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Ventilation-perfusion ratios and V/Q mismatch
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Physiology

Respiratory system

Anatomy and physiology
Respiratory system anatomy and physiology
Reading a chest X-ray
Lung volumes and capacities
Lung volumes and capacities
Anatomic and physiologic dead space
Breathing mechanics
Alveolar surface tension and surfactant
Compliance of lungs and chest wall
Combined pressure-volume curves for the lung and chest wall
Ventilation and perfusion
Ventilation
Zones of pulmonary blood flow
Regulation of pulmonary blood flow
Pulmonary shunts
Ventilation-perfusion ratios and V/Q mismatch
Airflow and gas exchange
Breathing cycle
Breathing cycle and regulation
Airflow, pressure, and resistance
Ideal (general) gas law
Boyle's law
Dalton's law
Henry's law
Graham's law
Fick's laws of diffusion
Gas exchange in the lungs, blood and tissues
Diffusion-limited and perfusion-limited gas exchange
Alveolar gas equation
Gas transport
Oxygen binding capacity and oxygen content
Oxygen-hemoglobin dissociation curve
Carbon dioxide transport in blood
Regulation of breathing
Breathing control
Pulmonary chemoreceptors and mechanoreceptors
Physiologic adaptations of the respiratory system
Pulmonary changes at high altitude and altitude sickness
Pulmonary changes during exercise

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Ventilation-perfusion ratios and V/Q mismatch

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Ventilation-perfusion ratios and V/Q mismatch

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A 2-year-old boy is brought to the emergency department by his mother after swallowing a small toy. Imaging is performed, revealing the toy is lodged within the right middle lobe bronchus. The patient’s partial pressure of arterial oxygen (PaO2) is 75 mmHg. Which of the following best characterizes the V/Q ratio in the affected portions of the lung and the effect that 100% supplemental oxygen administration would have on the patient’s PaO2?  

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Content Reviewers:

Rishi Desai, MD, MPH

Contributors:

Justin Ling, MD, MS, Gil McIntire

Alveolar ventilation (V) is the amount of air that reaches alveoli in the lungs, measured in liters/minute (L/min); and perfusion (Q) is the pulmonary blood flow, or cardiac output, that reaches the arteries, and specifically the capillaries, surrounding the alveoli, also measured in L/min.

When the lungs are upright and at rest, ventilation is about 4 L/min and perfusion is about 5 L/min, giving a ratio of 0.8.

Now, the lungs can be divided into three distinct zones.

Zone 1 is the top of the lungs, or the apexes; zone 2 is the middle of the lungs; and zone 3 is the bottom, or bases, of the lungs.

In an upright position, gravity dramatically affects both ventilation and perfusion across all three zones, and overall the V/Q ratio progressively decreases from zone 1 to zone 2 and finally to zone 3.

In zone 1, the flow of air and blood is the lowest with ventilation of around 0.25 L/min, and perfusion of around 0.07 L/min; generating a V/Q ratio of 3.6.

In zone 2, ventilation is equal to perfusion; generating a V/Q ratio of about 1.

In zone 3, the flow of air and blood is the highest with ventilation of around 0.8 L/min, and perfusion of around 1.3 L/min; generating a V/Q ratio of 0.6.

So the V/Q ratio varies depending on which part of the lung is involved, but the overall ratio is an average of the three zones and works out to be 0.8.

Now, the ratio of V to Q influences how efficiently gases, specifically O2 and CO2 , are exchanged in the lungs.

In healthy lungs with a V/Q ratio of 0.8, the alveolar partial pressure of O2 (PAO2), is about 100 mmHg or millimeters of mercury; and the alveolar partial pressure of CO2 (PACO2) is about 40 mmHg.

Meanwhile, the arterial partial pressure of O2 (PaO2) is around 95 mmHg - slightly lower than what’s on the alveolar side; and the arterial partial pressure of CO2 (PaCO2) is about 40 mmHg - the same as what’s on the alveolar side.

But these partial pressures are also an average over the the three lung zones.

In zone 1 the arterial partial pressure of O2 (PaO2) is 130 mmHg and arterial partial pressure of CO2 (PaCO2) is 28 mmHg.

In Zone 2 the arterial partial pressure of O2 (PaO2) is about 108 mmHg and arterial partial pressure of CO2 (PaCO2) is about 39 mmHg.

And in zone 3, the arterial partial pressure of O2 (PaO2) is 88 mmHg and arterial partial pressure of CO2 (PaCO2) is 42 mmHg.

So, a drop of blood in zone 1 gets more oxygen diffused into it than a drop of blood in zone 3, but because zone 3 has about 19 times more blood flowing through per minute, it ends up accounting for more of the overall gas exchange.

Summary

Ventilation-perfusion (V/Q) ratio is a measure of the relationship between the amount of air entering the alveoli (V) and the amount of blood flowing through the capillaries surrounding the alveoli in the lungs (Q). V/Q mismatch is a condition that occurs when this ratio is not properly matched resulting in ventilation-perfusion mismatch or dead space ventilation. V/Q mismatch can be caused by various factors, such as lung conditions like pulmonary embolism, asthma, COPD, and interstitial lung diseases.

Sources
  1. "Medical Physiology" Elsevier (2016)
  2. "Physiology" Elsevier (2017)
  3. "Human Anatomy & Physiology" Pearson (2018)
  4. "Principles of Anatomy and Physiology" Wiley (2014)
  5. "Physiologic Factors Influencing the Arterial-To-End-Tidal CO2 Difference and the Alveolar Dead Space Fraction in Spontaneously Breathing Anesthetised Horses" Frontiers in Veterinary Science (2018)
  6. "Detection of Lung Dysfunction Using Ventilation and Perfusion SPECT in a Mouse Model of Chronic Cigarette Smoke Exposure" Journal of Nuclear Medicine (2013)