MBChBI FAF Lectures_2024_Respiration_Prof Essop_FMHS Learn_Podcast_3 Sept .pdf

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MBChB I Respiratory Lectures 2024
Pressure and volume

Prof. Faadiel Essop
Room 3027, BMRI
Email: [email protected]
 Respiratory mechanics: gas laws (Dalton’s Law)

Atmosphere is a mixture of gases (nitrogen [78%]; oxygen [21%]) and water vapor (1%)
Gases move down pressure gradients
Air is a mixture of gases
Dalton’s law
Total pressure = sum of partial pressures of individual gases
Pressure of individual gas in a mixture is known as the partial pressure (Pgas)

Atmospheric pressure (Patm) = 760 mmHg (sea level)
Oxygen levels = 21% of the atmosphere
What is the partial pressure of oxygen (PO2)?

Partial pressure of gas (Pgas) = Patm x % gas in atmosphere
PO2 = 760 x 0.21 = 160 mmHg (sea level, dry air)
John Dalton
1766-1844
 Respiratory mechanics: gas laws (Dalton’s Law)
In humid air, water vapor “dilutes” the contribution of other gases to the total pressure

Partial Pressures (Pgas) of atmospheric gases at 760 mm Hg

Pgas in 25 °C air, 100% Pgas in 37 °C air, 100%
Gas and its percentage in air Pgas in dry 25 °C air
humidity humidity

O2, 21% 160 mm Hg 155 mm Hg 150 mm Hg

CO2, 0.03% 0.25 mm Hg 0.24 mm Hg 0.235 mm Hg
Water vapor 0 mm Hg 24 mm Hg 47 mm Hg

To calculate the partial pressure of a gas in humid air, you must first subtract the water
vapor pressure from the total pressure. At 100% humidity and 25 °C, water vapor
pressure = 24 mm Hg:
Pgas inhumid air =(Patm − PH2O )  %of gas

PO2 = (760 − 24)  21% = 155mmHg
 Respiratory mechanics: gas laws (Boyle’s Law)

Boyle’s Law expresses the inverse relationship between pressure and volume

P1V1 = P2 V2

For example, the container on the left is 1 L (V1)
and has a pressure of 100 mm Hg (P1).
What happens to the pressure when the volume
decreases to 0.5 L?

100mmHg 1L =P2 × 0.5L
200mmHg =P2
Hence the pressure has increased 2-fold
 Respiratory mechanics: gas laws (Boyle’s Law)

Robert Boyle
1627-1691

Graph shows data from Boyle’s original 1662 experiment, which shows that pressure and
volume are inversely related. No units are given as he used arbitrary units in his experiments.

https://courses.lumenlearning.com/wm-biology2/chapter/the-mechanics-of-human-breathing/
 Respiratory mechanics: gas laws (Boyle’s Law)

As the volume of the gas increases, the pressure decreases
proportionately (in diagram you go from A to B to C)

Conversely, the pressure increases proportionately as the
volume decreases (in diagram you go from C to B to A)

Note: same number of gas molecules present in all three
containers

Sherwood, CH13, p452

Boyle’s law: at any constant temperature, the pressure exerted by a gas
varies inversely with the volume of the gas
 Respiratory mechanics: gas laws (Charles’ Law)

Gas volume (V) is directly proportional to temperature (T)
when the pressure is constant:

V1/T1 = V2/T2

The gas volume (V1) at its initial temperature (T1) will increase
to V2 as its temperature increases to T2

Likewise, the gas will reduce in volume if its temperature is
lowered

On a cold day, as air is warmed in the conducting part of the
respiratory system, it will increase in volume
Jacques Charles
1746-1823
 Respiratory mechanics: definitions

Pulmonary ventilation:

-commonly referred to as breathing
-process of air flowing into the lungs during inspiration (inhalation)
& out of the lungs during expiration (exhalation)

Alveolar ventilation:
-exchange of gas between alveoli & external environment

Respiratory cycle:
-consists of one breath in (inhalation; inspiration) & one breath out
(exhalation; expiration)

Air moves into & out of lungs (during breathing) from a region of higher
pressure to a region of lower pressure – down a pressure gradient

Ventilation from ventilatio (from ventus) Latin: ‘’wind’’
 Respiratory mechanics: pressures

Pressures important in ventilation:

Atmospheric pressure:
-pressure exerted by weight of air in the atmosphere
on objects on earth’s surface (760 mmHg at sea level)

Intra-alveolar pressure:
-pressure within alveoli
-anytime it differs from atmospheric pressure,
incoming airflow equilibrates these two pressures

Intrapleural pressure:
-pressure within pleural sac
-usually less than atmospheric pressure (756 mmHg)
Sherwood, CH13, p451 -does not equilibrate with atmospheric and intra-
alveolar pressures as enclosed in a sac
 Respiratory mechanics: pressures

Why is the intrapleural pressure subatmospheric?

Elasticity of the lungs means they tend to pull inwards
towards collapse

Surface tension (alveoli) also tends to pull inwards to
collapse

Elasticity of the chest wall tends to pull outwards

Thus, competing ‘’pulls’’ lead to slight expansion of the
pleural cavity – increased volume

Boyle’s law means the pressure now lowered (typically
by 4 mmHg)

Sherwood, CH13, p451
 Respiratory mechanics: lung region ventilation
& compliance

Gravity & posture the reasons for regional differences
in intrapleural pressures in the lung apex versus base

In upright position, gravity pulls lungs downward &
away from the apex of the thoracic cage

This creates lower intrapleural pressure at apex

Gravity also pushes lungs into the thoracic cavity &
increases pleural pressure

Boron & Boulpaep, CH27, p631 (2nd ed)
 Respiratory mechanics: inspiration
For air to move, pressure inside lungs must become
lower than atmospheric pressure

With inspiration, thoracic volume increases – due to
skeletal muscles (rib cage) & diaphragm contracting

Diaphragm contraction and flattening causes 60-75% of
inspiratory volume change (quiet breathing)

Rib cage movement provides remainder of volume
change (25-40%)

Intercostal and scalene muscles pull ribs upward and
outward

Boyle’s law: as thoracic volume increases, pressure
decreases & air flows into the lungs

Silverthorn, CH17, p581
 Respiratory mechanics: inspiration

Lungs can be expanded in two ways i.e. downward and
upward movement of diaphragm & elevation of ribs

Muscles that raise the rib cage = inspiratory muscles

Inspiratory muscles include:
External intercostals, sternocleidomastoid muscles,
anterior serrati & scalenes

Silverthorn, CH17, p571
 Respiratory mechanics: inspiration
Inspiratory muscles do not act directly on lung, but
change volume of thoracic cavity

Before inspiration, muscles are relaxed & no air flowing

Onset of inspiration the phrenic nerve stimulates
diaphragm to contract, descend downwards; abdominal
muscles bulge outward

Intercostal nerves stimulate external intercostal muscles
to contract – ribs & sternum upwards and outwards

Intra-alveolar pressure (759 mmHg) and intrapleural (754
mmHg) pressure decrease to allow airflow into the lungs

Intercostal and scalene muscles pull ribs upward and
outward
Sherwood, CH13, p453 Transmural pressure gradient ensures lungs stretched to
fill expanded thoracic cavity
 Respiratory mechanics: inspiration
Quiet breathing

Sherwood, CH13, p454 Sherwood, CH13, p453

Deeper inspirations: contract diaphragm & external intercostals more forcefully &
the accessory inspiratory muscles (sternocleidomastoid & scalene)
 Respiratory mechanics: inspiration

Single inspiration:

-at time zero (brief pause between breaths) alveolar
pressure (PA1) is equal to atmospheric pressure
-at time 0-2 sec inspiration takes place
-increased thoracic volume, lowered alveolar
pressure (A2) by 1 mmHg
-air flows into alveoli (refer black, bottom graph: C1
to C2)
-as thoracic volume changes faster than air can flow,
PA reaches lowest value through inspiration (refer
A2)
-air flow continues until pressure equalizes between
PA and atmospheric pressure (refer A3)
-end of inspiration, lung volume at its maximum (C2)
-intrapleural pressure also decreases due to pleural
Silverthorn, CH17, p582 cavity expansion

Note: atmospheric pressure in this example set as 0 mmHg (vs. 760 mmHg) to allow for
easy comparisons without altitude considerations)
 Respiratory mechanics: expiration
Expiration is a passive process during quiet breathing

Inspiratory muscles relax at end of inspiration

Diaphragm returns to dome-shaped position

Elevated rib cage falls due to gravity
(following muscle relaxation)

Chest wall and stretched lungs recoil

Lung comprises elastin fibers that possess
natural recoil tendency

Sherwood, CH13, p454

Normal, resting ventilation rate:
12-20 breaths/min (adult)
 Respiratory mechanics: pneumothorax (collapsed lung)
Knife thrust between ribs punctures pleural
membrane

Atmospheric air flows down pressure gradient
into pleural cavity

Intrapleural and intra-alveolar pressures now
= atmospheric pressure

Transmural pressure gradient no longer exists
across lung and chest walls

Thus no force to stretch the lung & it collapses
to its unstretched state; thoracic wall extends
outwards due to unrestricted dimensions

Silverthorn, CH17, p583 How correct this?
a) remove as much air from pleural cavity
Pneumothorax: ‘’presence of air in the pleural cavity’’ with suction pump
b) sealing hole to present air entering
 Respiratory mechanics: expiration
Expiration is a passive process during quiet breathing
Inspiratory muscles relax at end of inspiration

Diaphragm returns to dome-shaped position

Elevated rib cage falls due to gravity
(following muscle relaxation)

Chest wall and stretched lungs recoil

Lung volumes decreases & PA increases
(Boyle’s law)

Air flows from higher PA to relatively lower
atmospheric pressure

Air flow ceases when PA = atmospheric
Sherwood, CH13, p454 pressure

Normal, resting ventilation rate: PA: alveolar pressure
12-20 breaths/min (adult)
 Respiratory mechanics: active expiration

Exercise or forced heavy breathing, then active
respiration occurs

Intercostal (internal) and abdominal muscles
(expiratory muscles) contract to further increase
intra-alveolar pressure versus atmospheric

Abdominal contraction exerts upward force on
diaphragm, up into thoracic cavity

Intercostal muscles pull ribs downward and
inward to flatten chest wall and decrease
thoracic cavity size

Intrapleural pressure also increases but lungs do
not collapse due to transmural pressure gradient
Sherwood, CH13, p454

Active respiration occurs when ventilation
rate 30-40 breaths/min (adult)
 Respiratory mechanics: expiration

Single expiration:

-at time 2-4 sec expiration takes place
-lung & thoracic volumes decrease
-air pressure in lungs increases (refer A4)
-intrapleural pressure also higher (refer B3)
-alveolar pressure now relatively higher versus
atmospheric pressure & hence air flows out of lungs
-When PA = atmospheric pressure (refer A5), air flow
ceases (refer C3)
-respiratory cycle ended now & ready to begin with
the next breath
PA: alveolar pressure

Silverthorn, CH17, p582

Note: atmospheric pressure in this example set as 0 mmHg (vs. 760 mmHg) to allow for
easy comparisons without altitude considerations)
 Respiratory mechanics: ventilation types
Type Characteristics
Apnea Stops briefly & completely (e.g. during sleep)

Bradypnea Slower than normal (e.g. poisons, injury)

Dyspnea Short of breath, labored

Eupnea Normal breathing

Hyperpnea Breathing more deeply (e.g. exercise)

Hyperventilation Deep & fast, letting more air out (CO2) vs. intake

Hypopnea Partial blockage of air (e.g. when sleeping)

Tachypnea Rapid shallow breathing (e.g. pneumonia)

Pnea: from ancient Greek: ‘’breathing’’
 Respiratory mechanics: lung compliance & elastance

Pulmonary elasticity

Compliance Elastic recoil (elastance)

How much effort to stretch lungs: ΔV/ΔP
-lung volume change (stretch) due to given
change in transmural pressure gradient
-low compliance thus requires larger
transmural pressure gradient (more force)
with inspiration
-greater expansion by thorax via vigorous
contraction of inspiratory muscles (more work)
Sherwood, CH13, p451
-high compliance means it stretches easily
 Respiratory mechanics: lung compliance & elastance

Pulmonary elasticity

Compliance Elastic recoil (elastance)

How much effort to stretch lungs: ΔV/ΔP
-lung volume change (stretch) due to given
change in transmural pressure gradient
-low compliance thus requires larger
transmural pressure gradient (more force)
with inspiration
-greater expansion by thorax via vigorous
contraction of inspiratory muscles (more work)
Sherwood, CH13, p451
-high compliance means it stretches easily
 Respiratory mechanics: lung compliance & elastance

Restrictive lung diseases – decreased
compliance
Respiratory muscles need to work
harder to stretch stiff lung

Example: pulmonary fibrosis
-long-term exposure to pollution
and/or toxins (e.g. asbestos, silicon)
-triggers inflammatory response
-alveolar macrophages secrete factors
-stimulate fibroblasts to synthesize
https://www.mayoclinic.org/diseases-conditions/pulmonary-
inelastic collagen fibers
fibrosis/symptoms-causes/syc-20353690 - can lead to pulmonary hypertension,
right-sided heart failure
 Respiratory mechanics: lung compliance & elastance
Pulmonary elasticity

Compliance Elastic recoil (elastance)

Elastic connective Alveolar surface
tissue tension

Elastance: ability to return to resting volume
when stretching force is released

High compliance lung (stretches easily)
probably lost elastic tissue & wont return to
resting volume when stretching force released
 Respiratory mechanics: lung compliance & elastance

Mice exposed to 6 months of cigarette smoke vs. controls

Emphysema: alveoli wall damage & rupture, decreases lung surface area
Example: smokers
-alveolar macrophages activated to counter-act inhaled irritants
-macrophages secrete elastase enzyme
-elastase breaks down elastin fibers & alveoli lose elastic recoil abilities
-thus expiration becomes a conscious effort
-individuals have more difficulty exhaling vs. inhaling
 Respiratory mechanics: lung compliance & elastance

Pulmonary elasticity

Compliance Elastic recoil (elastance)

Elastic connective Alveolar surface
tissue tension
-major factor
 Respiratory mechanics: lung compliance & elastance
Alveolar surface tension:
-H2O mols more attracted to other H2O mols vs. air at interface
-hydrogen bonding responsible for surface tension of H2O
-such unequal attraction creates a force (surface tension) at
the surface of this liquid
-hydrogen bonding leads to increased cohesiveness of H2O
(‘’clinging’’ together) & makes it difficult to stretch and
deform
-it resists any force that increases its surface area & opposes
alveolus expansion
-thus the greater the surface tension, the less lung compliance
-as H2O mols try get as close to each other as possible, the
liquid surface areas tends to shrink as small as possible
-such surface tension tends to reduce alveolar size squeezing
in on air inside (promotes lung collapse)

Sherwood, CH13, p449 Alveolar surface tension also helps with elastic recoil after
inspiration
 Respiratory mechanics: lung compliance & elastance

Emphysema: alveoli wall damage & rupture, decreases lung surface area
Example: smokers
-alveolar macrophages activated to counter-act inhaled irritants
-macrophages secrete elastase enzyme
-elastase breaks down elastin fibers & alveoli lose elastic recoil abilities
-thus expiration becomes a conscious effort
-individuals have more difficulty exhaling vs. inhaling
-breakdown of alveolar walls leads to decreased alveolar surface tension –
lowered elastic recoil
 Respiratory mechanics: lung compliance & elastance

Silverthorn, CH17, p585
Pierre-Simon Laplace
1749-1827
Alveolar surface tension similar to tension existing in spherical bubble
-alveoli not perfect spheres
-thin film of fluid creates surface tension directed towards center
-creates pressure within interior of bubble
-Law of LaPlace is an expression of this pressure
-note P = inward directed collapsing pressure
-this law means that more work needed to expand smaller alveoli
 Respiratory mechanics: lung compliance & elastance

Silverthorn, CH17, p585
-cohesive force between H2O mols so strong that if alveoli lined with H2O only, surface tension so
great causing lung collapse
-lungs would also be poorly compliant & need exhausting muscular efforts to achieve stretching
and inflation of alveoli
-lungs secrete surfactant (surface active agents) that lowers surface tension
-disrupt cohesive forces by H2O mols by substituting itself for H2O at the surface
-thus pulmonary surfactant decreases the resistance of the lungs to stretch
-pulmonary surfactant decreases surface tension to greater degree in small alveoli
 Respiratory mechanics: lung compliance & elastance

Sodium stearate – anionic surfactant
common in most soaps

http://www.bristol.ac.uk/chemistry/research/
eastoe/what-are-surfactants/ Liu et al. EDIS 2013 (11). https://doi.org/10.32473/edis-hs1230-2013

Pulmonary surfactants:
-amphiphilic (dual-natured) mols
-possess both hydrophobic & hydrophilic mols
-mixture of mostly phospholipids (˃90% by mass); of this 40% = dipalmitoylphosphatidylcholine (DPCC)
-mixture also contains small amount of proteins (Surfactant proteins A, B, C & D)
 Respiratory mechanics: lung compliance & elastance

https://chemistry.stackexchange.com/questions/51759/how-can-proteins-reduce-surface-tension
 Respiratory mechanics: lung compliance & elastance

-alveoli not individual, isolated air sacs
-are complex polyhedral shapes
-interconnected honeycomb of sacs, each
cavity sharing its walls with many others
-thus, changes in one affect surrounding
alveoli, known as ‘’alveolar interdependence’’
-mechanism contributes to elastic recoil &
prevents collapse of alveoli

Thus, alveolar stability (prevention of its
collapse) depends on a) surfactant and b)
alveolar interdependence

https://derangedphysiology.com/main/cicm-primary-exam/required-
reading/respiratory-system/Chapter%20012/structure-and-function-alveolus
 Respiratory mechanics: lung compliance & elastance

Surfactant:

-synthesis usually starts in 25th week of fetal development
-production reaches adequate levels by 34th week of pregnancy
-premature babies without adequate surfactant levels – complication known as
newborn respiratory distress syndrome (NRDS)
-also referred to as hyaline membrane disease
-babies display stiff lungs (low compliance) & alveoli that can collapse when exhale
-need significant energy to expand lungs with each breath
 Respiratory mechanics: lung compliance & elastance

Pulmonary elasticity

Compliance Elastic recoil (elastance)

Lung stability
Elastic connective Alveolar surface
tissue tension
Prevents pulmonary -major factor
Pulmonary Elastic
edema (lowers alveoli
compliance recoil
surface tension)
key functions
Surfactant
Counteracting
forces
Alveolar interdependence X
Tendency for alveoli to collapse

Atelectasis: complete or partial collapse of the entire lung or a lobe(s)
 Respiratory mechanics: lung region ventilation
& perfusion
Ventilation-perfusion ratio

Ventilation rate (V) = tidal volume x respiratory
rate

Perfusion of lungs (Q): total volume of blood reaching
pulmonary capillaries per unit time

V/Q standing upright: much higher in apex (3.3)
versus the base (0.63) of the lung

Thus, ventilation exceeds perfusion in the apex while
perfusion exceeds ventilation in the base

Areas of lung below the heart (e.g. base) display
increased perfusion relative to ventilation due to
gravity

https://quizlet.com/429434680/respiratory-physiology-packet2-flash-
cards/
MBChB I Respiratory Lectures 2024
Gas exchange

Prof. Faadiel Essop
Room 3027, BMRI
Email: [email protected]
 Respiratory mechanics: airway resistance

Flow  P R Pressure gradient/Resistance

Airway diameter (Poiseuille’s law) Length (L) of system
Wider airways have less resistance Resistance (R) Viscosity (Ƞ) of flowing substance
R  Lη r 4
Radius of tubes (r) in system
-length & viscosity = constant
-vessel radius = key determinant of resistance
-90% airway resistance – trachea and bronchi
-they rigid structures with smallest total
cross-sectional area
-such resistance generally constant
Jean Poiseuille
-however, mucus can increase resistance 1797-1869
 Respiratory mechanics: airway resistance

Flow (F)  P R

Insert into
above formula

Thus, very small decreases in the
Klabunde, 2021
radius significantly lowers the flow!
-view the graph from right to left
 Respiratory mechanics: airway resistance

Of note, the number of airways also plays a role in resistance
to air

More airways reduce resistance as there are increased paths
for air to flow into

Thus, although terminal bronchioles possess the smallest
airways (radius), their relatively higher numbers (vs. larger
airways) means that bronchi display a greater total resistance
 Respiratory mechanics: airway resistance

Silverthorn, CH17, p587

Bronchioles are collapsible and can contribute to airway resistance
Bronchoconstriction - increased resistance to airflow; bronchodilation = opposite
-neural control via parasympathetic neurons, cause bronchoconstriction
-no significant sympathetic innervation
-smooth muscle of bronchioles contain β2-receptors for circulating epinephrine effects (bronchodilation)
- paracrine signals play key role
- increased CO2 in exhaled air relaxes bronchiolar smooth muscle (bronchodilation)
-increased histamine release (by mast cells – allergic reactions) leads to bronchoconstriction
 Respiratory mechanics: airway resistance

Bronchiolar smooth muscle is sensitive to local
CO2 levels

More CO2 delivered by blood flow vs. CO2
exhaled, hence local levels rise

Higher local CO2 levels lead to smooth muscle
relaxation & lower airway resistance

Airflow now increased (for same ΔP)

In parallel, greater blood supply means more O2
extracted from alveoli

Local decrease in O2 leads to vasoconstriction of
pulmonary arterioles

Sherwood, CH13, p466 Thus, blood flow decreased to match the airflow
 Respiratory mechanics: airway resistance

The two mechanisms for matching airflow and
blood flow, function concurrently (limited neural
effects)

Hence very little air or blood wasted in the lung

Gravitational effects: differences in ventilation &
perfusion between top and bottom of the lung

Sherwood, CH13, p466
 Respiratory mechanics: alveolar ventilation

Hyperventilation:
Increased alveolar ventilation
Alveolar PO2 increases & alveolar PCO2 decreases

Hypoventilation:
Decreased alveolar ventilation
Less fresh air enters the alveoli
Alveolar PO2 decreases & PCO2 increases

Silverthorn CH17, p590
 Respiratory mechanics: energy requirements

Key factors influencing
work required Decreased compliance work required to
-e.g. pulmonary fibrosis expand the lungs

Compliance Passive expiration
Reduced elastic recoil insufficient
e.g. emphysema -abdominal muscles
work to expel air

Airway resistance Increased airway resistance
 Respiratory mechanics: airway resistance

Chronic obstructive pulmonary disease (COPD): lung diseases characterized by increased
airway resistance (with expiration)- includes chronic bronchitis & emphysema

Chronic bronchitis:
-triggered by frequent exposure to e.g. cigarette smoke, polluted air, allergens
-long-term inflammatory response
-airways become narrow due to thickening of airway linings & increased thick
mucus production
 Respiratory mechanics: airway resistance
“Asthma is a heterogeneous disease, usually characterized by chronic airway
inflammation. It is defined by the history of respiratory symptoms such as wheeze,
shortness of breath, chest tightness and cough that vary over time and in intensity,
together with variable expiratory airflow limitation.”*

Asthma:
-inflammation & histamine induces edema, leading to thickening of airway walls
-excessive secretion of very thick mucus
-smooth muscle spasms (in response to triggers, e.g. allergens, cigarette
smoke, infections) lead to severe constriction of smaller airways

Such airway obstruction usually reversible vs. COPD where it is mainly irreversible &
gets progressively worse

*Asthma definition as stipulated in GINA 2015 report (www.ginasthma.org)
Pulmonary gas exchange & transport

Silverthorn, CH18, p599
 Gas exchange

The body needs oxygen and removes carbon dioxide
Hypoxia – too little oxygen
Hypercapnia – increased concentrations of carbon
dioxide
To avoid hypoxia and hypercapnia, the body responds to
three regulated variables
1. Oxygen
2. Carbon dioxide
3. pH
 Types of hypoxia and some typical causes

Type Definition Typical Causes
Hypoxic hypoxia Low arterial PO High altitude; alveolar hypoventilation; decreased
2
lung diffusion capacity; abnormal ventilation-
perfusion ratio
Anemic hypoxia Decreased total amount of O2 Blood loss; anemia (low [Hb] or altered HbO2
bound to hemoglobin binding); carbon monoxide poisoning
Ischemic hypoxia Reduced blood flow Heart failure (whole-body hypoxia); shock
(peripheral hypoxia); thrombosis (hypoxia in a
single organ)
Histotoxic hypoxia Failure of cells to use O2 Cyanide and other metabolic poisons
because cells have been
poisoned
Normal blood values in pulmonary medicine

Blank Arterial Venous
PO2 95 mm Hg (85–100) 40 mm Hg
PCO2 40 mm Hg (35–45) 46 mm Hg

pH 7.4 (7.38–7.42) 7.37

Respiratory physiologists express plasma gas concentrations
as partial pressures

Oxygen diffuses down partial pressure (concentration)
gradient

Diffusion goes to equilibrium, i.e. PO2 of arterial blood
leaving lungs = that in alveoli (100 mm Hg)

When arterial blood reaches tissue capillaries then gradient
is reversed
 Gas exchange in lungs and tissue
Breathing is bulk flow of air into and out of lungs
Individual gases diffuse along partial pressure gradients until equilibrium
– Total pressure of mixed gas = sum of partial pressures of individual
gases
– Gas exchange between alveoli and blood

PO2 alveolar air  PO2 blood
PCO2 blood  PCO2 alveolar air

Gas exchange between blood and tissues

PO2 blood  PO2 tissue
PCO2 tissue  PCO2 blood
Gases diffuse down concentration gradients

Silverthorn, CH18, p601
 Efficiency of alveolar gas exchange

Influencing variables

Adequate oxygen must Transfer of gases between alveoli Adequate perfusion
reach the alveoli and pulmonary capillaries of alveoli

Hypoxia
Efficiency of alveolar gas exchange

Sherwood, CH13, p470
 Efficiency of alveolar gas exchange

Adequate oxygen must
reach the alveoli

Atmosphere composition altered Atmosphere composition normal
e.g. lower PO2 with a) altitude or but low alveolar ventilation
b) humidity -hypoventilation

Decreased lung compliance
Increased airway resistance
Central nervous system depression
Efficiency of alveolar gas exchange
Influencing variables

Transfer of gases (diffusion) between alveoli
and pulmonary capillaries

Silverthorn, CH18, p602
Diffusion barrier between lung and blood

Silverthorn, CH18, p602
 Diffusion problems can cause hypoxia
Diffusion rate  surface area x concentration gradient x
barrier permeability

Diffusion distance can also be added to this equation
- diffusion rate  1/distance2
- thus, diffusion is most rapid over short distances

Most of time: diffusion distance, surface area & barrier
permeability = constants

Hence, concentration gradient (between alveoli & blood)
is the primary factor affecting gas exchange in
healthy people

Pathology does play a role in some cases, for e.g.:
- decreased alveolar surface area
- increased thickness of alveolar-capillary exchange
barrier
- increased diffusion distance between alveolar air space
& blood Silverthorn, CH18, p602
Pathologies that can cause hypoxia

Silverthorn, CH18, p602
 Pathologies that can cause hypoxia

Pathological changes that adversely affect gas exchange
Surface area
Decrease in amount of alveolar surface area
Emphysema
Diffusion barrier permeability
Increase in thickness of alveolar membrane
Fibrotic lung diseases
Diffusion distance
Increase in diffusion distance between alveoli and
blood
Pulmonary edema
 Diffusion problems can cause hypoxia: gas solubility
Movement of gases is directly proportional to
1) pressure gradient of the gas When temperature is constant, the amount of a gas
that dissolves in a liquid depends on its a) solubility &
2) solubility of the gas in liquid b) partial pressure
3) temperature
If gas pressure is higher in gaseous phase than in water,
then it dissolves into the water (down the pressure
gradient)
At equilibrium, the movement of oxygen from air into
water = movement from oxygen from water back into
the air

Silverthorn, CH18, p604
 Diffusion problems can cause hypoxia: gas solubility
Movement of gases is directly proportional to
1) pressure gradient of the gas When temperature is constant, the amount of a gas
that dissolves in a liquid depends on its a) solubility &
2) solubility of the gas in liquid b) partial pressure
3) temperature
If gas pressure is higher in gaseous phase than in water,
then it dissolves into the water (down the pressure
gradient)
At equilibrium, the movement of oxygen from air into
water = movement from oxygen from water back into
the air
Concentration of oxygen in the water is referred to as
the partial pressure of the gas in solution
Oxygen is not very soluble in water and hence notice
the difference between O2/L for air vs. O2/L for water
(refer [c] in figure)
By contrast, carbon dioxide is 20x more soluble in water
vs. oxygen (refer [d] in figure)

Silverthorn, CH18, p604
 Gas transport in blood

Gas entering capillaries first dissolve in the plasma
– Dissolved gas accounts only for