Major differences in the pulmonary circulation between birds and mammals

West, John B.; Watson, Rebecca R.; Fu, Zhenxing

doi:10.1016/j.resp.2006.12.005

Cited by 50 publications

(37 citation statements)

References 28 publications

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“…A little later, Powell et al (1985) showed that in contrast to the mammalian lung, where the pulmonary vascular resistance (PVR) decreases as cardiac output increases, owing mainly to the distension and recruitment of the BCs (Borst et al 1956;Glazier et al 1969), in the avian lung, PVR doubled after ligation (occlusion) of the left pulmonary artery, an experimental procedure that doubled the flow of blood to the right lung: the investigators concluded that 'the BCs are noncompliant'. The exceptional strength of the ACs and the BCs has now been corroborated by other investigators (Wideman, 2001;West et al 2006West et al , 2007aWideman et al 2007;Watson et al 2008). West et al (2007a) and Watson et al (2008) observed that 'the avian pulmonary BCs behave like rigid tubes that defy either expansion or compression'.…”

Section: Introductionmentioning

confidence: 57%

“…Although accounts on the remarkable strengths of the ACs and the blood capillaries (BCs) of the avian lung have been in the scientific domain for about three decades (Macklem et al 1979;Powell et al 1985), until recently, only cursory references and speculations existed on this interesting property, which has now been sufficiently corroborated by, for example, Wideman (2001), West et al (2007a), and Watson et al (2008). The particular structures and ⁄ or mechanisms that can explain this property have remained obscure and contentious.…”

Section: Discussionmentioning

confidence: 99%

“…The particular structures and ⁄ or mechanisms that can explain this property have remained obscure and contentious. Klika et al (1997), Scheuermann et al (1997), West et al (2006West et al ( , 2007a, and Watson et al (2007Watson et al ( , 2008 ascribed the strength to the presence of what they termed 'retinacula', 'cross-braces', 'struts', 'plates', 'extensions', and 'cross-bridges', pairs of thin parallel epithelial cell processes that separate the ACs while connecting the BCs; Klika et al (1997) Figs 10-18 (Fig. 10) Collagen fibers of the atrial septa (star) connecting to the infundibula ones (arrows) which in turn connect to the very thin collagen fibers of the exchange tissue (dot).…”

Section: Discussionmentioning

confidence: 99%

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

2010

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To identify the forces that may exist in the parabronchus of the avian lung and that which may explain the reported strengths of the terminal respiratory units, the air capillaries and the blood capillaries, the arrangement of the parabronchial collagen fibers (CF) of the lung of the domestic fowl, Gallus gallus variant domesticus was investigated by discriminatory staining, selective alkali digestion, and vascular casting followed by alkali digestion. On the luminal circumference, the atrial and the infundibular CF are directly connected to the smooth muscle fibers and the elastic tissue fibers. The CF in this part of the parabronchus form the internal column (the axial scaffold), whereas the CF in the interparabronchial septa and those associated with the walls of the interparabronchial blood vessels form the external, i.e. the peripheral, parabronchial CF scaffold. Thin CF penetrate the exchange tissue directly from the interparabronchial septa and indirectly by accompanying the intraparabronchial blood vessels. Forming a dense network that supports the air and blood capillaries, the CF weave through the exchange tissue. The exchange tissue, specifically the air and blood capillaries, is effectively suspended between CF pillars by an intricate system of thin CF, elastic and smooth muscle fibers. The CF course through the basement membranes of the walls of the blood and air capillaries. Based on the architecture of the smooth muscle fibers, the CF, the elastic muscle fibers, and structures like the interparabronchial septa and their associated blood vessels, it is envisaged that dynamic tensional, resistive, and compressive forces exist in the parabronchus, forming a tensegrity (tension integrity) system that gives the lung rigidity while strengthening the air and blood capillaries.

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Section: Introductionmentioning

confidence: 57%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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

2010

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“…contribute to and explain the exceptional strength that has been reported in the avian lung by Macklem et al (1979), Powell et al (1985), and West et al (2007). The structural proximity between the lungs of the Ostrich, a bird from a taxon (ratite) considered to be the most primitive among birds (King and Farner, 1969;Storer, 1971a,b;Calder and Dawson, 1978), with those of the passerine birds (the most derived avian taxon) (Sibley and Alhquist, 1990;Barker et al, 2004), shows exceptional respiratory refinements for a nonvolant, supposedly primitive bird.…”

Section: Computer Reconstruction Of Parabronchus Of Ostrichmentioning

confidence: 81%

Three‐Dimensional Serial Section Computer Reconstruction of the Arrangement of the Structural Components of the Parabronchus of the Ostrich, Struthio Camelus Lung

Maina

Woodward

2009

The Anatomical Record

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The Ostrich, Struthio camelus is the largest extant bird. The arrangement of the airway and the vascular components of the parabronchus of its lung were investigated by 3D serial section reconstruction. Modestly developed atrial muscles, shallow atria, paucity of infundibulae with preponderant origination of the air capillaries (ACs) from the atria and lack of interparabronchial septa, structural features that epitomize lungs of most highly derived metabolically active volant birds were observed. Intertwined very closely, the ACs and the blood capillaries (BCs) are not straight, blindended tubules that run in contact, counter and parallel to each other as has been claimed and/or modeled. Crosscurrent (perpendicular ¼ orthogonal) orientation between the centripetal (inward) flow of the venous blood (VB) from the periphery of the parabronchus and the flow of air in the parabronchial lumen occur. Also, a countercurrent-like arrangement between the ACs which convey air centrifugally (outwards ¼ radially) and the BCs that transport venous blood centripetally (inwards) was identified. The VB is conveyed to the parabronchus by the interparabronchial arteries and delivered to the exchange tissue by the intraparabronchial arterioles: it is then arterialized at the infinitely many points where the ACs and the BCs contact. Functionally, the crosscurrent arrangement grants a multicapillary serial arterialization arrangement which extends the time that the respiratory media, air and blood, are exposed to each other. The contribution that the countercurrent-like arrangement makes to the gas exchange process remains obscure.

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“…The pulmonary circulation receives the entire cardiac output but has a pressure approximately onefifth that of the systemic circulation, a figure that is remarkably consistent across mammalian species. 9 The relation- Figure 1. Morphological changes in an athlete's heart compared with a nonathlete's heart.…”

Section: Introductionmentioning

confidence: 99%

The Response of the Pulmonary Circulation and Right Ventricle to Exercise: Exercise‐Induced Right Ventricular Dysfunction and Structural Remodeling in Endurance Athletes (2013 Grover Conference Series)

2014

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There is unequivocal evidence that exercise results in considerable health benefits. These are the result of positive hormonal, metabolic, neuronal, and structural changes brought about by the intermittent physiological challenge of exercise. However, there is evolving evidence that intense exercise may place disproportionate physiological stress on the right ventricle (RV) and the pulmonary circulation. Both echocardiographic and invasive studies are consistent in demonstrating that pulmonary arterial pressures increase progressively with exercise intensity, such that the harder one exercises, the greater the load on the RV. This disproportionate load can result in fatigue or damage of the RV if the intensity and duration of exercise is sufficiently prolonged. This is distinctly different from the load imposed by exercise on the left ventricle (LV), which is moderated by a greater capacity for reductions in systemic afterload. Finally, given the increasing RV demand during exercise, it may be hypothesized that chronic exercise-induced cardiac remodeling (the so-called athlete's heart) may also disproportionately affect the RV. Indeed, there is evidence, although somewhat inconsistent, that RV volume increases may be relatively greater than those for the LV. Perhaps more importantly, there is a suggestion that chronic endurance exercise may cause electrical remodeling, predisposing some athletes to serious arrhythmias originating from the RV. Thus, a relatively consistent picture is emerging of acute stress, prolonged fatigue, and long-term remodeling, which all disproportionately affect the RV. Thus, we contend that the RV should be considered a potential Achilles' heel of the exercising heart.

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Major differences in the pulmonary circulation between birds and mammals

Cited by 50 publications

References 28 publications

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

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

Three‐Dimensional Serial Section Computer Reconstruction of the Arrangement of the Structural Components of the Parabronchus of the Ostrich, Struthio Camelus Lung

The Response of the Pulmonary Circulation and Right Ventricle to Exercise: Exercise‐Induced Right Ventricular Dysfunction and Structural Remodeling in Endurance Athletes (2013 Grover Conference Series)

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