Case studies in novel narial anatomy: 3. Structure and function of the nasal cavity of saiga (Artiodactyla: Bovidae: Saiga tatarica)

Andrew B. Clifford; Lawrence M. Witmer

doi:10.1017/S0952836904005540

Abstract

Much of the narial anatomy of the enigmatic antelope Saiga tatarica has been described by previous workers. However, the anatomy of the nasal cavity and the causally associated osteological correlates of proboscis structure require closer attention, because these data are integral for both a more comprehensive understanding of saiga functional morphology and more robust reconstructions of proboscis structure in fossil taxa. Saiga and outgroup specimens were subjected to X-ray computed tomographic (CT) imaging, gross dissection and skeletonization. The nasal cavity of saiga is characterized by an enlarged nasal vestibule and basal conchal fold. Many structures (e.g. turbinates, lateral cartilages, mucosal folds, nasolacrimal duct) are retracted caudally to a small area in the caudodorsal part of the nasal cavity proper. The enlarged vestibule is associated laterally and ventrally with paired sacs. The nasal septum is largely membranous and contains a large patch of cavernous tissue that serves as a dynamic baffle modifying the flow of inspired air. Bones comprising the narial margin have modified attachment sites for buccinator group muscles and the reduced lateral cartilages. The premaxilla is greatly modified by the enlarged musculature associated with nasolabial fusion. Maintenance of the topological relationships of narial structures compared to bovid outgroups has resulted in a nasal cavity with much larger area for seromucous glands of the vestibule as well as narial musculature capable of controlling the aperture of the nasal cavity. Maxillolabial muscles and the lateralis nasi act together both to compress the nasal cavity and to control the dilation of the nostrils such that air flow through the cavity is highly modified relative to bovid outgroups. The lateral vestibular recess is an outpocketing of the nasal vestibule that produces supplementary seromucous secretions and seems to have no homologue among outgroups. The enlarged nasal vestibule, lateral vestibular recess, repositioned basal fold, and septal cavernous mass are regarded as a coordinated adaptation to dusty habitats, such that nasal air flow can be dynamically regulated allowing for collection of inspired particulates in the vestibule and thus cleansing of air destined for the lungs.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Bargo, M. Susana Toledo, Néstor and Vizcaíno, Sergio F. 2006. Muzzle of South American Pleistocene ground sloths (Xenarthra, Tardigrada). Journal of Morphology, Vol. 267, Issue. 2, p. 248.

Frey, Roland Volodin, Ilya and Volodina, Elena 2007. A nose that roars: anatomical specializations and behavioural features of rutting male saiga. Journal of Anatomy, Vol. 211, Issue. 6, p. 717.

Smith, Timothy D. Bhatnagar, Kunwar P. Rossie, James B. Docherty, Beth A. Burrows, Anne M. Cooper, Gregory M. Mooney, M.P. and Siegel, M.I. 2007. Scaling of the first ethmoturbinal in nocturnal strepsirrhines: Olfactory and respiratory surfaces. The Anatomical Record, Vol. 290, Issue. 3, p. 215.

Breda, Marzia 2008. Palaeoecology and palaeoethology of the Plio-Pleistocene genusCervalces(Cervidae, Mammalia) in Eurasia. Journal of Vertebrate Paleontology, Vol. 28, Issue. 3, p. 886.

Miyashita, Tetsuto Arbour, Victoria M. Witmer, Lawrence M. and Currie, Philip J. 2011. The internal cranial morphology of an armoured dinosaur Euoplocephalus corroborated by X-ray computed tomographic reconstruction. Journal of Anatomy, Vol. 219, Issue. 6, p. 661.

Smith, Timothy D. Eiting, Thomas P. and Bhatnagar, Kunwar P. 2012. A Quantitative Study of Olfactory, Non-Olfactory, and Vomeronasal Epithelia in the Nasal Fossa of the Bat Megaderma lyra. Journal of Mammalian Evolution, Vol. 19, Issue. 1, p. 27.

Giannini, Norberto P. Macrini, Thomas E. Wible, John R. Rowe, Timothy B. and Simmons, Nancy B. 2012. The Internal Nasal Skeleton of the BatPteropus lyleiK.Andersen, 1908 (Chiroptera: Pteropodidae). Annals of Carnegie Museum, Vol. 81, Issue. 1, p. 1.

MILEWSKI, Antoni V. and DIERENFELD, Ellen S. 2013. Structural and functional comparison of the proboscis between tapirs and other extant and extinct vertebrates. Integrative Zoology, Vol. 8, Issue. 1, p. 84.

Cassini, Guillermo H. 2013. Skull Geometric Morphometrics and Paleoecology of Santacrucian (Late Early Miocene; Patagonia) Native Ungulates (Astrapotheria, Litopterna, and Notoungulata). Ameghiniana, Vol. 50, Issue. 2, p. 193.

Ruf, Irina 2014. Comparative Anatomy and Systematic Implications of the Turbinal Skeleton in Lagomorpha (Mammalia). The Anatomical Record, Vol. 297, Issue. 11, p. 2031.

Ranslow, Allison N. Richter, Joseph P. Neuberger, Thomas Van Valkenburgh, Blaire Rumple, Christopher R. Quigley, Andrew P. Pang, Benison Krane, Michael H. and Craven, Brent A. 2014. Reconstruction and Morphometric Analysis of the Nasal Airway of the White‐Tailed Deer (Odocoileus virginianus) and Implications Regarding Respiratory and Olfactory Airflow. The Anatomical Record, Vol. 297, Issue. 11, p. 2138.

Wang, Xiaoming Wang, Yang Li, Qiang Tseng, Z. Jack Takeuchi, Gary T. Deng, Tao Xie, Guangpu Chang, Mee-mann and Wang, Ning 2015. Cenozoic vertebrate evolution and paleoenvironment in Tibetan Plateau: Progress and prospects. Gondwana Research, Vol. 27, Issue. 4, p. 1335.

Huggenberger, Stefan André, Michel and Oelschläger, Helmut H. A. 2016. The nose of the sperm whale: overviews of functional design, structural homologies and evolution. Journal of the Marine Biological Association of the United Kingdom, Vol. 96, Issue. 4, p. 783.

Eshrah, E. A. 2017. The Camel Rhinarium: A Study Revealing the Presence of the Nasal Plane in Dromedary Camel (Camelus dromedarius),with Special Reference to Its Epidermal Structure. Anatomia, Histologia, Embryologia, Vol. 46, Issue. 1, p. 65.

Jürgensen, Jonathan Drucker, Dorothée G. Stuart, Anthony J. Schneider, Matthias Buuveibaatar, Bayarbaatar and Bocherens, Hervé 2017. Diet and habitat of the saiga antelope during the late Quaternary using stable carbon and nitrogen isotope ratios. Quaternary Science Reviews, Vol. 160, Issue. , p. 150.

Arbour, Victoria M. Mallon, Jordan C. and Clemente, Christofer J. 2017. Unusual cranial and postcranial anatomy in the archetypal ankylosaur Ankylosaurus magniventris. FACETS, Vol. 2, Issue. 2, p. 764.

Wible, John R. and Rougier, Guillermo W. 2017. Craniomandibular Anatomy of the Subterranean MeridiolestidanNecrolestes patagonensisAmeghino, 1891 (Mammalia, Cladotheria) from the Early Miocene of Patagonia. Annals of Carnegie Museum, Vol. 84, Issue. 3, p. 183.

Moyano, Silvana Rocio and Giannini, Norberto Pedro 2018. Cranial characters associated with the proboscis postnatal-development in Tapirus (Perissodactyla: Tapiridae) and comparisons with other extant and fossil hoofed mammals. Zoologischer Anzeiger, Vol. 277, Issue. , p. 143.

Jones, Megan E.B. Gasper, David J. and Mitchell (née Lane), Emily 2018. Pathology of Wildlife and Zoo Animals. p. 117.

Maust‐Mohl, Maria Reiss, Diana and Reidenberg, Joy S. 2019. A Comparison of Common Hippopotamus (Artiodactyla) and Mysticete (Cetacea) Nostrils: An Open and Shut Case. The Anatomical Record, Vol. 302, Issue. 5, p. 693.

Download full list

Article contents

Case studies in novel narial anatomy: 3. Structure and function of the nasal cavity of saiga (Artiodactyla: Bovidae: Saiga tatarica)

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Case studies in novel narial anatomy: 3. Structure and function of the nasal cavity of saiga (Artiodactyla: Bovidae: Saiga tatarica)

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests