Implicit mechanistic role of the collagen, smooth muscle, and elastic tissue components in strengthening the air and blood capillaries of the avian lung

Maina, John N.; Jimoh, Sikiru A.; Hosie, Margo

doi:10.1111/j.1469-7580.2010.01279.x

Cited by 25 publications

(22 citation statements)

References 71 publications

(125 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…After comparing the strengths (stress tolerance) of the blood capillaries in the rabbit lungs, the dog lungs, and the horse lungs, Birks et al observed that stress failure may correlate with the thickness of the BGB (Birks et al, 1994), a property consistent with Laplace's relationship which states that wall stress is proportional to capillary radius but inversely proportional to wall thickness. We have demonstrated collagen fibers in the basement membrane of the BGB and the EECCs of the lung of the chicken (Maina et al, 2010) and immunolocalized type-IV collagen (Jimoh and Maina, 2013), a protein family of triple helical isoforms that form strong two-dimensional planar network of fibers (Timpl, 1989; Hudson et al, 1993; West, 2009), in the exchange tissue of the lung of the domestic fowl. The strength of the BGB of the mammalian lung has been attributed to presence of type-IV collagen in the basement membrane (Crouch et al, 1997; West and Mathieu-Costello, 1999; Maina and West, 2005; West, 2009).…”

Section: Discussionmentioning

confidence: 99%

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

Maina

Jimoh

2013

Biology Open

Self Cite

View full text Add to dashboard Cite

SummaryStructural 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.

show abstract

Section: Discussionmentioning

confidence: 99%

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

Maina

Jimoh

2013

Biology Open

Self Cite

View full text Add to dashboard Cite

show abstract

“…Inspired by nature, we are working towards the goal of building a platform analogous to the natural lung, a modular gas exchange system that has a low footprint, high-selectivity, and requires little energy. [ 16 ] Many methods have been developed to create vascular structures in soft materials for self-healing materials, tissue-growth, and autonomic cooling. [ 31 ] We have recently demonstrated the synthesis of biomimetic gas exchange units capable of capturing CO 2 .…”

Section: Introductionmentioning

confidence: 99%

The Effect of Membrane Thickness on a Microvascular Gas Exchange Unit

Nguyen¹,

Leho²,

Esser‐Kahn³

2012

Adv Funct Materials

View full text Add to dashboard Cite

For reducing anthropogenic CO2 emissions, carbon capture and sequestration technologies benefit from the creation of new and efficient gas exchange systems. Vascularized systems provide a means of exchanging CO2 by providing high specific surface areas and patterned, intimate contact between capture fluids and gases. The well‐defined geometrical arrangement of fluid and gas channels, separated by semipermeable membranes, also provides a new platform for augmenting the function of liquid chemical solutions to carbon capture. In particular, the separation distance of the channels, or polymer membrane thickness, is closely related to the absorption rate as gases must permeate through the membrane before reacting with a fluid. Here, a study of the relationship between the membrane thickness in 3D microvascular contactors and absorption rates via a selective etching process is reported. By decreasing the membrane thickness, the mass transport rate of CO2 in the vascular contactor is increased by up to 160%.

show abstract

“…T-IVc is a distinctively high tensile strength, non-fibrillar, particularly molecularly well-organized form of collagen [22]. The T-IVc localized here in the BMs of the BGB and the E-ECCs, together with other possible forms of collagen, connects to the peripheral and the central parabronchial 'pillars' of CFs [13], with the gas ET being effectively 'suspended' between the 'columns'. A closely related family of proteins with similar amino acid sequences and similar chemical and physical properties [33], collagens, form 20 per cent of the total protein in mammals [34] and supporting cells [35].…”

Section: Discussionmentioning

confidence: 93%

“…Here, we noted that T-IVc exists within the relatively much thinner and less conspicuous BM of the E-ECCs and the epithelial cells connect periodically. The E-ECCs appear to form a part of an integrated support system of the avian lung [13], directly strengthening the ACs and indirectly strengthening the BCs. This study was funded by the National Research Foundation (NRF) of South Africa.…”

Section: Discussionmentioning

confidence: 99%

Immuno-localization of type-IV collagen in the blood-gas barrier and the epithelial–epithelial cell connections of the avian lung

Jimoh

Maina

2013

Biol. Lett.

View full text Add to dashboard Cite

The terminal respiratory units of the gas exchange tissue of the avian lung, the air capillaries (ACs) and the blood capillaries (BCs), are small and rigid: the basis of this mechanical feature has been highly contentious. Because the strength of the blood-gas barrier (BGB) of the mammalian lung has been attributed to the presence of type-IV collagen (T-IVc), localization of T-IVc in the basement membranes (BM) of the BGB and the epithelial-epithelial cell connections (E-ECCs) of the exchange tissue of the lung of the avian (chicken) lung was performed in order to determine whether it may likewise contribute to the strength of the BGB. T-IVc was localized in both the BM and the E-ECCs. As part of an integrated fibroskeletal scaffold on the lung, T-IVc may directly contribute to the strengths of the ACs and the BCs.

show abstract

Implicit mechanistic role of the collagen, smooth muscle, and elastic tissue components in strengthening the air and blood capillaries of the avian lung

Cited by 25 publications

References 71 publications

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 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

The Effect of Membrane Thickness on a Microvascular Gas Exchange Unit

Immuno-localization of type-IV collagen in the blood-gas barrier and the epithelial–epithelial cell connections of the avian lung

Contact Info

Product

Resources

About