Distribution of Olfactory and Nonolfactory Surface Area in the Nasal Fossa of <i>Microcebus murinus</i>: Implications for Microcomputed Tomography and Airflow Studies

Smith, Timothy D.; Eiting, Thomas P.; Rossie, James B.

doi:10.1002/ar.21411

Cited by 77 publications

(51 citation statements)

References 27 publications

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“…Our study shows that variations in the size of the olfactory recess likely have significant functional consequences in groups that exhibit extensive variation in olfactory recess size, such as bats and primates (Cave, 1973;Moore, 1981;Smith et al, 2011;Smith et al, 2012;Smith et al, in press). This work also adds to the growing body of computational modeling studies that investigate the role of morphology in airway function.…”

Section: Research Articlementioning

confidence: 74%

The role of the olfactory recess in olfactory airflow

Eiting

Smith

Perot

et al. 2014

Journal of Experimental Biology

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The olfactory recess -a blind pocket at the back of the nasal airway -is thought to play an important role in mammalian olfaction by sequestering air outside of the main airstream, thus giving odorants time to re-circulate. Several studies have shown that species with large olfactory recesses tend to have a well-developed sense of smell. However, no study has investigated how the size of the olfactory recess relates to air circulation near the olfactory epithelium. Here we used a computer model of the nasal cavity from a bat (Carollia perspicillata) to test the hypothesis that a larger olfactory recess improves olfactory airflow. We predicted that during inhalation, models with an enlarged olfactory recess would have slower rates of flow through the olfactory region (i.e. the olfactory recess plus airspace around the olfactory epithelium), while during exhalation these models would have little to no flow through the olfactory recess. To test these predictions, we experimentally modified the size of the olfactory recess while holding the rest of the morphology constant. During inhalation, we found that an enlarged olfactory recess resulted in lower rates of flow in the olfactory region. Upon exhalation, air flowed through the olfactory recess at a lower rate in the model with an enlarged olfactory recess. Taken together, these results indicate that an enlarged olfactory recess improves olfactory airflow during both inhalation and exhalation. These findings add to our growing understanding of how the morphology of the nasal cavity may relate to function in this understudied region of the skull.

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Section: Research Articlementioning

confidence: 74%

The role of the olfactory recess in olfactory airflow

Eiting

Smith

Perot

et al. 2014

Journal of Experimental Biology

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“…Thus, the short snout of feliforms appears to have reduced the space available for the maxilloturbinal, allowing the anterior ethmoturbinals to lie in the respiratory air pathway (Fig. ), a pattern also observed in some primates (Smith et al, ).…”

Section: Comparative Anatomy and Functionmentioning

confidence: 74%

“…These turbinals are the primary location for olfactory epithelium, but may also participate in respiratory air‐conditioning in some primates (Smith et al, ; DeLeon and Smith, ) and short‐snouted carnivorans (Van Valkenburgh et al, ). In addition, olfactory epithelium can be found rostrally on the nasal septum as well as lining various recesses and the lateral walls of the nasal cavity (Adams, ; Bhatnagar and Kallen, ; Smith et al, ). In many or most mammals, the nasoturbinal has a tube‐like morphology and appears to function in directing air to the posteriorly positioned olfactory region.…”

Section: Comparative Anatomy and Functionmentioning

confidence: 99%

Tour of a Labyrinth: Exploring the Vertebrate Nose

Valkenburgh

Smith

Craven

2014

The Anatomical Record

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103

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This special issue of The Anatomical Record is the outcome of a symposium entitled "Inside the Vertebrate Nose: Evolution, Structure and Function." The skeletal framework of the nasal cavity is a complicated structure that often houses sinuses and comprises an internal skeleton of bone or cartilage that can vary greatly in architecture among species. The nose serves multiple functions, including olfaction and respiratory airconditioning, and its morphology is constrained by evolution, development, and conflicting demands on cranial space, such as enlarged orbits. The nasal cavity of vertebrates has received much more attention in the last decade due to the emergence of nondestructive methods that allow improved visualization of the internal anatomy of the skull, such as highresolution x-ray computed tomography and magnetic resonance imaging. The 17 articles included here represent a broad range of investigators, from paleontologists to engineers, who approach the nose from different perspectives. Key topics include the evolution and development of the nose, its comparative anatomy and function, and airflow through the nasal cavity of individual species. In addition, this special issue includes review articles on anatomical reduction of the olfactory apparatus in both cetaceans and primates (the vomeronasal system), as well as the molecular biology of olfaction in vertebrates. Together these articles provide an expansive summary of our current understanding of vertebrate nasal anatomy and function. In this introduction, we provide background information and an overview of each of the three primary topics, and place each article within the context of previous research and the major challenges that lie ahead.

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“…The architecture of the turbinals and floor of the nasal capsule determines whether orthonasal and/or retronasal air currents pass directly over olfactory epithelium. Turbinals are highly variable between mammalian clades, and only recently has 3D imaging made morphological analysis possible (Van Valkenburgh et al, 2004; Rowe et al, 2005; Smith et al, 2011; Eiting et al, 2015), and shown that they preserve phylogenetic (Macrini, 2012) and ecological (Van Valkenburgh et al, 2011) signals.…”

Section: Resultsmentioning

confidence: 99%

“…They lie directly in the stream of ortho-retronasal airflow and function in metabolic heat and water balance (Smith et al, 2011; Eiting et al, 2015). Saturation of air within the nose may also play a role in volatilization, but experimental airflow studies are still in their infancy.…”

Section: Resultsmentioning

confidence: 99%

Role of ortho‐retronasal olfaction in mammalian cortical evolution

Rowe

Shepherd

2015

J of Comparative Neurology

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Fossils of mammals and their extinct relatives among cynodonts give evidence of correlated transformations affecting olfaction as well as mastication, head movement, and ventilation, and suggest evolutionary coupling of these seemingly separate anatomical regions into a larger integrated system of ortho-retronasal olfaction. Evidence from paleontology and physiology suggests that ortho-retronasal olfaction played a critical role at three stages of mammalian cortical evolution: early mammalian brain development was driven in part by ortho-nasal olfaction; the bauplan for neocortex had higher-level association functions derived from olfactory cortex; and human cortical evolution was enhanced by ortho-retronasal smell.

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Distribution of Olfactory and Nonolfactory Surface Area in the Nasal Fossa of Microcebus murinus: Implications for Microcomputed Tomography and Airflow Studies

Cited by 77 publications

References 27 publications

The role of the olfactory recess in olfactory airflow

The role of the olfactory recess in olfactory airflow

Tour of a Labyrinth: Exploring the Vertebrate Nose

Role of ortho‐retronasal olfaction in mammalian cortical evolution

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