentage of the muscle's fuel
comes from CHOs, and this consists almost entirely of plasma
glucose.\
During low-intensity exercise (25 -- 40% of VO2max), as intensity
increases, the rate of FFA mobilisation in plasma matches the rate
of FFA oxidation (in muscle), which means there is an increase in
the utilisation of FFAs.\
This means that fats continue as the main energy source (\~55% of
total energy expenditure) at low exercise intensities.

*Moderate Intensity*

- During moderate-intensity exercise, more than 50% of total energy is
derived from FFA oxidation.\
With an increase from 40% to 65% of VO2max, total fat oxidation
reaches its peak, despite a slight decline in plasma FFA oxidation.
This is because of an increase in the oxidation of fats stored
within the muscle, known as **intramuscular triglycerides (IMTGs)**.

- Once intensity reaches 65% of VO2max, there is very little, if any,
further increase in lipolysis as the increasing blood glucose
inhibits lipase activity (the enzymes involved in breaking down
triglycerides), which inhibits lipolysis.\
Once intensity rises past 65% of VO2max, muscle glycogen usage
increases significantly, while both IMTG and plasma FFA use
decreases. Simultaneously, lipolysis is suppressed, and the
contribution of FFA oxidation to total energy requirement of
exercise further declines.

*High Intensity Exercise*

- When exercise intensity reaches 85% of VO2max, there is a further
decline in total FFA oxidation compared to moderate-intensity
exercise. This is due to the insufficient blood flow from adipose
tissue to the blood stream, which reduces the concentration of FFAs
in blood plasma and reduces overall fat oxidation.

- Additionally, CHOs can supply ATP to working muscles faster than
fat, which is why CHO is the preferential fuel during high-intensity
exercise.** **During intense exercise, CHO fuels predominate, with
muscle glycogen and glucose utilisation increasing exponentially
with increases in relative exercise intensity.

- Muscle glycogen therefore becomes the most important fuel source for
high-intensity exercise (65 -- 110% of VO2max

*[Exercise duration and fuel]*

*Low intensity exercise*

- During prolonged exercise performed at low exercise intensities,
fuel selection does not change considerably as exercise progresses,
even if the exercise persists for 1-2 hours.

- This is because energy needs of muscle can be met exclusively from
the oxidation of the fats (FFA mobilised from triglyceride stores in
adipose tissue), which is an almost unlimited source of energy in
the human body

*Moderate high intensity exercise*

- Conversely, during prolonged exercise performed at moderate-high
intensities, as exercise duration progresses, the rate of CHO
oxidation declines, while lipolysis and fat oxidation increases.

- The body can only maintain high-intensity exercise for a certain
amount of time (\~90 min at \~85% VO2max). Eventually, plasma
glucose levels decline due to the inability of glucose output from
the liver to meet the needs of skeletal muscle.

- As glycogen stores become depleted with prolonged exercise, fat once
again becomes the main energy source for skeletal muscle and
exercise intensity must decrease to a level constrained by the
body's ability to mobilise and oxidise fat.

[Fuel Depletion and Fatigue ]

CHO (glycogen) stores in the body are limited, and are often
substantially less than the requirements of training sessions and
competitions/matches undertaken by many athletes.

The ***depletion of muscle and liver glycogen*** also often ***coincides
with fatigue*** and reduced performance during endurance events and many
team sports.

Prolonged endurance exercise leads to muscle glycogen depletion, which
is in turn linked to fatigue and reduced performance, making it
difficult to meet the energetic requirements of training and
competition.

Because our CHO stores are limited, and depletion of these stores
reduces exercise performance, any nutritional strategy that conserves
endogenous CHO stores (and therefore promotes increase fat oxidation)
can potentially improve exercise capacity.

In fact, one of the adaptations to endurance (aerobic) training is an
improved ability to use fat as a fuel, which \'spares\' the limited CHO
stores for use later in exercise, thereby improving endurance

[Measuring Fuel Utilisation ]

We use the oxygen in the air that we breathe to "oxidise" the
macronutrients carbohydrate and lipids. Our cells then use the energy
released from these oxidation reactions to recycle ATP to maintain their
energy charge, one of the by-products of course is carbon dioxide which
we exhale. We can use gas analysis equipment to measure how much carbon
dioxide someone is producing and how much oxygen they are using. The
respiratory exchange ratio is the ratio of carbon dioxide produced to
oxygen consumed.

                                         RER = CO2 produced :
O2 consumed

When measured in the rested state on a general "western" diet RER is
usually around 0.8-0.85. A person's RER gives us an indication as to the
proportion of fat and carbohydrate that their body is burning to power
their activities.

How is it that RER can give us this insight into our metabolism? We know
that to aerobically burn carbohydrate we will produce 1 molecule of
carbon dioxide for every oxygen used to burn that carbohydrate. Hence
the respiratory exchange ratio for subsisting entirely on carbohydrate
will be 1. This is highlighted in the equation below:

However, to burn fat we need more oxygen to release all the carbon from
the fatty acids (remember that fatty acids must be beta-oxidised before
being oxidised in the mitochondria, this is because they contain less
oxygen than carbohydrate). As a result the RER for fat is less than 1 in
fact the RER for subsisting entirely on lipid sources is 0.7 (remember
that ratios don't have units). This is highlighted in the equation below
for the oxidation of palmitic acid:

CH3(CH2)14COOH + 23O2 = 16CO2 + 16H2O (RER for palmitic acid = 16:23 or
0.7)

So if we had someone in a rested, **fasted** state and we measured their
RER by assessing the composition of their exhaled air we would expect
their RER to be close to 0.7 which would indicate that their body is
predominantly utilising lipid as a fuel. However, if we had that person
undergo an incremental exercise test we would see their RER shift closer
to 1 as their metabolism shifted to become more reliant on carbohydrate
to fuel their activity. By the time they reached their VO2max their RER
would be at least 1.

We can thus utilise the RER measured in an individual's exhaled air to
estimate the proportion of fuel that they are burning to power the
activity.