Olfactory Epithelium size in Mammals : A structured review

Hipp Marchidan, Gabrielle

January 2021

Members of the class Mammalia have the most advanced skeletal complexity of the nasal cavity among vertebrates. Most mammals have an olfactory epithelium that consists of basal cells, supporting cells and olfactory sensory neurons that bind odor molecules with their cilia. The olfactory epithelium is responsible for detecting odor stimuli. The surface area of olfactory epithelium varies greatly among species. Carnivores have a generally larger surface area of the olfactory epithelium than primates and ungulates of the same size. Modern odontocetes lack olfactory epithelium. To get an overview of the between-species differences of the olfactory epithelium surface area and number of olfactory receptor cells, a search of the scientific literature was performed, using the database Web of Science and references from the scientific articles. The assembled data were entered into two tables, one that contains species names, surface area of the olfactory epithelium and references, and another that includes the total number of olfactory receptor cells for the few species that have been studied in this respect so far. Methods of measuring olfactory epithelium size differ, some studies used immunohistochemistry, other measured osteological proportions, like the surface area of the olfactory turbinals. A compilation of the published data provides an overview of the range that the size of the olfactory epithelium can have and allows for between-species comparisons of this anatomical measure as well as for assessing possible correlations with olfactory capabilities.

mammal olfaction

olfactory epithelium

olfactory receptor cells

Physiology

Fysiologi

Studies of cytochrome P-450-dependent reactions in the olfactory epithelium

Reed, C. J.

January 1986

No description available.

572

Olfactory cytochrome P-450

The toxicity of methyl iodide : in vivo and in vitro mechanistic studies in the rat nasal cavity and cerebellum

Chamberlain, Mark Peter

January 1998

No description available.

572

Glutathione; GSTs; Olfactory epithelium

Development and validation of an in vitro rat nasal epithelial model for predicting respiratory tract toxicity

Kilgour, Joanne Dawn

January 1997

No description available.

615.9

Contribution of microglial reactivity to olfactory ensheathing cell migration in vivo

Basiri, Mohsen

05 June 2008

Olfactory ensheathing cells (OECs) are glial cells that are an attractive candidate for neural repair after spinal cord injury and for remyelination of axons in diseases such as multiple sclerosis. OECs appear to migrate within the adult mammalian central nervous system (CNS) in animal models of spinal cord injury, but until recently there has been no systematic examination of the factors inducing or guiding this migration. Previous work in our lab (V.Skihar) implicated microglial reactivity in the generation of a migratory signal(s) inducing OECs to migrate towards an ethidium bromide-induced focal demyelination in the adult rat spinal cord. The long-term objective of this research project was to test the hypothesis that reactive microglial provide a migratory signal(s) driving the migration of OECs within the spinal cord of adult rats.<p>The first set of experiments determined the time-frame in which Wallerian degeneration (WD) induced microglial reactivity occurs in the right dorsal corticospinal tract (dCST) of adult rats at the level of T11 following aspiration of the contralateral sensorimotor cortex. This timing data from this study demonstrated a prominent microglial activation in the right dCST of T11 eight weeks after sensorimotor cortex injury indicating the microglial response to WD of dCST axons was very slow to appear. The second set of experiments determined whether OECs were induced to migrate in response to WD-induced microglial reactivity in the dCST, which based on the first set of experiments was known to occur within 8 weeks of lesioning the left sensorimotor cortex. This second set of experiments also examined the migratory path taken by OECs with respect to the location of reactive microglia (i.e. inside vs outside the right dCST). For these experiments, the left sensorimotor cortex was damaged 8 weeks prior to grafting the OECs at T12. <p>The next group of experiments examined the contribution of TNF-á induced microglial reactivity to generation of a migratory signal. First we identified concentrations of TNF-á that when injected into the DF of the T11 spinal cord segment of an adult rat induced microglial reactivity either along at least a 5 mm distance from the injection site or confined to the immediate vicinity of the injection site. The result of this experiment identified a concentration of 1 ng/µl and 0.01 ng/µl TNF-á as appropriate concentrations to induce the appropriate amount of microglial reactivity, respectively. The final set of experiments used these two concentrations to determine whether TNF-á induced microglial reactivity that is initiated 5 mm rostral to a DiI+ve OEC graft generates a migratory signal(s) inducing OECs to migrate towards the rostral part of T11 and whether the migratory signal(s) was present only if the microglial reactivity extended the full 5 mm distance between the TNF-á injection and the OEC graft. <p>The major findings were: i) there was a significantly higher density of DiI+ve OECs within the right dCST of rats in which there was WD-induced microglial reactivity as compared to the right dCST of rats in which there was no microglial reactivity; ii) the migratory path taken by DiI+ve OECs was preferentially within areas containing reactive microglia (i.e. dCST) and towards the site of TNF-á induced microglial reactivity (i.e. rostral to cell graft as opposed to caudal); iii) significantly more DiI+ve OECs migrated towards the site of a TNF-á injection when the microglia were reactive along the entire length of the migratory path between the cytokine injection and cell graft; and iv) minocycline treatment both dampened microglial reactivity and significantly reduced the number of migrating DiI+ve OECs. The major conclusions are that the migration of OECs within the adult rat spinal cord occurs in response to migratory signal(s) arising as a result of microglial activation and that this migration occurs preferentially along the path of microglial reactivity.

Migration

Microglia

Olfactory Ensheathing Cell

Contribution of microglial reactivity to olfactory ensheathing cell migration in vivo

Basiri, Mohsen

05 June 2008

Olfactory ensheathing cells (OECs) are glial cells that are an attractive candidate for neural repair after spinal cord injury and for remyelination of axons in diseases such as multiple sclerosis. OECs appear to migrate within the adult mammalian central nervous system (CNS) in animal models of spinal cord injury, but until recently there has been no systematic examination of the factors inducing or guiding this migration. Previous work in our lab (V.Skihar) implicated microglial reactivity in the generation of a migratory signal(s) inducing OECs to migrate towards an ethidium bromide-induced focal demyelination in the adult rat spinal cord. The long-term objective of this research project was to test the hypothesis that reactive microglial provide a migratory signal(s) driving the migration of OECs within the spinal cord of adult rats.<p>The first set of experiments determined the time-frame in which Wallerian degeneration (WD) induced microglial reactivity occurs in the right dorsal corticospinal tract (dCST) of adult rats at the level of T11 following aspiration of the contralateral sensorimotor cortex. This timing data from this study demonstrated a prominent microglial activation in the right dCST of T11 eight weeks after sensorimotor cortex injury indicating the microglial response to WD of dCST axons was very slow to appear. The second set of experiments determined whether OECs were induced to migrate in response to WD-induced microglial reactivity in the dCST, which based on the first set of experiments was known to occur within 8 weeks of lesioning the left sensorimotor cortex. This second set of experiments also examined the migratory path taken by OECs with respect to the location of reactive microglia (i.e. inside vs outside the right dCST). For these experiments, the left sensorimotor cortex was damaged 8 weeks prior to grafting the OECs at T12. <p>The next group of experiments examined the contribution of TNF-á induced microglial reactivity to generation of a migratory signal. First we identified concentrations of TNF-á that when injected into the DF of the T11 spinal cord segment of an adult rat induced microglial reactivity either along at least a 5 mm distance from the injection site or confined to the immediate vicinity of the injection site. The result of this experiment identified a concentration of 1 ng/µl and 0.01 ng/µl TNF-á as appropriate concentrations to induce the appropriate amount of microglial reactivity, respectively. The final set of experiments used these two concentrations to determine whether TNF-á induced microglial reactivity that is initiated 5 mm rostral to a DiI+ve OEC graft generates a migratory signal(s) inducing OECs to migrate towards the rostral part of T11 and whether the migratory signal(s) was present only if the microglial reactivity extended the full 5 mm distance between the TNF-á injection and the OEC graft. <p>The major findings were: i) there was a significantly higher density of DiI+ve OECs within the right dCST of rats in which there was WD-induced microglial reactivity as compared to the right dCST of rats in which there was no microglial reactivity; ii) the migratory path taken by DiI+ve OECs was preferentially within areas containing reactive microglia (i.e. dCST) and towards the site of TNF-á induced microglial reactivity (i.e. rostral to cell graft as opposed to caudal); iii) significantly more DiI+ve OECs migrated towards the site of a TNF-á injection when the microglia were reactive along the entire length of the migratory path between the cytokine injection and cell graft; and iv) minocycline treatment both dampened microglial reactivity and significantly reduced the number of migrating DiI+ve OECs. The major conclusions are that the migration of OECs within the adult rat spinal cord occurs in response to migratory signal(s) arising as a result of microglial activation and that this migration occurs preferentially along the path of microglial reactivity.

Migration

Microglia

Olfactory Ensheathing Cell

Optimization of functional MRI methods for olfactory interventional studies at 3T

Ahluwalia, Vishwadeep,

January 1900

Thesis (Ph.D.)--Virginia Commonwealth University, 2009. / Prepared for: Dept. of Radiology. Title from title-page of electronic thesis. Bibliography: leaves 117-124.

The effects of plume property variation on odor plume navigation in turbulent boundary layer flows

Page, Jennifer Lynn.

January 2009

Thesis (Ph.D)--Biology, Georgia Institute of Technology, 2009. / Committee Chair: Weissburg, Marc; Committee Member: Hay, Mark; Committee Member: Kubanek, Julia; Committee Member: Webster, Donald; Committee Member: Yen, Jeannette. Part of the SMARTech Electronic Thesis and Dissertation Collection.

The characterization of the olfactory ensheathing cell phenotype by protein analysis

Smithson, LAURA

09 October 2008

Over the recent years, olfactory ensheathing cells (OECs) have gained world-wide attention due to their reputed potential in promoting spinal cord regeneration and repair. In order to isolate, identify, and characterize OECs in vitro and following implantation, researchers have used three OEC markers: p75NTR, GFAP, and S100. The downfall with using these specific proteins is that Schwann cells, which are located within the olfactory system, as well as migrate into the damaged spinal cord, also express these proteins. It is therefore impossible to distinguish OECs from phenotypically similar Schwann cells using these molecular markers. Recently proteomic analyses have revealed that OECs (derived from embryonic rat olfactory bulbs), but not Schwann cells (derived from adult rat sciatic nerves) express a variety of proteins. The main aim of this project is to determine if heat shock protein-27 (Hsp27), carbonic anhydrase-III (CA-III), and annexin-A3 (Anx3) markers label OECs but not Schwann cells, both in vivo and in vitro. Additional analyses were also done to determine if smooth muscle α-actin (SMA) and calponin (two smooth muscle-related markers previously shown to label mucosal OECs of adult rats) label bulbar OECs of adult rats and OECs of adult cats. Using immunohistochemistry we found that SMA labeled olfactory mucosal and bulbar OECs of adult rats and adult cats, Hsp27 labeled olfactory mucosal and bulbar OECs of adult rats and olfactory mucosal OECs of adult cats, while calponin labeled only olfactory mucosal OECs of adult rats. In addition, calponin and SMA did not label Schwann cells (in vivo and in vitro), while Hsp27 labeled this peripheral glial cell. Finally, CA-III did not label OECs of adult rats or adult cats, in vivo or in vitro, and Anx3 did not label OECs in vivo, but showed immunopositive labeling of OECs and Schwann cells in vitro. In conclusion, Hsp27, CA-III, and Anx3 cannot be used as OECs markers either because of their expression in both OECs and Schwann cells or their lack of expression in OECs. Discovering new molecular markers expressed only by OECs is essential in order to determine the properties, fate, and overall potential of OECs in promoting spinal cord regeneration. / Thesis (Master, Neuroscience Studies) -- Queen's University, 2008-09-29 09:50:09.869

olfactory ensheathing cells

glial cells

Transplantation of nasal olfactory tissues into transected spinal cord of adult rats /

Lu, Jike.

January 2000

Thesis (Ph. D.)--University of New South Wales, 2000. / Also available online.

Rats Olfactory tissue Spinal cord