Resp 14 - Hypoxia Flashcards

1
Q

What parameter defines hypoxaemia?

A

PO2 < 8 kPa

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2
Q

Describe how the partial pressure of oxygen changes from inspired air to the tissues.

A

21.3 —> 20 (conducting airways) —> 13.5 (alveoli as the air is humidified and mixes with the air in airways) —> 13.5 (PaO2 immediately past exchange surface) —> 13.3 (diluted by return of bronchial circulation, 99% saturation) —> 5.3 (mixed venous blood, 75% saturation)

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3
Q

How does PAO2 and PaO2 change with age?

A

Decreases

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4
Q

How can the partial pressure of oxygen in the alveoli (after mixing) be changed?

A

It’ll continue to move down its concentration into the blood until it reaches equilibrium.

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5
Q

How is the ODC shifted to the right?

A

In environments that are associated with increased metabolism (e.g. exercise) - this is associated with:
o Increase in acidity
o Hypercapnia
o Increased 2,3-DPG concentration

Shifted to the left is the opposite

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6
Q

How is the ODC squished?

A

Anaemia

Polycythemia causes it to get shifted up

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7
Q

What percentage of cardiac output goes to perfuse the bronchial tree?

A

1%

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8
Q

State the normal arterial and venous PO2.

A

Arterial = 13.3
Venous = 5.3
NOTE: only 25% of haemoglobin desaturates when going from arteries to veins

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9
Q

How does dissolved oxygen affect the oxygen that is bound to haemoglobin?

A

The PO2 (dissolved oxygen) only counts for a small part of oxygen transport in the blood (the rest is bound to haemoglobin) but it is like the conductor of an orchestra. Uptake of dissolved oxygen into tissues is NOT keeping you alive directly, but it is accompanied by a LARGE unloading of oxygen from haemoglobin, which provides a sufficient supply of oxygen to the tissues.

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10
Q

The amount of gas that’ll diffuse across a membrane is proportional to:

A

o Surface area for gas exchange
o Diffusion constant (CO2 diffuses faster than O2)
o Diffusion gradient - hypoxic air reduces this gradient

–> Fick’s law

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11
Q

What is the oxygen cascade? What does it look like when you are breathing hypoxic air?

A

It describes the decreasing tension of the air from inspired to respiring cells.

When breathing hypoxic air, inspired PO2 is much lower so each step has a lower PO2. Exercise capacity is greatly reduced

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12
Q

State four factors affecting the oxygen cascade.

A

Ventilation/Perfusion mismatch
Alveolar Ventilation
Diffusion Capacity
Cardiac Output

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13
Q

State the different energy sources for different durations of exercise.

A
(in order of increasing duration of exercise - longest at the bottom)
Intramuscular ATP
Phosphocreatine
Lactic Acid 
Aerobic
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14
Q

State the five challenges of altitude.

A
Hypoxia
Solar Radiation
Thermal
Hydration
Dangerous
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15
Q

What’s the difference between accommodation and acclimatisation.

A
Accommodation = ACUTE response to this kind of change - rapid physiological change in response to a change in oxygen in the oxygen environment 
Acclimatisation = physiology becomes more efficient so that you can get more out of the environment
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16
Q

What have the benefits of increased ventilation and PaO2 been attributed to?

A

Renal compensation for the respiratory alkalaemia

Increased sensitivity to hypoxia

17
Q

Where is erythropoietin produced?

A

Renal cortex

18
Q

What does low PaO2 stimulate and what is the name given to this response?

A

Hypobaric Hyperventilation

Decreased PaO2 –> Increase Ventilation –> Increase PAO2 –> Increase PaO2

19
Q

What is acetazolamide?

A

Carbonic anhydrase inhibitor. This will create excess bicarbonate which will take up H+ from blood and so less H+, less acid so pH rises.
This is used to accelerate the slow renal compensation to hypoxia-induced hyperventilation (increased secretion of HCO3-)

20
Q

What is acclimation?

A

Like acclimatisation but in an artificial environment like breathing hypoxic gases or hypobaric chamber

21
Q

State four innate adaptations of native highlanders.

A

Barrel Chest - more O2 into body
Increased Haematocrit - more O2 carried in blood
Large Heart - greater pulmonary perfusion
Increased Mitochondrial Density - More O2 utilised

22
Q

What causes chronic mountain sickness and what are the consequences of CMS?

A

CMS is thought to be due to secondary polycythaemia in response to hypoxia - RBCs are overproduced to the point where they are no longer beneficial - thicken the blood. This spontaneously happens in acclimatised individuals. Symptoms - cyanosis, fatigue.

Consequences - heart failure, eventual death

23
Q

What causes acute mountain sickness and what are the consequences?

A

Maladaptation to the high altitude environment usually right after ascent. Symptoms are pretty vague, ‘hangover’ - dizziness, vomiting, irritability, insomnia, fatigue. Probably associated with mild cerebral oedema.

Consequences: HACE or HAPE

24
Q

What causes High Altitude Cerebral Oedema (HACE)?

A

Cause: rapid ascent or inability to aclimatise;
Vasodilation of vessels in response to hypoxaemia (to increase blood flow).
More blood going to the capillary beds and so more leakage —> cerebral oedema —> rise in ICP —> herniation

Symptoms: confusion, ataxia, behavioural change
Consequences: irreversible brain damage, coma, death

25
Q

What causes High Altitude Pulmonary Oedema (HAPE)?

A

Pulmonary arteries VASOCONSTRICT in response to hypoxaemia - leading to pulmonary hypertension.
This means that hydrostatic pressure in the capillaries is increased so more fluid moves out of the capillaries and into the tissue.

Symptoms: dyspnea, dry cough, bloody sputum

26
Q

What are the two main types of respiratory failure? State the parameters that define them.

A

Type 1 = Hypoxaemic (PO2 < 8 kPa)
Type 2 = Hypercapnic (PCO2 > 6.7 kPa)
There is also a third type: Mixed = PO2 < 8kPa AND PCO2 > 6.7 kPa

27
Q

What causes type 1 and type 2 respiratory failure?

A

Type 1 = V/Q mismatch - hypoventilated alveoli or hypoperfused
Type 2 = Increased CO2 production and decreased elimination - obesity, decreased CNS drive, increased work of breathing - basically air stagnates because poor ventilation, poor conc. gradient

28
Q

How do the kidneys control blood pH?

A

By secretion and retention of weak acids

They can eliminate or replenish H+ by altering the plasma bicarbonate concentration (HCO3-)