Structural failures of the blood-gas barrier and the epithelial-epithelial cell connections in the different vascular regions of the lung of the domestic fowl, Gallus gallus variant domesticus, at rest and during exercise

Structural failure of blood-gas barrier (BGB) and epithelial-epithelial cell connections (EECCs) in different vascular regions of the exchange tissue of the lung was studied in rested and exercised chickens. The number of red blood cells (nRBCs) was counted and protein concentration (PC) measured af...

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Published inBiology open Vol. 2; no. 3; pp. 267 - 276
Main Authors Maina, John N, Jimoh, Sikiru A
Format Journal Article
LanguageEnglish
Published England The Company of Biologists Ltd 15.03.2013
The Company of Biologists
Subjects
Birds
Blood plasma
Blood pressure
Blood vessels
Blood–gas barrier
Capillaries
Capillary pressure
Chicken
Chickens
Diameters
Epithelial cells
Epithelium
Erythrocytes
Exercise
Exudation
Failure
Gallus gallus
Heart rate
Hemodynamics
Lactic acid
Lung
Lungs
Pulmonary arteries
Pulmonary artery
Respiratory system
Rest
Structural failure
Treadmills
Workload
Workloads
Rest
Exercise
Lung
Structural failure
Birds
Chicken
Blood–gas barrier
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Summary:Structural failure of blood-gas barrier (BGB) and epithelial-epithelial cell connections (EECCs) in different vascular regions of the exchange tissue of the lung was studied in rested and exercised chickens. The number of red blood cells (nRBCs) was counted and protein concentration (PC) measured after lavaging the respiratory system, and blood was sampled to determine the blood lactate levels (BLLs). The numbers of complete BGB breaks (nBGBBs) and those of the EECCs (nEECCBs) were counted in the different vascular territories of the lung. The nRBCs and the PCs increased with increasing exercise intensities but the rate of increase decreased at higher workloads. From rest to the fastest experimental treadmill speed of 2.95 m.sec(-1), BLLs increased 4-fold. In all cases, the nEECCBs exceeded those of the BGB, showing that structurally the BGB is relatively weaker than the EECC. The increase in the number of breaks with increasing exercise can be attributed to increase in the pulmonary capillary blood pressure (PCBP) from faster heart rates and higher cardiac outputs, while the leveling out of the measurements made at higher workloads may have arisen from hemodynamic changes that initially ensued from exudation of blood plasma and then flow of blood into the air capillaries on failure of the BGB. The relative differences in the nBGBBs and the nEECCBs in the different vascular regions of the lung were ascribed to diameters of the branches and their points of origin and angles of bifurcation from the pulmonary artery. Presence of RBCs in the air capillaries of the lungs of rested chickens showed that failure of the BGB commonly occurs even in healthy and unstressed birds. Rapid repair and/or defense responses, which were observed, may explain how birds cope with mechanical injuries of the BGB.
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ISSN:2046-6390
2046-6390
DOI:10.1242/bio.20133608