Respiration and Breathing

Question 1

State Laplace’s and Fick’s laws:

Answer 1

LaPlace’s:
Pressure = 4(surface tension)/r

In alveoli divide by two as only one surface is a liquid-gas interface

Fick’s law:
dQ/dt = (Δp x A x d)/t

Diffusion rate = (Δpartial pressure x diffusion coefficient x area)/thickness.

d ∝ sqrt(molecular weight)

Question 2

What is Henry’s law and what does it describe?

Answer 2

Describes concentration of gas in blood:
Concentration = partial pressure x solubility

[Blood O2] = (1.39 x [Hb] x % saturation) + (0.003 x PO2)

Don’t forget the dissolved O2!!

Partial pressure = (atmospheric pressure - 47) x (%gas/100) in mmHg from DRY percentage

Question 3

What is functional residual capacity and how is it created?

Answer 3

FRC: the point at which elastic recoil forces inwards equals the outward forces from the chest wall.

Question 4

What is a collapsed lung?

Answer 4

• A breaking of the air-tight seal of the interpleural space
• Meaning negative pressure not maintained.
• Therefore force inwards due to elastic recoil overcomes force outward = collapse inwards

Question 5

What is compliance of the lung? What does it depend on?

Answer 5

ΔP/ΔV (gradient) = the pressure required to cause a given volume change.

Human lung shows marked hysteresis (lung volume at given pressure is larger on deflation

• Rigidity
• Shape of thoracic cage
• Expanding muscle strength
• Elastic properties (e.g. surface tension)
• Lung size

Question 6

What is specific compliance?

Answer 6

• Compliance divided by functional residual capacity
• Adjusts for lung size
• Roughly constant throughout animal kingdom

Question 7

What is regional compliance of the lung?

Answer 7

• Lung is more compliant at the base (maybe due to more surfactant)
• Pressure also higher in base due to gravity meaning larger volume expansion at base (for same mean pressure)
• Leads to base accepting a disproportionately large fraction of tidal volume
• During expiration opposite effect seen (base constricted more)

Question 8

How can regional compliance/tidal volume distribution be shown?

Answer 8

• (133)Xe gas inhaled with oxygen and the radiation distribution measured
• Graph drawn to show data (unit volume against distance up lung gives +ve proportional relationship during inspiration)

Question 9

Define trans total pressure; transmural pressure; trans chest wall pressure and transpulmonary pressure.

Answer 9

Trans chest wall pressure = pressure inside lung – atmospheric pressure

Transmural pressure = pressure inside - pressure outside

Trans chest wall pressure = pleural space pressure – atmospheric pressure

Transpulmonary pressure = pressure inside lung - pleural space pressure

Question 10

What are the effects of abnormally high and low lung compliance?

Answer 10

Compliance effects FRC

Abnormally high compliance (distensible lung):
- Elastic properties reduced (recoil force less)
- Exhaling becomes energy expensive as FRC now at much larger volume
- E.g. emphysema

Abnormally low compliance (stiff lung):
- More work required to increase -ve pressure high enough to expand lung
- Occurs during scarring/fibrosis e.g. after irritant exposure (silica/carbon particles, smoking)

Question 11

What factors affect lung compliance? Give examples.

Answer 11

Shape and rigidity of thoracic cavity:
- Extreme obesity can deform thorax, reducing compliance
- Fat deposits/deformation may narrow airways (increased resistance)
- Increased force required to expand thoracic cavity due to surrounding tissue (not compliance but added factor)

Surface tension:
- Generated by air-liquid interface (LaPlace law)
- Hugely affected by surfactant: shown by IRDS

Question 12

What do the Von Neergaard experiments show?

Answer 12

• Replaced air with saline solution to inflate lung
• Recorded pressure required to reach certain volume
• Pressure was much lower using saline and showed very little hysteresis
• Showed that surface tension accounts for large proportion of lung stiffness.

Question 13

How does pulmonary surfactant work?

Answer 13

• Surfactant molecules are highly organised due to their strong polarity (DPPC molecules)
• Forms a layer on inner surface stopping water from depositing and thereby reducing surface tension of lung
• Its ability to dynamically change in thickness during inhalation/expiration could explain hysteresis of lung compliance.

Question 14

How is pulmonary surfactant produced?

Answer 14

• Secreted by type II alveolar cells from precursors: glucose/choline/palmitate
• High turnover rate due to continued removal of surfactant on inner alveolar surface
• Forms highly organised (due to polarity) DPPC

Question 15

What are the roles of surfactant?

Answer 15

• Keeps lung dry (stops high surface tension of a water layer)
• Reduces water being drawn out from capillaries
• Reduces overall surface tension of lung, hence also compliance and therefore, work required to breath
• Allows alveoli of different sizes to coexist: normally there is increased pressure in smaller alveoli (forces air out causing collapse), surfactant opposes this by reducing surface tension inversely to increased pressure, allowing expansion

Question 16

Give evidence for surfactants’ role:

Answer 16

• IRDS: premature babies babies (alveolar type II cells not yet formed) who have limited surfactant struggle to breath due to increased surface tension
• Thoracic surgery patients who do not breath deeply for a period of time, leading to poor surfactant distribution and atelectasis also struggle.

Question 17

How might the structure of surfactant explain hysteresis of lung compliance?

Answer 17

• Magnitude of surfactant effect is dependent on the surface area and thickness of layer
• Due to structure, thickness can change between inhalation and exhalation
• Surfactant can expand (unlike most liquids) during inhalation = relatively thinner until molecules forced out of layer
• On expansion, molecules are fitted in again (harder) so lung relatively MORE compliant on exhalation

Question 18

What is a langmuir trough and what does it show?

Answer 18

• Set up: very stable tray containing test liquid with a high sensitivity force transducer, the force required to move the transducer perpendicular to the surface is the St.
• Area of the surface can be changed to simulate lung volume changes
• Surfactant is special as it reduces surface tension dependent on surface area

Question 19

What factors affect resistance to airflow in the lungs?

Answer 19

Think Poiseuille’s’ law: (8ηl/πr^4)

Radius of airways:
- Increased on inhalation as small airways are suspended in parenchyma which connects them to surrounding tissues.
- Contraction state of smooth muscles under parasympathetic control (ACh causes constriction and mucus secretion; adrenaline causes dilatation and mucus inhibition)
- PCO2 induces dilatation

Viscosity of gas increases resistance to movement.

Mucus secretion also increases resistance.

Question 20

What is the equal pressure point?

Answer 20

• Must always be a pressure gradient towards to mouth during expiration
• Therefore pressure inside airways decreases along length
• At some point the pressure inside = inward pressure from pleural contraction
• Transmural pressure = 0
  This is EPP.

Question 21

What are the consequences of the EPP in the lungs?

Answer 21

Limits flow rate of expiration due to potential airway collapse:
- Intrathoracic pressure increases during expiration (to create pressure gradient)
- Alveolar recoil and added pressure from contraction of pleural space increases pressure inside airways
- The steeper the pressure gradient, the lower EPP.
- Gradient must be shallow enough to make sure EPP occurs in supported airways (with cartilage rings)

Question 22

What factors control where EPP occurs?

Answer 22

• Lung compliance (since added to recoil) - shown by low EPP in emphysema
• Strength of thoracic muscle contraction

Question 23

Why does CO2 equilibrium never limit gas exchange?

Answer 23

• CO2 is 23 times more soluble than O2 in plasma (e.g. coefficient for CO2 is 0.7; for O2 is 0.03)
• This outweighs effect of molecule size (changes with sqrt(Mr)
• Therefore CO2 equilibrium always reached first.

Question 24

How does the lung continue to reach equilibrium on decreased transit time of blood (e.g. increased HR in exercise)?

Answer 24

• At rest, lung has diffusion reserve = spare transit distance where equilibrium already reached
• Gives roughly 0.3 seconds of spare time
• Lung can increase capacity (more alveoli open) by increasing breathing depth (vital; rather than tidal capacity)

Question 25

What is the difference between oxygen partial pressure and oxygen content in blood?

Answer 25

• O2 PP: only affected by dissolved O2
• Oxygen content is dissolved AND bound to haemoglobin

Question 26

Describe the structure of haemoglobin:

Answer 26

• 2α and 2β peptide chains
• Shows polymorphism (Adult = A; fetal = F; sickle cell = S)
• Reversibly binds 4 oxygen molecules (oxygenation) in porphyrin ring
• Sequential binding affects affinity of next binding sites (positive cooperativity)

Question 27

Name some factors which alter haemoglobin affinity:

Answer 27

Bohr effect: decreased pH shifts curve right (decreases affinity)

Haldane effect: higher CO2 concentration shifts curve right (weak acid) and forms more carbonamino compounds (think equilibrium)

2,3 DPG: shifts curve right (F Hb is less sensitive to this)

Question 28

What is one problem caused by leaving blood for a long time before transfusion?

Answer 28

2,3 DPG degrades over time, meaning blood may have an overly high affinity.
- Reduces unloading at tissue bed

Question 29

Describe 5 blood gas disorders:

Answer 29

Hypoxic hypoxia: low arterial pO2, with low Hb saturation
Anaemic hypoxia: reduced O2 carrying capacity (e.g. low RBC count)
Circulatory hypoxia: Poor delivery of oxygenated blood to tissues (haemorrhage)
Histotoxic hypoxia: normal O2 delivery but cells unable to use O2 (e.g. cyanide poisoning)
Hyper/hypocapnia: describes CO2 partial pressure due to hypo/hyper ventilation

Question 30

Why is carbon monoxide so deadly (and a fabulous poisonous gas)?

Answer 30

• CO has 240 times the affinity for Hb as O2
• Hence shifts curve left: increases affinity (but O2 beat out by CO) and prevents unloading of any O2 at tissues
• Hence 0.1% contaminated air can kill
• Tasteless, odourless, colourless, no hypoxic signs (blood still bright red)

Also impairs feedback mechanisms as arterial pO2 can be normal

Question 31

How is CO2 transported in blood?

Answer 31

• 5-10% dissolved
• 90% as bicarbonate (acts as buffer)
• 5% as carbonamino compounds (replaces one H on amide group)

Question 32

Describe the two buffer equilibria in blood for CO2:

Answer 32

Bicarbonate buffer:
CO2 + H2O <–carbonic anhydrase–> H2CO3 <—–>HCO3- + H+
- Made faster by carbonic anhydrase in RBCs

Carbonamino compounds:
R-NH2 + CO2 <—–> R-NHCOOH <—–> R-NHCOO- + H+
- Proteins can reversibly bind CO2 to amine groups.
- On Hb: CO2 binds to imidazole groups on histidine residues of α/β chains

Question 33

Detail three effects interacting in RBCs to control CO2 concentration:

Answer 33

Bohr effect: right shift to oxygen dissociation curve due to lower pH (better unloading at tissues)

Haldane effect: higher PO2 decreases Hb affinity for CO2 (allows better loading of O2 at lungs)

Hamburger’s phenomenon: allows right shift to bicarbonate equilibrium (more HCO3-) to be formed in RBC without net loss of anions. Allows CO2 to be drawn in.

Question 34

Explain Hamburger’s phenomenon:

Answer 34

• Cl- exchanged for HCO3- by BAND3 transporters
• Allows more HCO3- to be produced from shift of bicarbonate equilibrium
• Draws more CO2 into RBCs when pCO2 high

Question 35

Give adaptations of the pulmonary circulation:

Answer 35

Low resistance:
- Many parallel vessels (redundancy)
- High compliance (= capillary distension) meaning it is not limiting during increased flow

Important to prevent high pressure which leads to oedema.

Question 36

How can pulmonary arterial pressure be measured?

Answer 36

Using a Swan-Ganz catheter

Question 37

Which factors influence pulmonary resistance?

Answer 37

Increased CO:
- Recruitment
- Capillary distension = high compliance

Lung volume:
- Extra-alveolar vessels are opened by -ve pleural pressure so open (even when internal alveolar pressure constricts)
- At FRC resistance is lowest

Hypoxia:
- Causes vasoconstriction (effective locally to divert blood to better area but problematic over whole lung e.g. at altitude).

Question 38

What is Starling’s equation and what does it describe?

Answer 38

fluid flux = k[(Pcapillary – Pinterstitial) - σ[(πpleural - πinterstial)]

= Hydrostatic – colloid pressure

Describes fluid exchange between capillaries and interstital spaces.

Question 39

Using principles from Starling’s equation - how might pulmonary oedema be caused (give specific examples)?

Answer 39

• Increased capillary pressure: E.g. general hypoxia (altitude, emphysema); left heart failure.
• Decreased capillary colloid osmotic pressure: E.g. starvation resulting in plasma protein loss.
• Increased interstitial pressure: E.g. increased surface tension (causing increased -ve pressure) from IRDS.

May also be due to:
- Blocked lymphatic drainage
- Increased capillary wall permeability

Question 40

What are the mechanisms of fresh and salt water drowning?

Answer 40

Fresh water: lysis of RBCs; and cardiac fibrillation following increased Na+/K+ due to cell bursting.

Salt water: water drawn out of pulmonary capillaries into interstitium = death by asphyxiation

Question 41

What effect does gravity have on blood distribution in the lungs and why?

Answer 41

• 22mmHg difference between bottom and top
• Therefore most collapsed capillaries are in the top of the lung
• Middle pressure higher due to heart proximity not gravity

Question 42

Name some functions of the pulmonary circulation other than perfusion:

Answer 42

• Bronchial circulation provides warmth and humidity
• Serves as blood reservoir (10% of blood volume evenly distributed)
• Filtration
• Metabolism of vasoactive hormones

Question 43

How does the pulmonary circulatory system filter blood?

Answer 43

• Emboli/fat/clots: traps small blockages in capillaries protecting downstream organs (able to due to high redundancy)

Question 44

Give examples of the role of pulmonary circulation in metabolising hormones:

Answer 44

• Angiotensin I: locally converted to angiotensin II by ACE on endothelial cells
• Inactivation of hormones: E.g. SHT, NA, bradykinin, prostaglandins to reduce oedema due to damage from inflammation.
• Adrenaline/HA/ADH unaffected by passage through

Question 45

What is the ventilation-perfusion mismatch?

Answer 45

• Ventilation and perfusion increase down lung
• Perfusion increased more due to greater effect from gravity
• Therefore down lung ventilation/perfusion ratio changes from 3 –> 0.7

Question 46

How does the body oppose a change to average ventilation/perfusion ratio (Va/Q)?

Answer 46

• Low VA/Q ratio requires an increase in overall ventilation: regional vasoconstriction induced by localised hypoxia (shunts blood away)
• High VA/Q ratio suggests ventilation is wasted (local PCO2 will fall): Increase in pH and localised airway resistance (shifting ventilation to other alveoli)

Question 47

What is venous admixture? Why does it occur?

Answer 47

= Mixing of oxygenated and deoxygenated blood

Wasted air:
- Air in dead space does not oxygenate blood; blood

Wasted flow (any blood not fully oxygenated):
- Physiological shunting: blood bypasses alveoli (e.g. septum hole in heart, venous drainage of bronchial circulation). Approx 1-2% of CO.
- Alveolar shunting: blood contacts alveoli but does not become fully oxygenated (e.g. oedema, pneumonia, atelectasis)

Question 48

What is the alveolar gas equation?

Answer 48

Alveolar gas equation: PAO2 = PIO2 – PACO2[FIO2 + (1 - FIO2)/R]

• PIO2 is the partial pressure of inspired oxygen
• FIO2 is the fractional concentration of oxygen
• R is the respiratory exchange ratio

Question 49

Why does altitude cause problems for breathing?

Answer 49

• Reduced barometric pressure means much harder to draw air into lungs (transpleural pressure reduced) and speed of inhalation reduced.
• Main consequence is reduced pO2 (>4 fold drop at everest summit)
• Augmented by 5-fold ventilation increase to compensate
• Equilibrium may still not be achieved (all of diffusion reserve used) as diffusion gradient also shallower
• Oedema may result from generalised vasoconstriction causing high pressure

Question 50

What are the consequences of hyperventilation?

Answer 50

pH against pO2 battle:
- Decreasing pCO2 alkalises CSF opposing signals from peripheral chemoreceptors to increase pO2
- Sustained hypoxia overcomes pH signals allowing hyperventilation
- [HCO3-] must be reduced in CSF (kidney compensation)
- Over time chemoreceptors may become more active

Question 51

Give examples of adaptations to high altitude:

Answer 51

Polycythaemia (increased RBCs):
- Haemoglobin saturation lower so more need.
- Stimulated by increased endogenous erythropoietin
- In Peruvian Andes overcompensation seen!
- Not always true (Sherpa populations can show lower RBC to increase flow rate)

2,3 DPG increase:
- Causes right shift to oxygen dissociation curve
- Aids unloading at tissues

Question 52

How does SCUBA kit help?

Answer 52

Self-contained underwater Breathing Apparatus:

• Increased pressure in tank to match surrounding hydrostatic pressure
• Maintains trans total pressure so pressure gradient can be created (otherwise force needed is too large)

Question 53

What are ‘the bends’?

Answer 53

• Sustained high surrounding pressure forces low solubility gases into solution
• particularly N2 into fat
• During sudden decompression (e.g. ascent from underwater chamber) bubbles of gas escape, causing pain and potentially death (emboli in brain)

Question 54

How is the risk of ‘the bends’ reduced?

Answer 54

• He-O2 mixture used to breath rather than nitrogen (diffuses more quickly out and does not have narcotic effects of N2 under high pressure)
• Slow ascent to equilibrate; treatment = hyperbaric chamber

Question 55

Why does exercise increase O2 requirement?

Answer 55

• Muscle recruitment: more muscles to serve
• Muscle requirement increases
• Oxygen debt when anaerobic threshold reached (to metabolise lactate and restock PCr

Ventilation normally not limiting

Question 56

What are the two main muscle types and how do their oxygen requirements differ?

Answer 56

Type I (‘red’): slow twitch so mainly aerobic
Type II (‘white’): fast twitch so mainly glycolytic