Pivotal debates and controversies on the structure and function of the avian respiratory system: setting the record straight

Maina, John N.

doi:10.1111/brv.12292

Cited by 24 publications

(24 citation statements)

References 265 publications

(367 reference statements)

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“…Additionally, the majority of the quantitative metrics obtained from the bronchial tree in the alligators were collected from the proximal portion which is cartilaginous in nature (CVB, L, D2–3 and associated PB measures) and the avian bronchial tree is immobilized and thus less flexible than other pulmonary tissues (e.g. Maina, 2006b; Maina, 2017).…”

Section: Methodsmentioning

confidence: 99%

Anatomy, ontogeny, and evolution of the archosaurian respiratory system: A case study on Alligator mississippiensis and Struthio camelus

et al. 2020

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The avian lung is highly specialized and is both functionally and morphologically distinct from that of their closest extant relatives, the crocodilians. It is highly partitioned, with a unidirectionally ventilated and immobilized gas‐exchanging lung, and functionally decoupled, compliant, poorly vascularized ventilatory air‐sacs. To understand the evolutionary history of the archosaurian respiratory system, it is essential to determine which anatomical characteristics are shared between birds and crocodilians and the role these shared traits play in their respective respiratory biology. To begin to address this larger question, we examined the anatomy of the lung and bronchial tree of 10 American alligators (Alligator mississippiensis) and 11 ostriches (Struthio camelus) across an ontogenetic series using traditional and micro‐computed tomography (µCT), three‐dimensional (3D) digital models, and morphometry. Intraspecific variation and left to right asymmetry were present in certain aspects of the bronchial tree of both taxa but was particularly evident in the cardiac (medial) region of the lungs of alligators and the caudal aspect of the bronchial tree in both species. The cross‐sectional area of the primary bronchus at the level of the major secondary airways and cross‐sectional area of ostia scaled either isometrically or negatively allometrically in alligators and isometrically or positively allometrically in ostriches with respect to body mass. Of 15 lung metrics, five were significantly different between the alligator and ostrich, suggesting that these aspects of the lung are more interspecifically plastic in archosaurs. One metric, the distances between the carina and each of the major secondary airways, had minimal intraspecific or ontogenetic variation in both alligators and ostriches, and thus may be a conserved trait in both taxa. In contrast to previous descriptions, the 3D digital models and CT scan data demonstrate that the pulmonary diverticula pneumatize the axial skeleton of the ostrich directly from the gas‐exchanging pulmonary tissues instead of the air sacs. Global and specific comparisons between the bronchial topography of the alligator and ostrich reveal multiple possible homologies, suggesting that certain structural aspects of the bronchial tree are likely conserved across Archosauria, and may have been present in the ancestral archosaurian lung.

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Section: Methodsmentioning

confidence: 99%

Anatomy, ontogeny, and evolution of the archosaurian respiratory system: A case study on Alligator mississippiensis and Struthio camelus

et al. 2020

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“…For example, gas flow through the paleopulmonic parabronchi is unidirectional, but it is believed to be tidal within neo-pulmonic parabronchi (Weidner W, 2011). Similarly, pulmonary capillary blood flows perpendicularly to gas flow within the parabronchi but it runs directly counter to gas flow within the air capillaries (Maina J, 2017). Whether the resulting gas exchange is best described as cross-current, counter-current, or a mixture of both, was debated at length in earlier literature (Scheid P, et al, 1972).…”

Section: Discussionmentioning

confidence: 99%

“…Given these similarities, this study argues that lessons learned from over 150 years of research into the physiology of high altitude in humans have relevance for the understanding of the adaptation to hypobaric hypoxia in birds -particularly in the application of the alveolar gas equation (AGE) to birds. The basic hypothesis of this paper is that the long-standing theory of avian gas exchange based on multicapillary serial arterialization (Maina J, 2017), is incorrect because it does not include the effect of CO2 at the level of gas exchange.…”

Section: Evangelista Torricelli 1644mentioning

confidence: 99%

The alveolar gas equation: do lessons from WW2 research into high flying pilots provide insights into the adaptation to high altitude flight in birds?

Seear

2020

Preprint

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Dalton's law of partial pressures applies equally to birds and mammals so, as gas moves from the nostrils to the smallest gas-diffusion airways, the sequential addition of water vapour and CO2, steadily reduce the partial pressure of O2 (PO2) within the gas mixture. The PO2, at the point of gas exchange, at sea level, will be about 60 mm Hg less than the original PO2 within atmospheric air. As a result, the inspired PO2 is an inaccurate starting point for any model of oxygen transport. In humans, the interactions of gases at the point of diffusion, is described and quantified by the Alveolar Gas Equation (AGE). Its development during WW2, provided valuable insights into human gas exchange and also into the responses to high altitude flight in pilots but, except for an early study of hypoxia in pigeons, the AGE is not mentioned in the avian literature. Even detailed models of oxygen transport in birds omit the effect of CO2 clearance on pulmonary oxygen transfer. This paper develops two related arguments concerning the application of the AGE to birds. The first is that avian blood gas predictions, based on the theory of multicapillary serial arterialization (MSA), are inaccurate because they do not account for the added partial pressure of diffused CO2. The second is that the primary adaptation to hypobaric hypoxia is the same for both classes and consists of defending PaO2 by reducing PaCO2 through increasing hyperventilation. Support for the first is demonstrated by comparing PaO2 predictions made using the AGE, with published values from avian studies and also against values predicted by the theory of MSA.The second is illustrated by comparing the results of high altitude studies of both birds and humans. The application of the AGE to avian respiratory physiology would improve the predictive accuracy of models of the O2 cascade and would also provide better insights into the primary adaptation to high altitude flight.Introduction.

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“…The primary bronchi then divide further into the secondary bronchi (consisting of four kinds in the form of mediodorsal, medioventral, lateroventral, laterodorsal) to the parabronchi (tertiary bronchus) either paleopulmonic or neopulmonic. Nine air sacs are consisting of one interclavicular, two cervicals, two cranial thoracics, and two caudal thoracics, and two abdominal (Schmidt and Wild 2014;Powell 2015;Maina 2016). Therefore, it is challenging to extrapolate personal data of chicken respiratory systems as there are different characteristics.…”

Section: Determining Image Opacity In Broiler Respiratory Radiographimentioning

confidence: 99%

Determining Image Opacity in Broiler Respiratory Radiographic Using ImageJ and Ansel Adam’s Zone System

Wirahadikesuma¹,

Santoso²,

Maheshwari³

et al. 2020

J. Riset Vet. Ind.

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The diagnosis of diseases of the respiratory, lung, and air sacs generally uses radiographic images by radiologists. Therefore, the results are very subjective, causing differences in the interpretation and diagnosis among different radiologists. A radiographic image reading needs to be made in the form of a simple, fast, and accurate algorithm. The study aimed to reduce subjectivity and be easily carried out by radiology medical personnel, especially veterinarians. This study carried out density measurements by image processing using ImageJ software on 14 radiographic images of broiler chickens. Furthermore, the density value is associated with the Ansel Adam's - grayscale system to determine the opacity of respiratory tract tissues/organs, which were previously inhaled by one of them with chitosan-iopamidol nanoparticles using a nebulizer. The results of density measurements for the category of opacity in radiographic images are that seven spot areas lead brighter (radiopaque) only in chickens that are inhaled mist maker of chitosan-iopamidol nanoparticles. Then the determination of the value range is obtained average value on two ventrodorsal radiographic images, which are inhaled by mist maker of chitosan-iopamidol nanoparticles and chitosan nanoparticle compressor. The conclusion of this study was only in chickens that were infested with mist maker chitosan-iopamidol, whose radiographic image had a radiopaque spot and middle-value area.

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Pivotal debates and controversies on the structure and function of the avian respiratory system: setting the record straight

Cited by 24 publications

References 265 publications

Anatomy, ontogeny, and evolution of the archosaurian respiratory system: A case study on Alligator mississippiensis and Struthio camelus

Anatomy, ontogeny, and evolution of the archosaurian respiratory system: A case study on Alligator mississippiensis and Struthio camelus

The alveolar gas equation: do lessons from WW2 research into high flying pilots provide insights into the adaptation to high altitude flight in birds?

Determining Image Opacity in Broiler Respiratory Radiographic Using ImageJ and Ansel Adam’s Zone System

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