Equine and Animal Cognition Reference Database -- Query Results

Tooze, Z. J., Harrington, F. H., & Fentress, J. C. (1990). Individually distinct vocalizations in timber wolves, Canis lupus. Anim Behav, 40. https://references.equine-behaviour.de/show.php?record=6468
Zaccaroni, M., Passilongo, D., Buccianti, A., Dessi-Fulgheri, F., Facchini, C., & Gazzola, A. (2012). Group specific vocal signature in free- ranging wolf packs. Ethol Ecol Evol, 24. https://references.equine-behaviour.de/show.php?record=6470
Stenglein, J. L., Waits, L. P., Ausband, D. E., Zager, P., & Mack, C. M. (2011). Estimating gray wolf pack size and family relationships using non invasive genetic sampling at rendezvous sites. J Mammal, 92. https://references.equine-behaviour.de/show.php?record=6476
Galaverni, M., Palumbo, D., Fabbri, E., Caniglia, R., Greco, C., & Randi, E. (2012). Monitoring wolves (Canis lupus) by non-invasive genetics and camera trapping: A small-scale pilot study. Eur J Wildl Res, 58. https://references.equine-behaviour.de/show.php?record=6479
Herbst, C. T., Herzel, H., Svec, J. G., Wyman, M. T., & Fitch, W. T. (2013). Visualization of system dynamics using phasegrams. J R Soc Interface, 10. https://references.equine-behaviour.de/show.php?record=6487
Sueur, J., Aubin, T., & Simonis, C. (2008). Seewave: a free modular tool for sound analysis and synthesis. Bioacoustics, 18. https://references.equine-behaviour.de/show.php?record=6490
Marescot, L., Pradel, R., Duchamp, C., Cubaynes, S., Mrboutin, E., & Choquet, R. (2011). Capture – recapture population growth rate as a robust tool against detection heterogeneity for population management. Ecol Appl, 21. https://references.equine-behaviour.de/show.php?record=6491
Morgan, T. W., & Elliott, C. L. (2011). Comparison of remotely-triggered cameras vs. howling surveys for estimating coyote (Canis latrans) Abundance in central Kentucky. J Ky Acad Science, 72. https://references.equine-behaviour.de/show.php?record=6492
Tegetmeier, W. B., & Sutherland, C. L. (1895). Horses, asses, zebras, mules and mule breeding. Abstract: A scholarly review of the entire horse family with separate chapters on Prejevalsky`s horse, the African wild ass, the wild ass of Somaliland, the Asiatic wild ass, the mountain zebra, Grevy`s zebra, Burchell`s zebra, the Quagga, hybrid Equidae, the Poitou mule, the American mule and others. Rare. https://references.equine-behaviour.de/show.php?record=106
Moons, C., Heleski, C. R., Leece, C. M., & Zanella, A. J. (2002). Conflicting Results in the Association Between Plasma and Salivary Cortisol Levels in Foals. Abstract: Introduction Glucocorticoids are present in many biological fluids as a free fraction or bound to Corticoid Binding Globulins (CBG) (Matteri et al, 2000). There are conflicting claims regarding the validity of saliva as a biological fluid to measure cortisol in horses (Lebelt et al, 1996; McGreevy and Pell, 1998; van der Kolk et al, 2001). Measuring changes in salivary cortisol levels in normal horses and horses with Cushing`s disease van der Kolk and collaborators (2001) demonstrated the validity of saliva to assess adrenal function. Puzzling results were reported by McGreevy and Pell (1998) who suggested that plasma and salivary cortisol concentrations in horses showing oral stereotypies were correlated but this association was non-existent in control animals. Investigating the responses of foals to branding and foot-trimming Zanella et al (unpublished results) were unable to identify a relationship between plasma and salivary cortisol levels in foals. In several species, levels of cortisol in plasma and saliva are tightly correlated (Fenske, 1996). Cortisol found in blood consists of a fraction bound to corticoid binding globulin (CBG) and a free, unbound fraction. Free cortisol represents the biologically active fraction of this steroid hormone. Salivary cortisol reflects the unbound fraction found in plasma or serum and it passes readily through the parotid membrane (Riad-Fahmy, 1983; Horning Walker et al,1977). Unbound steroids transfer rapidly between plasma and saliva (Walker,1989; Scott et al 1990). Saliva flow-rate does not appear to influence saliva cortisol levels in different species (Hubert and de Jong-Meyer, 1989; Walker 1989, Scott et a, 1990). In horses, Lebelt et al (1996) reported that salivary and plasma total cortisol in stallions were correlated. We hypothesized that changes in salivary cortisol in foals would show a pattern that is correlated to that of plasma free and plasma total cortisol concentrations in foals. In addition, we anticipated that the lack of good sampling techniques provides an explanation for the failure in determining the association between salivary and plasma cortisol in foals. https://references.equine-behaviour.de/show.php?record=470

Zaccaroni, M., Passilongo, D., Buccianti, A., Dessi-Fulgheri, F., Facchini, C., & Gazzola, A. (2012). Group specific vocal signature in free- ranging wolf packs. Ethol Ecol Evol, 24.

Galaverni, M., Palumbo, D., Fabbri, E., Caniglia, R., Greco, C., & Randi, E. (2012). Monitoring wolves (Canis lupus) by non-invasive genetics and camera trapping: A small-scale pilot study. Eur J Wildl Res, 58.

Sueur, J., Aubin, T., & Simonis, C. (2008). Seewave: a free modular tool for sound analysis and synthesis. Bioacoustics, 18.

Morgan, T. W., & Elliott, C. L. (2011). Comparison of remotely-triggered cameras vs. howling surveys for estimating coyote (Canis latrans) Abundance in central Kentucky. J Ky Acad Science, 72.

Moons, C., Heleski, C. R., Leece, C. M., & Zanella, A. J. (2002). Conflicting Results in the Association Between Plasma and Salivary Cortisol Levels in Foals.

Abstract: Introduction
Glucocorticoids are present in many biological fluids as a free fraction or bound to Corticoid
Binding Globulins (CBG) (Matteri et al, 2000). There are conflicting claims regarding the validity of
saliva as a biological fluid to measure cortisol in horses (Lebelt et al, 1996; McGreevy and Pell, 1998;
van der Kolk et al, 2001). Measuring changes in salivary cortisol levels in normal horses and horses
with Cushing`s disease van der Kolk and collaborators (2001) demonstrated the validity of saliva to
assess adrenal function. Puzzling results were reported by McGreevy and Pell (1998) who suggested
that plasma and salivary cortisol concentrations in horses showing oral stereotypies were correlated
but this association was non-existent in control animals. Investigating the responses of foals to
branding and foot-trimming Zanella et al (unpublished results) were unable to identify a relationship
between plasma and salivary cortisol levels in foals. In several species, levels of cortisol in plasma and
saliva are tightly correlated (Fenske, 1996). Cortisol found in blood consists of a fraction bound to
corticoid binding globulin (CBG) and a free, unbound fraction. Free cortisol represents the
biologically active fraction of this steroid hormone. Salivary cortisol reflects the unbound fraction
found in plasma or serum and it passes readily through the parotid membrane (Riad-Fahmy, 1983;
Horning Walker et al,1977). Unbound steroids transfer rapidly between plasma and saliva
(Walker,1989; Scott et al 1990). Saliva flow-rate does not appear to influence saliva cortisol levels in
different species (Hubert and de Jong-Meyer, 1989; Walker 1989, Scott et a, 1990). In horses, Lebelt
et al (1996) reported that salivary and plasma total cortisol in stallions were correlated. We
hypothesized that changes in salivary cortisol in foals would show a pattern that is correlated to that of
plasma free and plasma total cortisol concentrations in foals. In addition, we anticipated that the lack
of good sampling techniques provides an explanation for the failure in determining the association
between salivary and plasma cortisol in foals.

https://references.equine-behaviour.de/show.php?record=470