7.2: Fick's Law of Diffusion

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Fick's law of diffusion (Equation \ref{6.3}) describes all the factors that influence the transfer of gas (or flow, V) across a membrane.

\[\dot{\mathrm{V}} \propto \frac{\mathrm{A}}{\mathrm{T}} \cdot \mathrm{D} \cdot\left(\mathrm{P}_{1}-\mathrm{P}_{2}\right) \label{6.3} \]

We will look at each factor in the equation and see how it relates to the physiology of the lung.

Pressure gradient (P₁−P₂): The higher the pressure gradient, the greater the transfer of gas, and the pressure gradient must be maintained for gas exchange to continue. The maintenance of the gradient is achieved by adequate ventilation to the alveolus to refresh the alveolar gases, and adequate perfusion to flush oxygen away from the gas exchange surface and supply more CO₂. We will look at the importance of matching ventilation and perfusion in chapter 13.

Other factors in Fick's law are fairly obvious and are reflected in the lung’s structure.

Surface area (A): The greater the surface area available for exchange, the greater the exchange. The lung has a surface area of 100 m², which is more than adequate to maintain sufficient gas transfer, even during maximal exercise.

Membrane thickness (T): The thickness of the membrane that gas has to cross also determines the rate of transfer; the thinner the membrane, the more rapid the transfer. The gas exchange membrane in the lung is approximately a 0.3 um thick—and poses little opposition to gas movement.

Diffusion constant (D): The last variable is the diffusion constant of the gases in question, which for us are O₂ and CO₂. The important issue here is that CO₂ is much more soluble (x 20) than O₂ and so has a much greater diffusion constant; hence it transfers across the membrane much more readily and does not need the large pressure gradient like the relatively insoluble oxygen (5 mmHg compared with 60 mmHg).

Some of these factors can change in lung disease and can result in decreased gas exchange and so result in deranged blood gases. Loss of surface area occurs in diseases, such as emphysema, that destroy the lung architecture, and cause a loss of gas transfer. Likewise, any disease that causes thickening of the alveolar membrane, such as pulmonary fibrosis, increases the distance for, and resistance to, gas transfer. If ventilation or perfusion of the gas exchange surface fails—for example, a mucus plug blocking an airway or a pulmonary embolus blocking a vessel—then the pressure gradient across the membrane is lost and gas exchange is reduced compared to the ideal situation of ventilation and perfusion being matched.

Summary

So after this chapter you should be able to calculate the alveolar partial pressure of a gas at any atmospheric pressure and relate it to the rate of gas exchange.

You should also now understand the different factors that contribute to the rate of gas exchange described in Fick’s law of diffusion and be able to appreciate how they might change in disease.

References, Resources, and Further Reading

Text

Levitsky, Michael G. "Chapter 6: Diffusion of Gases and Interpretation of Pulmonary Function Tests." In Pulmonary Physiology, 9th ed. New York: McGraw Hill Education, 2018.

West, John B. "Chapter 3: Diffusion—How Gas Gets Across the Blood–Gas Barrier." In Respiratory Physiology: The Essentials, 9th ed. Philadelphia: Wolters Kluwer Health/Lippincott Williams and Wilkins, 2012.

Widdicombe, John G., and Andrew S. Davis. "Chapter 4." In Respiratory Physiology. Baltimore: University Park Press, 1983.

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