Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
Titulo:

Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
.

Sumario:

Objetivo: Comparar y analizar la correlación entre las concentraciones tiroideas séricas de 6 grupos de equinos (hembras jóvenes vs. machos jóvenes; hembras adultas vs. machos adultos; hembras jóvenes vs. hembras adultas; machos jóvenes vs. machos adultos; hembras vs. machos y jóvenes vs. adultos). Materiales y métodos: Se obtuvieron 99 muestras sanguíneas de caballos en estado de ayuno, diferenciados por género y edad (50 caballos menores de dos años: 25 hembras y 25 machos, y 49 caballos mayores de dos años: 25 hembras y 24 machos). Se determinaron los niveles de TSH y T4L mediante inmunoensayo enzimático. Resultados: Para el grupo de la fracción T4L según edad: jóvenes vs. adultos se encontró una diferencia significativa con... Ver más

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Boletín Científico Centro de Museos Museo de Historia Natural

0123-3068

2462-8190

Osorio, José Henry

Ramírez, Felipe

Pérez, Jorge Enrique

UNIVERSIDAD DE CALDAS

17

2013-07-01

121

126

Colombia

tiroides

metabolismo

caballos

Boletín Científico del Centro de Museos - 2013

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id oai:revistasojs.ucaldas.edu.co:article_4492
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spelling Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
Comparison of thyroid profile in Equus ferus caballus (mammalia: perissodactyla) by gender and age
Objetivo: Comparar y analizar la correlación entre las concentraciones tiroideas séricas de 6 grupos de equinos (hembras jóvenes vs. machos jóvenes; hembras adultas vs. machos adultos; hembras jóvenes vs. hembras adultas; machos jóvenes vs. machos adultos; hembras vs. machos y jóvenes vs. adultos). Materiales y métodos: Se obtuvieron 99 muestras sanguíneas de caballos en estado de ayuno, diferenciados por género y edad (50 caballos menores de dos años: 25 hembras y 25 machos, y 49 caballos mayores de dos años: 25 hembras y 24 machos). Se determinaron los niveles de TSH y T4L mediante inmunoensayo enzimático. Resultados: Para el grupo de la fracción T4L según edad: jóvenes vs. adultos se encontró una diferencia significativa con un p-valor inferior a 0,05 igual a 0,005, con rangos promedio de 0,74 mg/dl jóvenes y 0,59 mg/dl adultos, con un nivel de confianza de 95%. De igual forma en el grupo de hembras jóvenes vs. hembras adultas en la fracción de T4L con rangos de 0,74 mg/dl y 0,56 mg/dl respectivamente, se halló una diferencia estadísticamente significativa con un p-valor inferior a 0,05 igual a 0,01. Para los demás grupos las diferencias en los valores de T4L y TSH, no fueron significativas (P ≥ 0,05).  Conclusiones: Los resultados sugieren que las hembras jóvenes presentan niveles séricos más altos de T4L.
Objective: To compare and analyze the correlation between serum thyroid concentrations of 6 groups of horses (young females vs. young males; adult females vs. adult males; young females vs. adult females; young males vs. adult males; females vs. males, and young vs. adults). Materials and Methods:  Blood samples were obtained from 99 horses in the fasting state, differentiated by gender and age (50 horses under two years: 25 females and 25 males, and 49 horses over two years: 25 females and 24 males). Levels of THS and free T4 were measured by enzymatic immunoassay. Results: For the FT4 by age group: significant difference for young vs. adults was found, with a p-value lower than 0.05 equal to 0.005, with 0.74 mg/dl and 0.59 mg/dl average ranks for young and adults respectively, with a confidence level of 95%. Similarly, statistically significant difference for young females vs. adult females was found in the FT4 fraction ranging from 0.74 mg/dl and 0.56 mg/dl respectively, with a p-value lower than 0.05 equal to 0.01. For the other groups, the differences in FT4 and TSH values ?? were not significant (P ≥ 0.05).  Conclusions: The results suggest that young females present higher FT4 serum levels.
Osorio, José Henry
Ramírez, Felipe
Pérez, Jorge Enrique
tiroides
metabolismo
caballos
thyroid
metabolism
horses
17
2
Núm. 2 , Año 2013 : Julio - Diciembre
Artículo de revista
Journal article
2013-07-01T00:00:00Z
2013-07-01T00:00:00Z
2013-07-01
application/pdf
Boletín Científico
Boletín Científico Centro de Museos Museo de Historia Natural
0123-3068
2462-8190
https://revistasojs.ucaldas.edu.co/index.php/boletincientifico/article/view/4492
https://revistasojs.ucaldas.edu.co/index.php/boletincientifico/article/view/4492
spa
https://creativecommons.org/licenses/by-nc-sa/4.0/
Boletín Científico del Centro de Museos - 2013
121
126
ABRAHAM, G.G. et al., 2011. Serum thyroid hormone, insulin, glucose, triglycerides and protein concentrations in normal horses: Association with topical dexamethasone usage. Vet J., 188: 307-312.
BARAGLI, P. et al., 2011. Early evidence of the anticipatory response of plasma catecholamine in equine exercise. Equine Vet J., 31: 85-88.
BOOSINGER, T.R.; BRENDEMUEHL, J.P.; BRANSBY, D.L. et al. 1995. Prolonged gestation, decreased triiodothyronine concentration, and thyroid gland histomorphologic features in newborn foals of mares grazing Acremonion coenophialum-infected fescue. Am J Vet Res, 56, 66-9
BREUHAUS, B.A., 2011. Disorders of the Equine Thyroid Gland. Vet Clin North Am Equine Pract., 27 (1): 115-128.
BREUHAUS, B.A. & LAFEVERS, D.H. 2005. Thyroid function in normal, sick and premature Foals [abstract]. J Vet Intern Med, 19, 445.
BUFF, P.R. et al., 2007. Seasonal and pulsatile dynamics of thyrotropin and leptin in mares maintained under a constant energy balance. Domestic Animal Endocrinol., 33: 430-436.
CHRISTENSEN, R.A. et al., 1997. Acute effects of short-term feed deprivation and refeeding on circulating concentrations of metabolites, insulin-like growth factor i, insulin-like growth factor binding proteins, somatotropin, and thyroid hormones in adult geldings. J Anim Sci., 75: 1351-1358.
CROCKFORD, S.J., 2003. Thyroid rhythm phenotypes and hominid evolution: a new paradigm implicates pulsatile hormone secretion in speciation and adaptation changes. Comp Biochem Physiol AMol Integr Physiol., 135: 105-129.
DIVERS, J.T., 2008. Endocrine Testing in Horses: Metabolic Syndrome and Cushing's Disease. Equine Vet J., 28 (5): 315-316.
DONALD E.G. GRIESDALE, RUSSELL J. DE SOUZA, ROB M. VAN DAM. et al., 2008. Intensive insulin therapy and mortality among critically ill patients: a meta-analysis including NICE-SUGAR study data. CMAJ. 180(8): 821–827.
DOUGLAS, R. 1999. Circadian cortisol rhythmicity and equine cushing's-like disease. Equine Vet J, 19(11), 684, 750-751, 753.
DUCKETT WM. 1989. Thyroid gland. Equine internal medicine. 917–923.
FAZIO, E. et al., 2007. Total and free iodothyronine levels of growing Thoroughbred foals: Effects of weaning and gender. Livestock Science, 110 (3): 207-213.
FRANK, N. et al., 2002. Equine thyroid dysfunction. Vet Clin Equine, 18: 305-319.
FURR, M.O.; MURRAY, M.J. & FERGUSON, D.C. 1992. The effects of stress on gastric ulceration, T3, T4, reverse T3 and cortisol in neonatal foals. Equine Vet J, 24, 37-40.
HALLERMEIER KM , WU SM, STRATAKIS CA, CHAN CHY, BOURDONY CJ, RENNERT OM, et al., 1998. Genetic heterogeneity of adrenocorticotropin (ACTH) resistance syndromes: identification of a novel mutation of the ACTH receptor genein hereditary glucocorticoid deficiency. Mol Genet Metab., 64:256-65.
HULBERT, A.J., 2000. Thyroid hormones and their effects: a new perspective. Biol. Rev., 75: 519-631.
HURCOMBE, S.D., 2011. Hypothalamic-Pituitary gland axis function and disfunction in horses. Vet Clin Equine, 27: 1-17.
KRATZSCH, J. & PULZER, F., 2008. Thyroid gland development and defects. Best Pract Res Clin Endocrinol Metab., 22 (1): 57-75.
MEDICA, P. et al., 2011. 24-hour endocrine profiles of quarter horses under resting conditions. Equine Vet J., 31: 35-40.
MESSER, N.T. et al., 1998. Thyroid Hormone Levels in Thoroughbred Mares and Their Foals at Parturition. Proceedings of the Annual Convention of the AAEP, 44: 248-251.
TORIBIO, R.E., 2011. Endocrine dysregulation in critically ill foals and horses. Vet Clin North Am Equine Pract., 27 (1): 35-47.
TORIBIO, R.E. & DUCKETT, W.M., 2004. Equine Internal Medicine. Estados Unidos de América: Saunders.
https://revistasojs.ucaldas.edu.co/index.php/boletincientifico/article/download/4492/4125
info:eu-repo/semantics/article
http://purl.org/coar/resource_type/c_6501
info:eu-repo/semantics/publishedVersion
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Text
Publication
institution UNIVERSIDAD DE CALDAS
thumbnail https://nuevo.metarevistas.org/UNIVERSIDADDECALDAS/logo.png
country_str Colombia
collection Boletín Científico Centro de Museos Museo de Historia Natural
title Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
spellingShingle Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
Osorio, José Henry
Ramírez, Felipe
Pérez, Jorge Enrique
tiroides
metabolismo
caballos
thyroid
metabolism
horses
title_short Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
title_full Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
title_fullStr Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
title_full_unstemmed Comparación del perfil tiroideo en Equus ferus caballus (mammalia: perissodactyla) por género y edad
title_sort comparación del perfil tiroideo en equus ferus caballus (mammalia: perissodactyla) por género y edad
title_eng Comparison of thyroid profile in Equus ferus caballus (mammalia: perissodactyla) by gender and age
description Objetivo: Comparar y analizar la correlación entre las concentraciones tiroideas séricas de 6 grupos de equinos (hembras jóvenes vs. machos jóvenes; hembras adultas vs. machos adultos; hembras jóvenes vs. hembras adultas; machos jóvenes vs. machos adultos; hembras vs. machos y jóvenes vs. adultos). Materiales y métodos: Se obtuvieron 99 muestras sanguíneas de caballos en estado de ayuno, diferenciados por género y edad (50 caballos menores de dos años: 25 hembras y 25 machos, y 49 caballos mayores de dos años: 25 hembras y 24 machos). Se determinaron los niveles de TSH y T4L mediante inmunoensayo enzimático. Resultados: Para el grupo de la fracción T4L según edad: jóvenes vs. adultos se encontró una diferencia significativa con un p-valor inferior a 0,05 igual a 0,005, con rangos promedio de 0,74 mg/dl jóvenes y 0,59 mg/dl adultos, con un nivel de confianza de 95%. De igual forma en el grupo de hembras jóvenes vs. hembras adultas en la fracción de T4L con rangos de 0,74 mg/dl y 0,56 mg/dl respectivamente, se halló una diferencia estadísticamente significativa con un p-valor inferior a 0,05 igual a 0,01. Para los demás grupos las diferencias en los valores de T4L y TSH, no fueron significativas (P ≥ 0,05).  Conclusiones: Los resultados sugieren que las hembras jóvenes presentan niveles séricos más altos de T4L.
description_eng Objective: To compare and analyze the correlation between serum thyroid concentrations of 6 groups of horses (young females vs. young males; adult females vs. adult males; young females vs. adult females; young males vs. adult males; females vs. males, and young vs. adults). Materials and Methods:  Blood samples were obtained from 99 horses in the fasting state, differentiated by gender and age (50 horses under two years: 25 females and 25 males, and 49 horses over two years: 25 females and 24 males). Levels of THS and free T4 were measured by enzymatic immunoassay. Results: For the FT4 by age group: significant difference for young vs. adults was found, with a p-value lower than 0.05 equal to 0.005, with 0.74 mg/dl and 0.59 mg/dl average ranks for young and adults respectively, with a confidence level of 95%. Similarly, statistically significant difference for young females vs. adult females was found in the FT4 fraction ranging from 0.74 mg/dl and 0.56 mg/dl respectively, with a p-value lower than 0.05 equal to 0.01. For the other groups, the differences in FT4 and TSH values ?? were not significant (P ≥ 0.05).  Conclusions: The results suggest that young females present higher FT4 serum levels.
author Osorio, José Henry
Ramírez, Felipe
Pérez, Jorge Enrique
author_facet Osorio, José Henry
Ramírez, Felipe
Pérez, Jorge Enrique
topicspa_str_mv tiroides
metabolismo
caballos
topic tiroides
metabolismo
caballos
thyroid
metabolism
horses
topic_facet tiroides
metabolismo
caballos
thyroid
metabolism
horses
citationvolume 17
citationissue 2
citationedition Núm. 2 , Año 2013 : Julio - Diciembre
publisher Boletín Científico
ispartofjournal Boletín Científico Centro de Museos Museo de Historia Natural
source https://revistasojs.ucaldas.edu.co/index.php/boletincientifico/article/view/4492
language spa
format Article
rights https://creativecommons.org/licenses/by-nc-sa/4.0/
Boletín Científico del Centro de Museos - 2013
info:eu-repo/semantics/openAccess
http://purl.org/coar/access_right/c_abf2
references ABRAHAM, G.G. et al., 2011. Serum thyroid hormone, insulin, glucose, triglycerides and protein concentrations in normal horses: Association with topical dexamethasone usage. Vet J., 188: 307-312.
BARAGLI, P. et al., 2011. Early evidence of the anticipatory response of plasma catecholamine in equine exercise. Equine Vet J., 31: 85-88.
BOOSINGER, T.R.; BRENDEMUEHL, J.P.; BRANSBY, D.L. et al. 1995. Prolonged gestation, decreased triiodothyronine concentration, and thyroid gland histomorphologic features in newborn foals of mares grazing Acremonion coenophialum-infected fescue. Am J Vet Res, 56, 66-9
BREUHAUS, B.A., 2011. Disorders of the Equine Thyroid Gland. Vet Clin North Am Equine Pract., 27 (1): 115-128.
BREUHAUS, B.A. & LAFEVERS, D.H. 2005. Thyroid function in normal, sick and premature Foals [abstract]. J Vet Intern Med, 19, 445.
BUFF, P.R. et al., 2007. Seasonal and pulsatile dynamics of thyrotropin and leptin in mares maintained under a constant energy balance. Domestic Animal Endocrinol., 33: 430-436.
CHRISTENSEN, R.A. et al., 1997. Acute effects of short-term feed deprivation and refeeding on circulating concentrations of metabolites, insulin-like growth factor i, insulin-like growth factor binding proteins, somatotropin, and thyroid hormones in adult geldings. J Anim Sci., 75: 1351-1358.
CROCKFORD, S.J., 2003. Thyroid rhythm phenotypes and hominid evolution: a new paradigm implicates pulsatile hormone secretion in speciation and adaptation changes. Comp Biochem Physiol AMol Integr Physiol., 135: 105-129.
DIVERS, J.T., 2008. Endocrine Testing in Horses: Metabolic Syndrome and Cushing's Disease. Equine Vet J., 28 (5): 315-316.
DONALD E.G. GRIESDALE, RUSSELL J. DE SOUZA, ROB M. VAN DAM. et al., 2008. Intensive insulin therapy and mortality among critically ill patients: a meta-analysis including NICE-SUGAR study data. CMAJ. 180(8): 821–827.
DOUGLAS, R. 1999. Circadian cortisol rhythmicity and equine cushing's-like disease. Equine Vet J, 19(11), 684, 750-751, 753.
DUCKETT WM. 1989. Thyroid gland. Equine internal medicine. 917–923.
FAZIO, E. et al., 2007. Total and free iodothyronine levels of growing Thoroughbred foals: Effects of weaning and gender. Livestock Science, 110 (3): 207-213.
FRANK, N. et al., 2002. Equine thyroid dysfunction. Vet Clin Equine, 18: 305-319.
FURR, M.O.; MURRAY, M.J. & FERGUSON, D.C. 1992. The effects of stress on gastric ulceration, T3, T4, reverse T3 and cortisol in neonatal foals. Equine Vet J, 24, 37-40.
HALLERMEIER KM , WU SM, STRATAKIS CA, CHAN CHY, BOURDONY CJ, RENNERT OM, et al., 1998. Genetic heterogeneity of adrenocorticotropin (ACTH) resistance syndromes: identification of a novel mutation of the ACTH receptor genein hereditary glucocorticoid deficiency. Mol Genet Metab., 64:256-65.
HULBERT, A.J., 2000. Thyroid hormones and their effects: a new perspective. Biol. Rev., 75: 519-631.
HURCOMBE, S.D., 2011. Hypothalamic-Pituitary gland axis function and disfunction in horses. Vet Clin Equine, 27: 1-17.
KRATZSCH, J. & PULZER, F., 2008. Thyroid gland development and defects. Best Pract Res Clin Endocrinol Metab., 22 (1): 57-75.
MEDICA, P. et al., 2011. 24-hour endocrine profiles of quarter horses under resting conditions. Equine Vet J., 31: 35-40.
MESSER, N.T. et al., 1998. Thyroid Hormone Levels in Thoroughbred Mares and Their Foals at Parturition. Proceedings of the Annual Convention of the AAEP, 44: 248-251.
TORIBIO, R.E., 2011. Endocrine dysregulation in critically ill foals and horses. Vet Clin North Am Equine Pract., 27 (1): 35-47.
TORIBIO, R.E. & DUCKETT, W.M., 2004. Equine Internal Medicine. Estados Unidos de América: Saunders.
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