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The Bohr equation, named after Danish physician Christian Bohr (1855–1911), describes the amount of physiological dead space in a person's lungs. This is given as a ratio of dead space to tidal volume. It differs from anatomical dead space as measured by Fowler's method as it includes alveolar dead space.

Description

The Bohr equation is used to quantify the ratio of physiological dead space to the total tidal volume, and gives an indication of the extent of wasted ventilation. It is stated as follows:^[1]

${\displaystyle \frac{{\mathbf{V}}_{\mathrm{d}}}{{\mathbf{V}}_{\mathrm{t}}}=\frac{{\mathrm{P}}_{\mathrm{a}}{\mathrm{C}\mathrm{O}}_{\mathrm{2}}-{\mathrm{P}}_{\mathrm{e}}{\mathrm{C}\mathrm{O}}_{\mathrm{2}}}{{\mathrm{P}}_{\mathrm{a}}{\mathrm{C}\mathrm{O}}_{\mathrm{2}}}}$

Derivation

Its derivation is based on the fact that only the ventilated gases involved in gas exchange (${\displaystyle V_a}$) will produce CO₂. Because the Total tidal volume (${\displaystyle V_t}$) is made up of ${\displaystyle V_a+V_d}$ (alveolar volume + dead space volume), we can substitute ${\displaystyle V_a}$ for ${\displaystyle V_t-V_d}$.

Initially, Bohr tells us Vt = Vd + Va. The Bohr equation helps us find the amount of any expired gas, Template:CO2, N₂, O₂, etc. In this case we will focus on Template:CO2. Defining Fe as the fraction of expired Template:CO2 and Fa as the fraction of expired alveolar Template:CO2, and Fd as fraction of expired dead space volume Template:CO2, we can say
Vt x Fe = ( Vd x Fd ) + (Va x Fa ). This merely means all the Template:CO2 expired comes from two parts, the dead space volume and the alveolar volume.
If we suppose that Fd = 0 (since carbon dioxide concentration in air is normally negligible), then we can say that:^[2]

${\displaystyle V_t\times F_e=V_a\times F_a}$ Where F_e = Fraction expired CO₂, and Fa = Alveolar fraction of CO₂.

${\displaystyle V_t\times F_e=(V_t-V_d)\times F_a}$ Substituted as above.

${\displaystyle V_t\times F_e=V_t\times F_a-V_d\times F_a}$ Multiply out of the brackets.

${\displaystyle V_d\times F_a=V_t\times F_a-V_t\times F_e}$ Rearrange.

${\displaystyle V_d\times F_a=V_t\times (F_a-F_e)}$

${\displaystyle V_d/V_t=\frac{F_a-F_e}{F_a}}$ Divide by V_t and by F_a.

The above equation makes sense because it describes the total Template:CO2 being measured by the spirometer. The only source of the Template:CO2 we are assuming to measure is from the alveolar space where Template:CO2 and O₂ exchange takes place. Thus alveolar's fractional component, F_a, will always be higher than the total Template:CO2 content of the expired air, F_e, thus we will be always yielding a positive number.

Where Ptot is the total pressure, we obtain:

• ${\displaystyle F_a\times Ptot=PaC{O}_2}$ and
• ${\displaystyle F_e\times Ptot=PeC{O}_2}$

Therefore:

${\displaystyle V_d/V_t=\frac{FaC{O}_2-FeC{O}_2}{FaC{O}_2}\times \frac{Ptot}{Ptot}}$

This is simplified as:

${\displaystyle V_d/V_t=\frac{PaC{O}_2-PeC{O}_2}{PaC{O}_2}}$

References

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