A2. Environmental factors and physical performance Flashcards

1
Q

Conduction

A

The heat (moving energy) that has traveled from the core is transferred from the blood, to the body tissue and skin

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2
Q

Radiation

A

The transfer of energy waves that are sent out from one object and absorbed by another.

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3
Q

convection

A

Heat is moved from one place to another through the movement of air (or water)

–> Warm particles rise up and cool particles rise down (fill the rest)

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4
Q

evaporation

A

Evaporation is the conversion of sweat to water vapor (Liquid to Gas). As this process happens, heat is transferred from the body to the environment

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5
Q

The cycle between ATP and ADP

A

When ATP is combined with water, it loses its phosphate.

This causes large amounts of energy to be released and ATP becomes ADP.

ATP can be remade in the opposite way, by adding a phosphate molecule back to the ADP. Energy is required for this as well.

–> Basically, repeating the cycle with adding phosphate and removing phosphate from ADP and ATP.

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6
Q

The relationship between cellular metabolism and the production of heat in the human body.

A

The energy released when glucose reacts with oxygen is used in order to produce ATP. However, only a fraction of the released energy goes into the high-energy bonds of ATP. Some energy is lost as heat.

We then break down that ATP and use the energy to fuel muscle contraction. However, this is very inefficient since we use only about 20% of the energy for muscular contraction.

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7
Q

The normal core body temperature at rest

A

The normal physiological range for core body temperature is approximate 36°C to 38°C

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8
Q

The relation between body heat loss with respect to surfaces exposed to the low and high humidity environment.

A
  • As humidity increases, no more water can evaporate. In hot conditions, sweat evaporates slower (causing the body to overheat).
  • In low humidity, sweat evaporates quickly which may cause dehydration.
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9
Q

Explain the relation between body heat loss with respect to the wind.

A

Wind causes body to perceive decreased temperature leading to hypothermia.

Less wind, less convection, and vice versa.

(Convection involves moving heat from one place to another by the motion of air movement)

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10
Q

The relation between body heat loss with respect to humidity.

A

Evaporation, including sweating, becomes less efficient when humidity is high.

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11
Q

Describe how the formation of sweat in order to maintain body temperature during exercise works.

A
  1. Plasma is the source of sweat formation
  2. Sweat is formed in the secretory parts of the sweat gland
  3. Amount of sweat formed depends on the individual/ exercise intensity/ hydration status.
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12
Q

Physiological responses that occur during prolonged exercise in the heat.

A

The reduced muscle blood flow in high temperatures results in increased glycogen breakdown in the muscle and higher levels of muscle and blood lactate in comparison to the same exercise performed in a cooler environment.

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13
Q

Health risks associated with exercising in the heat.

A

Heat-related disorders include heat cramps, heat exhaustion and heat stroke.
Because of their relatively large body surface area and immature sweat response, infants, children and young adolescents are more susceptible to complications associated with exercise performed in the heat and the cold.

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14
Q

Define what heat cramp is and steps that should be taken to prevent it.

A

It’s a type of heat illness, are muscle spasms that result from loss of large amount of salt and water through exercise.

  • Stop exercise; rehydrate
  • Massage/Light stretching
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15
Q

Define what heat syncope is and steps that should be taken to prevent it.

A

In other word called fainting, it’s an illness when that results from Intense prolonged exercise in the heat

  • Acclimatize
  • Rehydrate
  • Reduce exertion on hot days
  • Avoid standing still in the heat
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16
Q

Define heat exhaustion and outline steps that should be taken to prevent it.

A

Heat exhaustion is a condition whose symptoms may include heavy sweating and a rapid pulse, a result of your body overheating.

  • Remove subject to shaded area/air conditioned area
  • Hydrate before and during exercise
  • Acclimatize
17
Q

Define heat stroke and outline steps that should be taken to prevent it.

A

Heat stroke is a type of severe heat illness that results in a body temperature greater than 40.0 °C (104.0 °F) and confusion.

  • Immediate whole body cooling
  • Acclimatize
  • Adapt to climatic constraints
18
Q

How an athlete should acclimatize to heat stress.

A
  • Performing training sessions in similar environmental conditions (heat and humidity) for 5 to 10 days results in almost total heat acclimatization.
  • The intensity of training should be reduced to avoid heat-related problems in these conditions.
19
Q

What is the ethical consideration for an athlete when they acclimatize to heat stress?

A

There’s an ethical implication that poorer nations will be unable to afford such support mechanisms and so their athletes are disadvantaged in comparison to athletes from wealthier nations.

20
Q

Physiological and metabolic adaptations that occur with heat acclimatization in long term adaptation

A
  • Increased plasma volume
  • Increased sweat response
  • Reduced rate of muscle glycogen utilization
21
Q

Explain the principal means by which the body maintains core temperature in cold environments.

A
  • shivering
    • (repeated muscular contractions
    • uses up extra oxygen and glucose/glycogen stores.
  • non-shivering thermogenesis)
    • (The cold stimulates adrenaline which acts on BAT to break down Trigycerides into FFA and Glycerol.

FFA undergo oxidation in the mitchondria releasing heat)

  • peripheral vasoconstriction.
    • (Constriction of the blood vessels close to the skin and skeletal muscles, meaning more blood remains near the core.
    • keeps the core temperature elevated and decreases the heat transferred to the environment.)
22
Q

why is the body surface area-to-body mass ratio is important for heat preservation

A

The ratio of body surface area to body mass affects the rate of heat loss.

A larger surface area to body mass ratio = Increased heat loss

A lower surface area to body mass ratio = decreased heat loss.

Higher SA allows more sweating to cool the skin with evaporation and convection

23
Q

What causes wind- chill, in relation to body heat loss

A

A chill factor created by the increase in the rate of heat loss via convection and conduction caused by wind.

24
Q

Why swimming in cold water represents a particular challenge to the body’s ability to thermoregulate

A

During cold-water immersion, humans generally lose body heat and become hypothermic at a rate proportional to the thermal gradient and the duration of exposure.
During swimming, the effect of cold water on body heat loss is increased because of greater convective heat loss. However, at high swimming speeds, the metabolic rate of the swimmer may compensate for the increased heat loss.

25
Q

Physiological responses to exercise in the cold

A
  • Decrease in muscle contractility (ability to contract)
  • Decrease in the power and velocity of muscle contraction
  • Prolonged exercise in the cold depletes glycogen stores and can lead to an inability to maintain blood glucose.
26
Q

Health risks of exercising in the cold, including cold water

A
  • Hypothermia
    • Body’s core temperature falls below 35 which is required for body function
  • Frostbite
    • Constant freezing of the cells and can lead to cell death.
27
Q

Precautions that should be taken when exercising in the cold.

A
  • The main precaution that should be taken when exercising in the cold, is clothing.
  • Decrease amount of skin in contact with the environment in high wind-chill.
    • Decrease the amount of convective heat loss
  • Provide insulation for feet, hands, ears
    • The hands/fingers, feet/toes and ears are the parts of the body most prone to frostbite.
  • Preserve a warm core temp
    • Warm core temp means warm extremities
  • Increased carbohydrate intake
    • Account for increased glucose/glycogen use during exercise in the cold
28
Q

Why is there increased hydration while exercising in the cold?

A

Exercise in cold results in increased breathing rates, increased heat production and therefore increased potential for dehydration

29
Q

Why is the clothing requirement is dependent on the intensity of exercise and environment

A

Too much clothing can lead to heat stress from excess heat production and decreased ability to remove heat.

30
Q
A