Morphology of the Air Sacs in Crimson Rosella (Platycercus elegans) Parrots

The fate of the tracheal system is traced from the first larval instar to the adult stage. The basic larval pattern conforms to that shown for other Diptera Cyclorrhapha (Whitten, 1955), and is identical in all three instars. According to previous accounts the adult system directly replaces the larval: the larval system is partly shed, partly histolysed, and the adult system arises from imaginal cell clusters independently of the preceding larval system. In contrast, it is shown here that in the cephalic, thoracic, and anterior abdominal region there is a definite continuity in the tracheal system, from larval, through pupal to the adult stage, whereas in the posterior abdominal region the larval system is histolysed, and the adult system is independent of it in origin. Moreover, in the pupal stage this region is tracheated by tracheae arising from the anterior abdominal region and belonging to a distinct pupal system. Moulting of the tracheal linings is complete at the first and second larval ecdyses, but incomplete at the third larval-pupal and pupal-adult ecdyses. In consequence, in both pupal and adult systems there are tracheae which are secreted around preexisting tracheae, others formed as new ‘branch’ tracheae, and those which have been carried over from the previous instar. In the adult the newly formed tracheae of the posterior abdominal region fall into a fourth category. Most of the adult thoracic air sacs correspond to new ‘branch’ tracheae of other instars. The pre-pupal moult and instar are discussed with reference to the tracheal system and tentative suggestions are made concerning the true nature of the pre-pupal cuticle. There is no pre-pupal tracheal system. Events traced for Drosophila would seem to be general for Cyclorrhapha, both Acalypterae and Calypterae. The separate fates of the anterior and posterior abdom inal systems, in contrast with the straightforward development in Dipterc Nematocera, would appear to mark a distinct step in the evolution of the system in Diptera.

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Air Sacs

Encyclopedia of Entomology ◽

10.1007/978-1-4020-6359-6_123 ◽

2008 ◽

pp. 85-85

Author(s):

George Hangay ◽

Severiano F. Gayubo ◽

Marjorie A. Hoy ◽

Marta Goula ◽

Allen Sanborn ◽

...

Keyword(s):

Air Sacs

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The Movement of Gas in the Respiratory System of the Duck

Journal of Experimental Biology ◽

10.1242/jeb.56.1.57 ◽

1972 ◽

Vol 56 (1) ◽

pp. 57-65 ◽

Cited By ~ 1

Author(s):

W. L. BRETZ ◽

KNUT SCHMIDT-NIELSEN

Keyword(s):

Mass Spectrometer ◽

Respiratory System ◽

Experimental Results ◽

Arrival Times ◽

Expiratory Phase ◽

Air Sacs ◽

Inspiratory Phase ◽

Thoracic And Abdominal ◽

Ventilation Rates ◽

Residual Air

1. A single inhalation of marker gas (argon) was administered to unanaesthetized ducks. Pargon was continuously monitored in the interclavicular, cranial thoracic, caudal thoracic and abdominal air sacs with a mass spectrometer during the marked inspiration and subsequent respiratory cycles. 2. The sequence of arrival times of the inspired marker at the various sampling sites was determined; ventilation rates of the different air sacs were compared by examining the rate of decrease of Par during washout of each sac. 3. The experimental results agree with previously proposed patterns of air flow in the duck respiratory system. 4. It is proposed that the movement of gas in the respiratory system of birds is a two-cycle event. During the inspiratory phase of the first cycle, inhaled air is drawn into the posterior air sacs; during the expiratory phase of the first cycle, this air (having mixed with the residual air in the posterior air sacs) is pumped into the secondary and tertiary bronchi of the lung; during the inspiratory phase of the second cycle this air in the lung passage-ways is drawn into the anterior air sacs; and finally, during the expiratory phase of the second cycle, this air is exhaled from the anterior air sacs and the respiratory system.

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Effects of Combined Abdominal and Thoracic Airsac Occlusion on Respiration in Domestic Fowl

Journal of Experimental Biology ◽

10.1242/jeb.152.1.93 ◽

1990 ◽

Vol 152 (1) ◽

pp. 93-100 ◽

Cited By ~ 3

Author(s):

JOHN BRACKENBURY ◽

JANE AMAKU

Keyword(s):

Metabolic Rate ◽

Tidal Volume ◽

Dead Space ◽

Domestic Fowl ◽

Detrimental Effect ◽

Minute Ventilation ◽

Respiratory Pattern ◽

Blood Gas ◽

Control Value ◽

Air Sacs

Ventilation and respiratory and blood gas tensions were monitored at rest and during running exercise, following bilateral occlusion of the cranial and caudal thoracic and the abdominal air sacs. This represents a removal of approximately 70% of the total air-sac capacity. At rest, the birds were strongly hypoxaemic/hypercapnaemic. Ventilation was maintained at its control value but respiratory frequency was significantly increased and tidal volume diminished. The birds were capable of sustained running at approximately three times the pre-exercise metabolic rate. Minute ventilation during exercise was the same as that of the controls, but breathing was faster and shallower. Exercise had no effect on blood gas tensions in either the control or the experimental birds. There was no evidence of a detrimental effect of air-sac occlusion on the effectiveness of inspiratory airflow valving in the lung: hypoxaemia appeared to be due to the altered respiratory pattern, which resulted in increased dead-space inhalation.

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Ontogeny and evolution of the sound-generating structures in the infraorder Delphinida (Odontoceti: Delphinida)

Biological Journal of the Linnean Society ◽

10.1093/biolinnean/blz118 ◽

2019 ◽

Vol 128 (3) ◽

pp. 700-724 ◽

Cited By ~ 4

Author(s):

Guilherme Frainer ◽

Ignacio B Moreno ◽

Nathalia Serpa ◽

Anders Galatius ◽

Dirk Wiedermann ◽

...

Keyword(s):

Computed Tomography ◽

Postnatal Development ◽

Histological Examination ◽

Sound Generation ◽

Resonance Imaging ◽

3D Slicer ◽

Perinatal Development ◽

Air Sacs ◽

Magentic Resonance Imaging ◽

Resonance Imaging Scan

AbstractThe ontogeny of the structures involved in sound generation and modulation in dolphins was investigated through a comparison of the soft nasal structures of foetal, perinatal, neonatal and adult specimens of Pontoporiidae, Phocoenidae and Delphinidae. Foetal samples were sectioned at 10 µm in the saggital and coronal planes, and stained for histological examination. Computed tomography and magentic resonance imaging scan series were combined with new data to represent the ontogenetic stages of the three groups. The images were analysed in 3D-Slicer to characterize the general head topography. The origins of the melon and the vestibular air sac were detected between Carnegie stages C16 and F22. The three groups analysed showed distinct formation of the nasal plug and nasal plug muscles, mainly with regard to the loss of fat pathways (or their maintenance in Pontoporiidae) and the development of the nasal plug muscles on both sides (during perinatal development of Phocoenidae) or just on the left side (during postnatal development in Delphinidae). Broadband vocalizing delphinidans might have evolved under heterochronic events acting on the formation of sound-generating structures such as the rostrum and vestibular air sacs, and on the transformation of the branches of the melon, probably leading to a reduced directionality of the sonar beam.

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Gross morphological features of the air sacs of the hooded crow ( Corvus cornix )

Anatomia Histologia Embryologia ◽

10.1111/ahe.12504 ◽

2020 ◽

Vol 49 (2) ◽

pp. 159-166

Author(s):

Ahmed K. El‐Sayed ◽

Said Hassan

Keyword(s):

Morphological Features ◽

Hooded Crow ◽

Air Sacs ◽

Corvus Cornix

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Comparative migration, growth and development of Typhlocoelum cucumerinum sisowi in dabbling ducks and Typhlocoelum cucumerinum cucumerinum in diving ducks

Parasitology ◽

10.1017/s0031182000044887 ◽

1982 ◽

Vol 84 (2) ◽

pp. 333-350 ◽

Cited By ~ 5

Author(s):

Marilyn E. Scott ◽

M. E. Rau ◽

J. D. McLaughlin

Keyword(s):

Life Cycle ◽

Life Span ◽

Definitive Host ◽

Host Species ◽

Growth And Development ◽

Abdominal Cavity ◽

Dabbling Ducks ◽

Diving Ducks ◽

Air Sacs ◽

Aythya Valisineria

SUMMARYExperimental infections of mallards (Anas platyrhynchos L.) with Typhlocoelum cucumerinum sisowi (Skrjabin, 1913) and of canvasbacks (Aythya valisineria (Wilson)) with Typhlocoelum cucumerinum cucumerinum (Rudolphi, 1809) revealed significant differences in various parameters of the life-cycle in the definitive host. Both T. c. sisowi and T. c. cucumerinum migrate to the trachea via the abdominal cavity, air sacs and lungs, although T. c. cucumerinum migrate more quickly and more synchronously than T. c. sisowi. Typhlocoelum c. sisowi has a shorter expected life-span than T. c. cucumerinum but grows and reaches maturity more quickly than T. c. cucumerinum. Evidence suggests that T. c. cucumerinum has a higher fecundity than T. c. sisowi. These differences in the patterns of migration, growth and development are related not only to differences between the two host species but also to differences intrinsic to the parasites, and serve to provide biological support for considering them as separate sub-species.

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Air Sacs in the Turkey

Poultry Science ◽

10.3382/ps.0370053 ◽

1958 ◽

Vol 37 (1) ◽

pp. 53-60 ◽

Cited By ~ 10

Author(s):

R.H. Rigdon ◽

T.M. Ferguson ◽

G.L. Feldman ◽

J.R. Couch

Keyword(s):

Air Sacs

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