Ventilation-perfusion mismatch pathophysiology

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Aida Javanbakht, M.D.

Overview

Any disruption between blood flow and ventilation is called V/Q mismatch.

Pathogenesis

In the upright position of the normal lung, the amount of ventilation and perfusion is higher in the base of the lung compare to apex of the lung^[1]. Although ventilation and perfusion are low in the apex of the lung, the perfusion is lower than ventilation in the apex. So, the V/Q is higher in the apex of the lung compare to the base ^[2]. In a normal lung V/Q is 0.8 which means 4 liters of oxygen and 5 liters of blood transfer in the lung per minute. V/Q mismatch is one of the common reason of hypoxemia in patients with lung disease like obstructive lung diseases, pulmonary vascular diseases, and interstitial diseases . Usually hypoxemia due to V/Q mismatch will resolve by oxygen therapy.^[3]

In normal condition when there is a low ventilation, the body tries to keep this ratio in a normal range by restricting the perfusion in that specific area of the lung. This unique mechanism is called hypoxic pulmonary vasoconstriction. If this process continues for a long time it can cause pulmonary hypertension .

Associated Conditions

Some conditions that cause decrease in V/Q are:^[4] ^[5]

Some conditions that cause increase in V/Q are:

Genetics

The association between V/Q mismatch and genetic depends on the etiology of the mismatch. For example ORMDL3 and GSDML genes play a role in causing asthma .

Gross Pathology

The gross pathology depends on the exact reason for the V/Q mismatch.

Microscopic Pathology

The microscopic pathology depends on the exact reason for the V/Q mismatch. For example in asthma there are extracellular Charcot-Leyden crystals and increased mucosal goblet cells.

↑ Schaffartzik W (October 1994). "[Ventilation-perfusion ratios]". Anaesthesist (in German). 43 (10): 683–97. PMID 7818053.
↑ Petersson J, Glenny RW (October 2014). "Gas exchange and ventilation-perfusion relationships in the lung". Eur. Respir. J. 44 (4): 1023–41. doi:10.1183/09031936.00037014. PMID 25063240.
↑ Baumgardner JE, Hedenstierna G (February 2016). "Ventilation/perfusion distributions revisited". Curr Opin Anaesthesiol. 29 (1): 2–7. doi:10.1097/ACO.0000000000000269. PMID 26545142.
↑ Sarkar M, Niranjan N, Banyal PK (2017). "Mechanisms of hypoxemia". Lung India. 34 (1): 47–60. doi:10.4103/0970-2113.197116. PMC 5234199. PMID 28144061.
↑ Ballester E, Reyes A, Roca J, Guitart R, Wagner PD, Rodriguez-Roisin R (April 1989). "Ventilation-perfusion mismatching in acute severe asthma: effects of salbutamol and 100% oxygen". Thorax. 44 (4): 258–67. PMC 461786. PMID 2763227.

[pmid7818053-1] Schaffartzik W (October 1994). "[Ventilation-perfusion ratios]". Anaesthesist (in German). 43 (10): 683–97. PMID 7818053.

[pmid25063240-2] Petersson J, Glenny RW (October 2014). "Gas exchange and ventilation-perfusion relationships in the lung". Eur. Respir. J. 44 (4): 1023–41. doi:10.1183/09031936.00037014. PMID 25063240.

[pmid26545142-3] Baumgardner JE, Hedenstierna G (February 2016). "Ventilation/perfusion distributions revisited". Curr Opin Anaesthesiol. 29 (1): 2–7. doi:10.1097/ACO.0000000000000269. PMID 26545142.

[pmid28144061-4] Sarkar M, Niranjan N, Banyal PK (2017). "Mechanisms of hypoxemia". Lung India. 34 (1): 47–60. doi:10.4103/0970-2113.197116. PMC 5234199. PMID 28144061.

[pmid2763227-5] Ballester E, Reyes A, Roca J, Guitart R, Wagner PD, Rodriguez-Roisin R (April 1989). "Ventilation-perfusion mismatching in acute severe asthma: effects of salbutamol and 100% oxygen". Thorax. 44 (4): 258–67. PMC 461786. PMID 2763227.

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