Class notes

CTB 3: Ventilation and gas transport

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Course
Cardiovascular and thoracic biology

Institution
Imperial College London (ICL)

Lecture notes from Imperial College London, Medical Biosciences BSc, 2nd year, cardiovascular and thoracic biology (CTB) module. Lecture 3 on ventilation and gas transport: fundamental processes required to achieve effective breathing and gas transport. These processes enable oxygen to get from ...

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Uploaded on September 27, 2023
Number of pages 6
Written in 2022/2023
Type Class notes
Professor(s) Duncan rogers
Contains All classes

cardiology
cardiovascular
thoracic
cardiothoracic
biology
ventilation
lungs
airways
gas
transport
oxygen
breathing
cells
aerobic
anaerobic
carbon dioxide
energy
gases
tissue
volume
capacity
dead space

Institution
Imperial College London (ICL)
Education Unknown
Course
Cardiovascular and thoracic biology

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Cardiovascular and Thoracic biology Imperial College London

$ 93.21 $ 55.08 9 items

1. Class notes - Ctb 10: step into the future
2. Class notes - Ctb 8: anaphylaxis: a cardiovascular-respiratory problem
3. Class notes - Ctb 2: mechanical and electrical properties of the heart
4. Class notes - Cbt 4:blood pressure and flow
5. Class notes - Ctb 6: cell biology of the respiratory tract
6. Class notes - Cbt 7: cell biology of the cardiovascular system
7. Class notes - Ctb 5: assessing performance of the cardiopulmonary system
8. Class notes - Ctb 3: ventilation and gas transport
9. Class notes - Ctb 9: respiratory and cardiovascular diseases
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Ventilation & Gas transport
Volume, capacities and dead space
- lung volumes (don’t overlap):
=> Tidal volume (TV/ VT): air inspired + expired during regular breathing (not always at rest)
=> Inspiratory reserve volume (IRV): max air that can be inspired after a tidal respiration
=> Expiratory reserve volume (ERV): max air that can be expired after a tidal respiration
=> Residual volume (RV): air that can’t be emptied from the lungs (fixed)

vary according to height,
age, genetics, disease...

- total lung capacity (TLC) = RV + IRV + TV + ERV
- functional residual capacity (FRC) = RV + ERV
=> volume in the lungs following a tidal respiration (lung recoil + chest recoil at equilibrium)
- inspiratory capacity (IC) = TV + IRV
=> max volume lungs can draw in from the equilibrium FRC point
- vital capacity (VC) = TLC - RV = TV + IRV + ERV
=> volume between the max and min achievable volumes

- dead space (VD) = parts of the airways that don’t participate in gas exchange
=> anatomical dead space: conducting airways + upper respiratory tract
=> alveolar dead space: respiratory tissues unable to exchange gas (inadequate blood flow)
=> 0 in healthy ppl
=> physiological dead space = anatomical + alveolar

, Rq: a 10m snorkel would
create too much additional
dead space to allow gas
exchange (if narrow, too much
resistance)

Ventilation
- pulmonary ventilation (VE) = TV*Rf (breathing frequency) in mL/min: 500(mL)*15(breaths/ min)
=> amount of air moving into and out of the lungs per min
- alveolar ventilation (Valv) = (TV - VD)*Rf
=> amount of air per minute reaching the gas exchange surface

- each generation down the airway: 50% pressure + velocity (constant generational divergence)

- generate airflow by distorting the lungs equilibrium:

:
=> pressure outside lungs: positive-pressure breathing (on a ventilator)
=> pressure inside: negative-pressure breathing (normal): inspiration normalises from -8 to -5
=> diaphragm contracts downward + external intercostal muscles pull rib cage outwards &
upwards - intrathoracic pressure - lung stretch to fill space - suck air from outside
- breath out: chest wall force decreases + lung recoil inwards => lungs empty
(waste brought by capillaries + move
into alveolar sacs to be breathed out)

Cumulative
cross-sectional
area increases

- Poiseuille’s law: airway resistance = 8 η l / π (r)^4
with η = viscosity; l = length of tube; r = radius
- at first, resistance inversely proportional to r^4 BUT
after decreases according to constant generational
divergence in the airways

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