Respiratory 2

Question 1

Gas diffusion between air and blood

Answer 1

(REFER TO LECTURE IMAGES)
Left images
- 159 mmHg - partial pressure of oxygen in atmosphere
- 100 mmHg - partial pressure of oxygen in alveolar gas
- Positive difference - Diffusion of oxygen into the blood from lungs increased oxygen in blood

Right image

• More carbon dioxide in alveolar gas than in air
• Negative difference - Diffusion of carbon dioxide into the lungs from the blood will increase carbon dioxide in lungs

Lower image

• The sheet are represents the alveoli and the capillaries
• The movement of gases is determined by the area and thickness of the sheet (alveolar capillary interface)
• Vgas - the larger the difference in partial pressure increases the flow of gas

Question 2

Ventilation and Perfusion

• Normal
• Stop blood flow
• Stop Ventilation

Answer 2

Ventilation: Process of bringing air into and out of the lungs

Perfusion: Blood flow through the pulmonary arteries, pulmonary capillaries & pulmonary veins

Normal
- Ventilation & perfusion

Stop Blood Flow

• Ventilation & no perfusion
• Diffusion of gas from lungs to the blood will decrease

Stop Ventilation

• Perfusion & no ventilation
• Diffusion of gas from the lungs to the blood will eventually slow down and then stop
• Once the oxygen partial pressure in the lungs becomes 40mmHg oxygen will no longer diffuse into the blood because the partial pressure of oxygen in the lungs and blood will be equal

Question 3

Ventilation and perfusion increase during exercise

• CO
• Alveolar ventilation
• Alveolar PO2

Answer 3

• Cardiac output increases progressively as you work harder during graded exercise and will eventually plateau
• Alveolar ventilation increases in a straight line to a point by which it then increases disproportionally relative to the change in intensity
• Alveolar PO2 increases as a result of exercise

Question 4

PO2, O2 solubility and haemoglobin

- resting value of oxygen consumption

Answer 4

• Pgas = Total Pressure (mmHg) × Fgas
• PO2 = Total Pressure (mmHg) × FO2
• PO2 of dry air at sea level = 760 mmHg × 0.21 = 159 mmHg
• Resting value of oxygen consumption: 200-400 ml’s per minute
• Plasma can hold some oxygen but not as much as haemoglobin. We need haemoglobin to survive

Question 5

O2 binding, exercise & altitude

Answer 5

• O2 dissociation curve for Hb. (binging affinity gets stronger the more oxygen it holds. It hold onto the four oxygens very strongly)
• Most of the total O2 content is bound to Hb compared with that dissolved in plasma.
• Anchor points: arterial (100 mmHg); mixed venous (40 mmHg).
• Rightward shift of curve during exercise… less oxygen in the blood - something has weakened the affinity of haemoglobin to bind to oxygen
• ..due to increases in T, [H+ ], PCO2 and 2-3DPG.
• This shift is favourable for unloading of O2 in muscle, but increases the difficulty of O2 binding in the lungs.
• Effect of going to Mt Everest (8848 m, Bar. Pressure = 253 mmHg)?

Question 6

Oxygenating blood during exercise

- demand

Answer 6

When the demand for oxygen increases, we have the capacity to utilise more oxygen, deliver more oxygen or at a higher rate and transfer at the lungs at a higher rate

1. Pulmonary O2 exchange 
2. Circulatory O2 Delivery 
    3. Cellular O2 utilisation

Question 7

Pulmonary gas exchange, CaO2 and O2 uptake

- Transit time

Answer 7

Transit time for oxygen exchange during rest is 0.25second, however, during exercise blood flow is much faster so the oxygen exchange may be reduced

Question 8

Oxygen cascade effectiveness of pulmonary gas exchange

• partial pressures of alveolar PO2 and arterial PO2
• Rest & exercise

HINT: Under normal exercise conditions….

Answer 8

• Under normal exercise conditions (“Exercise”), alveolar PO2 and arterial PO2 are very similar and the arterial PO2 and CaO2 are high.
• Thus, the lung is generally considered not to limit O2 delivery and O2 uptake.
• But…pulmonary gas exchange can become impaired and this is reflected in an increase in the difference between alveolar and arterial PO2 linked to a reduction in the O2 saturation of arterial blood (%SaO2 , next slide) and fall in CaO2
  Rest: partial pressure of oxygen decreases as it travels around the body (air -> airway -> alveoli -> systemic arterial -> tissue -> systemic/venous). Cells <1% O2
  Exercise: Higher PO2 in airway & alveoli. In blood, less PO2. In tissues, less PO2. Cells &laquo_space;(much less) 1% O2

Question 9

Arterial hypoxaemia in athletes

Answer 9

• Data taken from two studies.
• Minimal O2 desaturation (normoxaemia) in six male untrained or ‘less-trained’ subjects (UT) under normoxia (FIO2 = 0.21) – continuous line.
• Large O2 desaturation (hypoxaemia) in seven male endurance-trained subjects (ET) under normoxia – dotted line.
• Hyperoxia (FIO2 = 0.26) has no effect on %SaO2 in UT; but it reduces the hypoxaemia in ET (dashed line).
• Maximum O2 uptake is not affected by hyperoxia in UT (57 ml/kg/min);
• But it is increased from 70 to 75 ml/kg/min in ET.
• Arterial hypoxaemia is due to either diffusion limitation (short pulmonary transit time), inadequate ventilation relative to very high CO2 production and/or the extent of mismatching between the ventilation and perfusion of alveoli (“VAQ inequality”).

Question 10

The paradoxical effect of training on pulmonary gas exchange

Answer 10

• Focus on “maximal exercise” (i.e. at VO2 max)
• In nonathletes (“N.A.”), alveolar PO2 can be increased during exercise; but this has little affect on arterial PO2 .
• In elite athletes (“ATH”) the response of alveolar PO2 is highly variable; but often arterial PO2 is lower than observed in nonathletes.
• Thus, the effectiveness of pulmonary gas exchange can be reduced by training – the paradox.

Question 11

Automatic (chemical) control of breathing

Answer 11

Breathing is controlled by looking at the O2, CO2 and H+ content of the arterial blood

Question 12

The controller

Answer 12

• Brainstem

- Pons & Medulla

Question 13

Effectors

Answer 13

• Phrenic nerves & Diaphragm
• Cervical origin near Medulla
• Accessory muscles

Question 14

Sensors

Answer 14

• Central chemoreceptors located on ventrolateral surface of medulla (CSA)
  
  • Sensitive to CO2 (and H+ ), not O2 .
• Peripheral chemoreceptors located in aortic arch and carotid sinus.
  
  • Sensitive to CO2 (H+ ), O2 and K+ .

At rest breathing is much more sensitive to changes in CO2 than oxygen

Question 15

Basic rhythm of breathing at rest

Answer 15

• The central controller generates the basic inspiratory rhythm at rest – another example of a central pattern generator.
• PreBotzinger complex (found in “VRG”) is the key cluster of neurons controlling the rhythm.
• This rhythm is influenced by neural input from the central chemosensors (see “RTN”) which is linked to the sensing of CO2 levels.
• CO2 is the major stimulus for breathing at rest (see next slide).
• CO2 sensing needed to continually tune the basic rhythm.
• Central apnea syndrome is caused by impaired neuronal function in RTN and severely reduced CO2 sensitivity of RTN.

Question 16

Breathing response to O2 and CO2

Answer 16

At rest breathing is much more sensitive to change in CO2 than oxygen

Question 17

Central apnea syndrome: rest and exercise

Answer 17

• Central apnea syndrome (or congenital hypoventilation syndrome) is characterised by a lack of breathing during sleep.
• The defect lies in the central chemosensor.
• Data (below) from ten children/adolescents who were healthy controls (7-14 y) or had CAS (8-17 y): Shea et al (1993). J Physiol 468: 623-640
• Minimal effect of CO2 on breathing at rest
• Normal response of breathing during treadmill walking

Question 18

Control of breathing during exercise

Answer 18

• Central Command
• Temperature
• Muscle feedback
• Peripheral Chemoreceptors (carotid bodies)
• Baroreceptors + pulmonary artery

Question 19

Peripheral chemosensors

- CBR

Answer 19

• Carotid bodies.
• “CBR” = carotid body resection: carotid bodies removed to help treat asthma.
• Wasserman, Whipp et al. (1975). J Appl Physiol 39(3): 354-358
• No effect at low intensities; larger effect at higher intensities.
• Difference between control and CBR reflects the contribution of the carotid bodies to the ventilatory response during graded exercise.
• This effect usually attributed to rise in [H+ ] (i.e. fall in arterial pH) due to lactic acidosis; but the rise in arterial K+ will also contribute.

Question 20

Central Command

- We can voluntarily control…

Answer 20

• We can voluntarily control our breathing (speak, sing, breath - hold, hyperventilate, etc).
• Neural pathways from motor cortex and other locomotor areas of the brain (hypothalamus) connect to motoneurons of respiratory muscles.
• Stimulation of these pathways increases breathing (e.g., Eldrige et al. (1981). Science 211: 844 -846).
• There is uncertainty about the neural pathways involved and the extent to which central command increases ventilation during exercise.

Question 21

Muscle Feedback

Answer 21

• Muscle contraction stimulates sensory (afferent) neurons which detect changes in mechanical and chemical states (type III and IV neurons).
• Input from these afferent neurons reaches regions of the medulla.
• Mild electrical stimulation of muscle evokes similar breathing responses to voluntary contractions (Adams et al. (1987) J Physiol 383: 19-30).
• This suggests that sensory feedback from muscle contributes to the rise in ventilation during mild exercise.
• More recent studies (Professor Jerry Dempsey, USA) involving spinal blockade of this sensory input support this, but also show that this contribution gets relatively smaller at higher workloads.

Question 22

Synthesis

- ventilation

Answer 22

• Muscle sensory feedback - switches on at lower intensities but does not increase its contribution as intensity increases
• Central command - its contribution increases as intensity increases
• Peripheral chemoreceptors- switches on at higher work loads
• Temp - max