Zones of pulmonary blood flow

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Zones of pulmonary blood flow

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Airflow, pressure, and resistance
Pulmonary embolism
Pulmonary edema
Pulmonary valve disease
Idiopathic pulmonary fibrosis
Restrictive lung diseases
Respiratory system anatomy and physiology
Regulation of pulmonary blood flow
Lung volumes and capacities
Chronic obstructive pulmonary disease: Clinical sciences
Zones of pulmonary blood flow
Obstructive lung diseases: Pathology review
Apnea, hypoventilation and pulmonary hypertension: Pathology review
Respiratory acidosis
Respiratory alkalosis
Approach to respiratory alkalosis: Clinical sciences
Approach to respiratory acidosis: Clinical sciences
Neonatal respiratory distress syndrome: Clinical sciences
Anatomic and physiologic dead space
Physiological changes during exercise
Guillain-Barré syndrome: Clinical sciences
Aspiration pneumonia and pneumonitis: Clinical sciences
Hypoxia
Sickle cell disease (NORD)
Emphysema
Alpha-thalassemia
Sleep apnea: Clinical sciences
Iron deficiency anemia
Cerebral circulation
Erythropoietin
Intrinsic hemolytic normocytic anemia: Pathology review
Beta-thalassemia
Approach to anemia (underproduction): Clinical sciences
Aplastic anemia
Macrocytic anemia: Pathology review
Autoimmune hemolytic anemia
Iron deficiency anemia: Clinical sciences
Non-hemolytic normocytic anemia: Pathology review
Microcytic anemia: Pathology review
Extrinsic hemolytic normocytic anemia: Pathology review
Anemia of chronic disease
Vitamin B12 deficiency: Clinical sciences
Approach to jaundice (unconjugated hyperbilirubinemia): Clinical sciences
Vitamin B12 deficiency
Consumptive coagulopathy from massive transfusion: Clinical sciences
Pneumothorax
Pulmonary changes at high altitude and altitude sickness
Pleural effusion, pneumothorax, hemothorax and atelectasis: Pathology review
Deep vein thrombosis and pulmonary embolism: Pathology review
Respiratory distress syndrome: Pathology review
Bronchodilators: Beta 2-agonists and muscarinic antagonists
Bronchodilators: Leukotriene antagonists and methylxanthines
Pulmonary corticosteroids and mast cell inhibitors
Alveolar gas equation
Diffusion-limited and perfusion-limited gas exchange
Gas exchange in the lungs, blood and tissues
Alveolar surface tension and surfactant
Carbon dioxide transport in blood
Oxygen binding capacity and oxygen content
Oxygen-hemoglobin dissociation curve
Ventilation-perfusion ratios and V/Q mismatch
Ventilation

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Content Reviewers

Rishi Desai, MD, MPH

Air from the environment enters through the nostrils, goes through the airways, and finally reaches the alveoli, the tiny air-filled sacs in the lungs.

Here, gas is exchanged between the alveoli and blood flowing through the capillaries that surround each alveolus.

And blood flows from the higher pressured arteriole (Pa) to the lower pressured venule (Pv).

Now, PA, which is the pressure within the alveoli of the lungs is relatively constant throughout the lungs.

At the end of expiration, it’s equal to atmospheric pressure, which is 0 centimeters of water (0 cmH2O) And although Pa is always greater than Pv , their values change at different vertical levels within the lungs.

Consider the fact that some blood vessels are more vertical while others are more horizontal. The horizontal ones are unaffected by gravity, but the more vertical ones are affected by gravity.

The analogy would be a cylinder filled with water - the cylinder represents a blood vessel and the water would be the blood.

As you add more and more water, the height (H) of the water increases. And when the column is completely filled, the pressure (P) from the water that’s exerted on the bottom of the cylinder, or the hydrostatic pressure, is equal to the density of water (p) multiplied by gravitational acceleration (g), multiplied by the height of the column of water above it.

Blood in vertical blood vessels in upright lungs have similar hydrostatic effects.

At the apex of the lung, Pa and Pv are relatively low, at the base of the lung, Pa and Pv are relatively high, and in the middle of the lung, Pa and Pv are somewhere in between.

Now because PA is constant, the relationship of Pa and Pv with respect to PA changes. And it’s the relationship between these three that determines the zones of the lungs.

In zone 3, at the base of the lungs, Pa is higher than Pv, and both are higher than PA.

In zone 3, blood flows through the capillaries because of the pressure difference between Pa and Pv.

Key Takeaways

The zones of pulmonary blood flow refer to the three anatomical regions of the lung that differ in their perfusion and ventilation. Zone 1 is the region closest to the apex of the lung where alveolar pressure is highest, and pulmonary blood flow is limited. Zone 2 is the intermediate region where the pulmonary blood flow is determined by the balance between the alveolar pressure and the pulmonary artery pressure. Zone 3 is the region closest to the base of the lung where pulmonary blood flow is the highest due to the high pulmonary artery pressure.

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. "Pulmonary blood flow distribution after banding of pulmonary artery." Heart (1975)
  6. "Regional Pulmonary Blood Flow in Humans and Dogs by 4D Computed Tomography" Academic Radiology (2008)