Biom2012 Respiratory Physiology L3 Student PDF

Summary

These are lecture notes providing an overview of respiratory physiology, focusing on concepts like pulmonary ventilation, gas exchange, and transport mechanisms.

Full Transcript

BIOM2012 - Systems Physiology:
Respiratory System L3
Dr. Jacky Suen
[email protected]
Credit: A/Prof Stephen Anderson and Dr. Hardy Ernst
Learning Objectives
Pulmonary Ventilation and Respiratory mechanics
Gas exchange
Gas transport
Blood pH regulation
Control of Respiration
 External Respiration

External respiration refers to the exchange of oxygen and
carbon dioxide between blood and alveoli across the
respiratory membrane.

Factors influencing gas movement across the respiratory membrane
Matching of alveolar ventilation and pulmonary blood perfusion
Structural characteristics of the respiratory membrane
Partial pressure gradients and gas solubility
“borrowed” from
CVS lectures Pulmonary Circulation

The pulmonary circulation system is the only system through which the entire cardiac
output passes. The major role of pulmonary circulation is respiratory gas exchange.
“borrowed” from Pulmonary
CVS lectures
Circulation
The pulmonary circuit has the following characteristics:
Low pressure and low resistance circuit
Relatively short circuit
Branches immediately, increases exchange area, and lowers resistance
Arteries (less muscle) and therefore higher compliance vessels cf systemic
Minimal resting smooth muscle tone – normally near fully dilated
'Passive factors' play an important role in determining flow eg. gravity
Receives all cardiac output (from right ventricle)

An important difference is local response to hypoxia – vasoconstriction
Diversion of blood to regions of better ventilation
Is related to minimising ventilation – perfusion (VQ) differences
It supplies blood to regions of lung that will most efficiently oxygenate it.

ventilation perfusion “matching” or “coupling”
 Efficient respiration requires matching ventilation
(V) with perfusion (Q)

PvO2 40 mm Hg
PvCO2 45 mm Hg PAO2 100 mm Hg
PACO2 40 mm Hg

PcO2 100 mm Hg
V/Q = 1 PcCO2 40 mm Hg
 V/Q < 1 V/Q > 1

Increased Decreased Increased Decreased
CO2 O2 O2 CO2

airway dilation + vasoconstriction airway constriction + vasodilation
 Structural Characteristics
of the respiratory membrane

The respiratory membrane refers
to the area between the alveolus
and pulmonary capillaries lining the
terminal portions of the lungs.

Features
alveolar walls are lined in thin squamous epithelial cells (type I pneumocytes)
pulmonary capillaries tightly encase the external surfaces of the alveoli
type II pneumocytes secrete pulmonary surfactant
a thin (approximately 0.5 µm) layer of interstitial fluid exists

Together, the above allow for O2 and CO2 to easily diffuse between the systems
 Structural Characteristics
of the respiratory membrane

Diffusion is ideal for gas transport over short distances.

Recall characteristics of diffusion
- hint: what sort of process?
- hint: movement occurs how?
- short distance
- hint: many alveoli = a good what?
- solubility of gases matter

Over larger distances gases require ‘bulk flow’ (atmosphere
to alveoli) or to be carried in circulation (Hb)
 Partial pressure gradients & gas solubility

Dalton’s law in respiration:
In a given system of mixed gases, the partial pressure exerted
by a single gas present will be proportional to the amount or
percentage of that gas.

Atmospheric air is a mixture of gases:
nitrogen (N2) at about 78.6%
oxygen (O2) at 20.9%
most of the remaining 0.5% consists of water vapour (H2O)
carbon dioxide (CO2) a mere 0.04%
Partial pressure gradients & gas solubility

Henry’s law in respiration:
The amount of a gas that dissolves in a liquid is directly
proportional to the partial pressure of that gas.

Also, gases with a higher solubility will have more dissolved
molecules than gases with a lower solubility, if they have the
same partial pressure.

So whilst N2 in the atmosphere is found in high concentrations,
only very minute concentrations are dissolved into blood,
due to low solubility in plasma.

In contrast, CO2 is the most soluble (23x more soluble than O2).
Dalton +
Henry’s law
At a given
temperature, the
amount of a particular
gas in solution is
directly proportional to
the partial pressure of
that gas.

Gas exchange occurs down the partial pressure gradient!
Quick Quiz
Patients with
respiratory failure often
received oxygen
therapy.

What’s the PO2 with
50% O2?
 Respiration includes 4
events

To ensure delivery of O2 to
tissues, and the disposal of
CO2.
 O2
Gas exchange: happens at
both the pulmonary capillary
and the tissue-capiliary levels
Down the partial pressure
gradient

Gas transport: O2 needs to be
moved from lungs to tissues,
and vice versa for CO2

CO2
 External Respiration
Inhaled air is humidified prior to reaching
the alveoli. Additionally, the air in the alveoli is
comprised of more CO2 and less O2 than atm air.

Uptake of O2 into the CVS (from Resp system)
Mismatch between the partial pressure of O2 in
the air around us (in particular, our alveoli)
pO2 = 104 mmHg versus partial pressure of O2 in
venous blood pO2 = 40 mmHg
drives diffusion of gas down a pressure gradient.

Removal of CO2 from the CVS (to Resp system)
pCO2 = 46 mmHg in blood to pulmonary capillaries
versus pCO2 = 40 mmHg in avleoli

But CO2 more soluble in plasma so the the amount
of CO2 diffuses between the blood and the alveoli is
similar to the amount of O2.

The steep O2 gradient allows O2 partial pressures to
rapidly reach equilibrium (in 0.25 seconds). Blood
can move 3 times as quickly through the pulmonary
Adapted from RG Carroll (2007) capillary and still be adequately oxygenated.
Elsevier’s Integrated Physiology
Factors other than the partial pressure
that influence the rate of gas transfer:

Surface area
Thickness of the membrane
diffusion coefficient
Factors other than the partial pressure
that influence the rate of gas transfer:
Changes due to
Surface area physiological demands,
Thickness of the membrane and diseases

Diffusion coefficient - depends on gas and concentration
Decreased
surface area
Emphysema
Increased thickness of membrane due to
Pulmonary oedema (HAPE)
Pneumonia (COVID-19, Influenza A)
Pulmonary Fibrosis (post COVID-19)
Why does it matter?
Acute Respiratory Distress Syndrome (ARDS)
1 in 10 mechanically
ventilated patients
Up to 45% mortality
3 out of 4 acute COVID-19
death
NO TREATMENT!
Diffusion Coefficient

Diffusion coefficient (D) determines the rate of gas transfer

Related to solubility and molecular weight.

D for CO2 is ~20 times that of O2

But O2 has a bigger difference in partial pressure

Normally equal amounts of O2 and CO2 are exchanged.
Quick Quiz
What are the 5 factors that affect rate/efficiency of gas transfer?

Function Location Influencing factors

Ventilation Airways Airway resistance
Lung compliance
Alveolar surface tension
Gas exchange Respiratory membrane Gas characteristics
Pressure gradient
Diffusion Coefficient
Membrane characteristics
V/Q matching
Gas Transport

Respiratory rate
V/Q < 1
V/Q > 1