Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.

Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.

La obesidad y sus patologías relacionadas son riesgos de salud muy conocidos. Aunque la obesidad y el sobrepeso tienen causas multifactoriales, la sobreingesta de alimento es frecuente en estas condiciones. De acuerdo con modelos animales, los endocanabinoides y sus receptores en el cerebro juegan un papel clave en la génesis y desarrollo de la obesidad. Se ha propuesto que los receptores a canabinoides CB1 (RCB1) expresados en el núcleo accumbensshell (NAcS) están involucrados en el incremento de las propiedades hedónicas del alimento. Para probar esta hipótesis, este estudio tuvo como objetivo evaluar los efectos de la activación de los RCB1 en el NAcS sobre la ingesta de alimento estándar durante la fase de luz del ciclo luz-oscuridad. S... Ver más

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Acta Colombiana de Psicología

0123-9155

1909-9711

Suárez Ortíz, Josué Omar

Escartín Pérez, Rodrigo Erick

López Alonso, Verónica Elsa

Mancilla Díaz, Juan Manuel

Cendejas Trejo, Nancy Mónica

Cortés Salazar, Felipe

UNIVERSIDAD CATÓLICA DE COLOMBIA

10.14718/ACP.2014.17.2.7

17

2014-07-01

61

68

Colombia

Alimentación

Secuencia de saciedad conductual

Núcleo accumbens shell

Canabinoides

info:eu-repo/semantics/openAccess

http://purl.org/coar/access_right/c_abf2

Acta Colombiana de Psicología - 2014

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spelling Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.
Alimentación
Acta Colombiana de Psicología
Universidad Católica de Colombia
Artículo de revista
2
17
Secuencia de saciedad conductual
Núcleo accumbens shell
Canabinoides
Suárez Ortíz, Josué Omar
La obesidad y sus patologías relacionadas son riesgos de salud muy conocidos. Aunque la obesidad y el sobrepeso tienen causas multifactoriales, la sobreingesta de alimento es frecuente en estas condiciones. De acuerdo con modelos animales, los endocanabinoides y sus receptores en el cerebro juegan un papel clave en la génesis y desarrollo de la obesidad. Se ha propuesto que los receptores a canabinoides CB1 (RCB1) expresados en el núcleo accumbensshell (NAcS) están involucrados en el incremento de las propiedades hedónicas del alimento. Para probar esta hipótesis, este estudio tuvo como objetivo evaluar los efectos de la activación de los RCB1 en el NAcS sobre la ingesta de alimento estándar durante la fase de luz del ciclo luz-oscuridad. Se evaluaron los efectos de la activación de los RCB1 con WIN 55-212-2 y CP 55,940 (0.125, 0.25, y 0.5 nmol) en el NAcS sobre la conducta alimentaria y la secuencia de saciedad conductual en ratas. Se encontró que ambos agonistas aumentaron la ingesta de alimento y demoraron la expresión de la saciedad durante la fase de luz. Lo anterior sugiere que los agonistas canabinoides estimulan el consumo de alimento cuando la motivación por el mismo es baja y la palatabilidad es normal.
Escartín Pérez, Rodrigo Erick
López Alonso, Verónica Elsa
Mancilla Díaz, Juan Manuel
Cendejas Trejo, Nancy Mónica
Cortés Salazar, Felipe
Pandolfo, P., Pamplona, F. A., Prediger, R. D. & Takahashi, R. N. (2007). Increased sensitivity of adolescent spontaneously hypertensive rats, an animal model of attention deficit hyperactivity disorder, to the locomotor stimulation induced by the cannabinoid receptor agonist WIN 55,212-2. European Journal of Pharmacology, 563(1–3), 141-148.
González, B., Paz, F., Florán, L., Aceves, J., Erlij, D. & Floran, B. (2009). Cannabinoid agonists stimulate [3H]-GABA release in the globus pallidus of the rat when Gi proteinreceptor coupling is restricted. Journal of Pharmacology and Experimental Therapeutics, 328, 822-828.
Perello, M., Chuang, J., Scott, M. M. & Lutter, M. (2010). Translational Neuroscience approaches to hyperphagia. The Journal of Neuroscience, 30(35), 11549-11554.
Paxinos, G. & Watson, C. (1998). The brain in stereotaxic coordinates. New York: Academic Press.
Guegan, T., Cutando, L., Ayuso, E., Santini, E., Fisone, G., Bosch, F., Martinez, A., Valjent, E., Maldonado, R. & Martina, M. (2013). Operant behavior to obtain palatable food modifies neuronal plasticity in the brain reward circuit. European Neuropsychopharmacology, 23(2), 146-159. Jamshidy, N. & Taylor, D.A. (2001). Anandamide administration into the ventromedial hypothalamus stimulates appetite in rats.British Journal of Pharmacology, 134, 1151-1154.
Nederkoorn, C., Braet, B., Van Eijs, Y., Tanghe, A. & Jansen, A. (2006). Why obese children cannot resist food: The role of impulsivity. Eating Behaviors, 7, 315-322.
Melis, T., Succu, S., Sanna, F., Boi, A., Argiolas, A. & Melis, M. R. (2007). The cannabinoid antagonist SR 141716A (Rimonabant) reduces the increase of extra-cellular dopamine release in the rat nucleus accumbens induced by a novel high palatable food. Neuroscience Letters, 419 (3), 231-235.
Kirkham, T. C., Williams, C. M., Fezza, F., & Di Marzo, V. (2002). Endocannabinoid levels in rat limbic forebrain and hypothalamus in relation to fasting, feeding and satiation: stimulation of eating by 2-arachidonoyl glycerol. British Journal of Pharmacology, 136(4), 550-557.
Ravinet-Trillou, C., Delgorge, C., Menet, C., Arnone, M. & Soubrié, P. (2004). CB1 cannabinoid receptor knockout in mice leads to leanness, resistance to diet-induced obesity and enhanced leptin sensitivity. International Journal of Obesity, 28, 640-648.
Matias, I., Cristino, L. & Di Marzo, V. (2008). Endocannabinoids: Some like it fat (and sweet too). Journal of Neuroendocrinology, 20(1), 100-109.
Maccarrone, M., Gasperi, V., Catani, M. V., Diep, T. A., Dainese, E., Hansen, H. S. & Avigliano, L. (2010). The endocannabinoid system and its relevance for nutrition. Annual Reviews of Nutrition, 30, 423-440.
Quarta C., Bellocchio L., Manzini G., Mazza R., Cervino C., Braulke L., Fekete C., Latorre R., Nanni C., Bucci M., Clemens L., Heldmaier G., Watanabe M., Leste-Lassere T., Maitre M., Tedesco L., FanelliF., Reuss S., KlausS., Srivastava R., Monory K., Valerio A., Grandis A., de Giorgio R., Pasquali R., Nisoli E., Cota D., Lutz B., Marsicano G. & Pagotto U. (2010). CB1 signaling in forebrain and sympathetic neurons is a key Determinant of endocannabinoid actions on energy balance. Cell Metabolism, 11, 273-285.
http://purl.org/redcol/resource_type/ART
Sanudo-Pena, M.C., Patrick, S. L., Patrick, R.L. & Walker, J.M. (1996). Effects of intranigral cannabinoids on rotational behavior in rats: Interactions with the dopaminergic system. Neuroscience Letters, 206, 21-24.
Soria-Gómez, E., Matías, I., Rueda-Orozco, P. E., Cisneros, M., Petrosino, S., Navarro, L. Di Marzo, V. & Próspero-García, O. (2007). Pharmacological enhancement of the endocannabinoid system in the nucleus accumbens shell stimulates food intake and increases c-Fos expression in the hypothalamus. British Journal of Pharmacology, 151, 1109-1116.
Verty, A.N., McGregor, I.S. & Mallet, P.E. (2005). Paraventricular hypothalamic CB(1) cannabinoid receptors are involved in the feeding stimulatory effects of Delta(9)tetrahydrocannabinol. Neuropharmacology, 49 (8), 1101-1109.
info:eu-repo/semantics/article
http://purl.org/coar/resource_type/c_6501
http://purl.org/coar/resource_type/c_2df8fbb1
Gardner, E. L. (2005). Endocannabinoid signaling system and brain reward: Emphasis on dopamine. Pharmacology, Biochemistry and Behavior, 81(2), 263-284.
info:eu-repo/semantics/publishedVersion
http://purl.org/coar/version/c_970fb48d4fbd8a85
info:eu-repo/semantics/openAccess
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Text
Gong, J. P., Onaivi, E. S., Ishiguro, H., Liu, Q. R., Tagliaferro, P. A., Brusco, A. & Uhla, G. R. (2006). Cannabinoid CB2 receptors: Immunohistochemical localization in rat brain. Brain Research, 1071,10-23.
Publication
Escartín-Pérez, R. E., Cendejas-Trejo, N. M., Cruz-Martínez, A. M., González-Hernández B., Mancilla-Díaz, J. M. & Florán-Garduño, B. (2009). Role of cannabinoid CB1 receptors on macronutrient selection and satiety in rats. Physiology and Behavior, 96, 646-650.
Inglés
Behavioral satiety sequence
application/pdf
Nucleus accumbens shell
Drews, E., Schneider, M. & Koch, M. (2005). Effects of the cannabinoid receptor agonist win 55,212-2 on operant behavior and locomotor activity in rats. Pharmacology Biochemistry and Behavior, 80(1),145-150.
https://actacolombianapsicologia.ucatolica.edu.co/article/view/165
Food
Cannabinoids
https://creativecommons.org/licenses/by-nc-sa/4.0/
Acta Colombiana de Psicología - 2014
Effects of CB1 cannabinoid receptor activation in the nucleos accumbens shell on feeding behavior.
Obesity and its related pathologies are well- known health hazards. Although obesity and overweight have multifactorial causes, overeating is common in both of these conditions. According to animal models, endocannabinoids and their receptors in the brain play a key role in the genesis and development of obesity. It has been proposed that the cannabinoid receptors CB1 (RCB1) expressed in the nucleus accumbens shell (NAC) are involved in the increase of the hedonic properties of food. To test this hypothesis, thisstudy aimed to assess the effects of activating the NACs RCB1 on standard food intake during the light phase of the light-dark cycle. The effects of activating the RCB1 with CP 55,940 and WIN 55-212-2 (0.125, 0.25 and 0.5 nmol) in the NACS on feeding behavior and the behavioral satiety sequence of rats were assessed. It wasfound that both agonists increased food intake and delayed expression of satiety during the light phase. These results suggest that cannabinoid agonists encourage food intake when motivation is low and palatability is normal.
Bassareo, V. & Di Chiara, G. (1999). Modulation of feedinginduced activation of mesolimbic dopamine transmission by appetitive stimuli and its relation to motivational state. European Journal of Neuroscience, 11(12), 4389-4397.
Berner, L. A., Avena, N. M. & Hoebel, B. G. (2008). Bingeing, self-restriction, and increased body weight in rats with limited access to a sweet-fat diet. Obesity (Silver Spring) 16,1998-2002. Cota, D., Marsicano, G., Tschöp, M., Grübler, Y., Flachskamm, C., Schubert, M., Auer, D., Yassouridis, A., Thöne-Reineke, C., Ortmann, S., Tomassoni, F., Cervino, C., Nisoli, E., Linthorst, A. C., Pasquali, R., Lutz, B., Stalla, G. K. & Pagotto, U. (2003). The endogenous cannabinoid system affects energy balance via central orexigenic drive and peripheral lipogenesis. Journal of Clinical Investigation, 112, 423-431.
Di Patrizio, N. V. & Simansky, K. J. (2008). Activating parabrachial cannabinoid CB1 receptors selectively stimulates feeding of palatable foods in rats.Journal of Neuroscience, 28(39),9702-9709.
Dimitriou, S. G., Rice, H. B. & Corwin, R. L. (2000). Effects of limited access to a fat option on food intake and body composition in female rats. International Journal of Eating Disorders, 28,436-445.
Journal article
2014-07-01T00:00:00Z
1909-9711
2014-07-01T00:00:00Z
2014-07-01
https://actacolombianapsicologia.ucatolica.edu.co/article/download/165/205
0123-9155
10.14718/ACP.2014.17.2.7
https://doi.org/10.14718/ACP.2014.17.2.7
68
61
institution UNIVERSIDAD CATÓLICA DE COLOMBIA
thumbnail https://nuevo.metarevistas.org/UNIVERSIDADCATOLICADECOLOMBIA/logo.png
country_str Colombia
collection Acta Colombiana de Psicología
title Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.
spellingShingle Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.
Suárez Ortíz, Josué Omar
Escartín Pérez, Rodrigo Erick
López Alonso, Verónica Elsa
Mancilla Díaz, Juan Manuel
Cendejas Trejo, Nancy Mónica
Cortés Salazar, Felipe
Alimentación
Secuencia de saciedad conductual
Núcleo accumbens shell
Canabinoides
Behavioral satiety sequence
Nucleus accumbens shell
Food
Cannabinoids
title_short Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.
title_full Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.
title_fullStr Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.
title_full_unstemmed Efectos de la activación del receptor cannabinoide CB1 en el núcleo accumbens shell sobre la conducta alimentaria.
title_sort efectos de la activación del receptor cannabinoide cb1 en el núcleo accumbens shell sobre la conducta alimentaria.
title_eng Effects of CB1 cannabinoid receptor activation in the nucleos accumbens shell on feeding behavior.
description La obesidad y sus patologías relacionadas son riesgos de salud muy conocidos. Aunque la obesidad y el sobrepeso tienen causas multifactoriales, la sobreingesta de alimento es frecuente en estas condiciones. De acuerdo con modelos animales, los endocanabinoides y sus receptores en el cerebro juegan un papel clave en la génesis y desarrollo de la obesidad. Se ha propuesto que los receptores a canabinoides CB1 (RCB1) expresados en el núcleo accumbensshell (NAcS) están involucrados en el incremento de las propiedades hedónicas del alimento. Para probar esta hipótesis, este estudio tuvo como objetivo evaluar los efectos de la activación de los RCB1 en el NAcS sobre la ingesta de alimento estándar durante la fase de luz del ciclo luz-oscuridad. Se evaluaron los efectos de la activación de los RCB1 con WIN 55-212-2 y CP 55,940 (0.125, 0.25, y 0.5 nmol) en el NAcS sobre la conducta alimentaria y la secuencia de saciedad conductual en ratas. Se encontró que ambos agonistas aumentaron la ingesta de alimento y demoraron la expresión de la saciedad durante la fase de luz. Lo anterior sugiere que los agonistas canabinoides estimulan el consumo de alimento cuando la motivación por el mismo es baja y la palatabilidad es normal.
description_eng Obesity and its related pathologies are well- known health hazards. Although obesity and overweight have multifactorial causes, overeating is common in both of these conditions. According to animal models, endocannabinoids and their receptors in the brain play a key role in the genesis and development of obesity. It has been proposed that the cannabinoid receptors CB1 (RCB1) expressed in the nucleus accumbens shell (NAC) are involved in the increase of the hedonic properties of food. To test this hypothesis, thisstudy aimed to assess the effects of activating the NACs RCB1 on standard food intake during the light phase of the light-dark cycle. The effects of activating the RCB1 with CP 55,940 and WIN 55-212-2 (0.125, 0.25 and 0.5 nmol) in the NACS on feeding behavior and the behavioral satiety sequence of rats were assessed. It wasfound that both agonists increased food intake and delayed expression of satiety during the light phase. These results suggest that cannabinoid agonists encourage food intake when motivation is low and palatability is normal.
author Suárez Ortíz, Josué Omar
Escartín Pérez, Rodrigo Erick
López Alonso, Verónica Elsa
Mancilla Díaz, Juan Manuel
Cendejas Trejo, Nancy Mónica
Cortés Salazar, Felipe
author_facet Suárez Ortíz, Josué Omar
Escartín Pérez, Rodrigo Erick
López Alonso, Verónica Elsa
Mancilla Díaz, Juan Manuel
Cendejas Trejo, Nancy Mónica
Cortés Salazar, Felipe
topicspa_str_mv Alimentación
Secuencia de saciedad conductual
Núcleo accumbens shell
Canabinoides
topic Alimentación
Secuencia de saciedad conductual
Núcleo accumbens shell
Canabinoides
Behavioral satiety sequence
Nucleus accumbens shell
Food
Cannabinoids
topic_facet Alimentación
Secuencia de saciedad conductual
Núcleo accumbens shell
Canabinoides
Behavioral satiety sequence
Nucleus accumbens shell
Food
Cannabinoids
citationvolume 17
citationissue 2
publisher Universidad Católica de Colombia
ispartofjournal Acta Colombiana de Psicología
source https://actacolombianapsicologia.ucatolica.edu.co/article/view/165
language Inglés
format Article
rights info:eu-repo/semantics/openAccess
http://purl.org/coar/access_right/c_abf2
https://creativecommons.org/licenses/by-nc-sa/4.0/
Acta Colombiana de Psicología - 2014
references_eng Pandolfo, P., Pamplona, F. A., Prediger, R. D. & Takahashi, R. N. (2007). Increased sensitivity of adolescent spontaneously hypertensive rats, an animal model of attention deficit hyperactivity disorder, to the locomotor stimulation induced by the cannabinoid receptor agonist WIN 55,212-2. European Journal of Pharmacology, 563(1–3), 141-148.
González, B., Paz, F., Florán, L., Aceves, J., Erlij, D. & Floran, B. (2009). Cannabinoid agonists stimulate [3H]-GABA release in the globus pallidus of the rat when Gi proteinreceptor coupling is restricted. Journal of Pharmacology and Experimental Therapeutics, 328, 822-828.
Perello, M., Chuang, J., Scott, M. M. & Lutter, M. (2010). Translational Neuroscience approaches to hyperphagia. The Journal of Neuroscience, 30(35), 11549-11554.
Paxinos, G. & Watson, C. (1998). The brain in stereotaxic coordinates. New York: Academic Press.
Guegan, T., Cutando, L., Ayuso, E., Santini, E., Fisone, G., Bosch, F., Martinez, A., Valjent, E., Maldonado, R. & Martina, M. (2013). Operant behavior to obtain palatable food modifies neuronal plasticity in the brain reward circuit. European Neuropsychopharmacology, 23(2), 146-159. Jamshidy, N. & Taylor, D.A. (2001). Anandamide administration into the ventromedial hypothalamus stimulates appetite in rats.British Journal of Pharmacology, 134, 1151-1154.
Nederkoorn, C., Braet, B., Van Eijs, Y., Tanghe, A. & Jansen, A. (2006). Why obese children cannot resist food: The role of impulsivity. Eating Behaviors, 7, 315-322.
Melis, T., Succu, S., Sanna, F., Boi, A., Argiolas, A. & Melis, M. R. (2007). The cannabinoid antagonist SR 141716A (Rimonabant) reduces the increase of extra-cellular dopamine release in the rat nucleus accumbens induced by a novel high palatable food. Neuroscience Letters, 419 (3), 231-235.
Kirkham, T. C., Williams, C. M., Fezza, F., & Di Marzo, V. (2002). Endocannabinoid levels in rat limbic forebrain and hypothalamus in relation to fasting, feeding and satiation: stimulation of eating by 2-arachidonoyl glycerol. British Journal of Pharmacology, 136(4), 550-557.
Ravinet-Trillou, C., Delgorge, C., Menet, C., Arnone, M. & Soubrié, P. (2004). CB1 cannabinoid receptor knockout in mice leads to leanness, resistance to diet-induced obesity and enhanced leptin sensitivity. International Journal of Obesity, 28, 640-648.
Matias, I., Cristino, L. & Di Marzo, V. (2008). Endocannabinoids: Some like it fat (and sweet too). Journal of Neuroendocrinology, 20(1), 100-109.
Maccarrone, M., Gasperi, V., Catani, M. V., Diep, T. A., Dainese, E., Hansen, H. S. & Avigliano, L. (2010). The endocannabinoid system and its relevance for nutrition. Annual Reviews of Nutrition, 30, 423-440.
Quarta C., Bellocchio L., Manzini G., Mazza R., Cervino C., Braulke L., Fekete C., Latorre R., Nanni C., Bucci M., Clemens L., Heldmaier G., Watanabe M., Leste-Lassere T., Maitre M., Tedesco L., FanelliF., Reuss S., KlausS., Srivastava R., Monory K., Valerio A., Grandis A., de Giorgio R., Pasquali R., Nisoli E., Cota D., Lutz B., Marsicano G. & Pagotto U. (2010). CB1 signaling in forebrain and sympathetic neurons is a key Determinant of endocannabinoid actions on energy balance. Cell Metabolism, 11, 273-285.
Sanudo-Pena, M.C., Patrick, S. L., Patrick, R.L. & Walker, J.M. (1996). Effects of intranigral cannabinoids on rotational behavior in rats: Interactions with the dopaminergic system. Neuroscience Letters, 206, 21-24.
Soria-Gómez, E., Matías, I., Rueda-Orozco, P. E., Cisneros, M., Petrosino, S., Navarro, L. Di Marzo, V. & Próspero-García, O. (2007). Pharmacological enhancement of the endocannabinoid system in the nucleus accumbens shell stimulates food intake and increases c-Fos expression in the hypothalamus. British Journal of Pharmacology, 151, 1109-1116.
Verty, A.N., McGregor, I.S. & Mallet, P.E. (2005). Paraventricular hypothalamic CB(1) cannabinoid receptors are involved in the feeding stimulatory effects of Delta(9)tetrahydrocannabinol. Neuropharmacology, 49 (8), 1101-1109.
Gardner, E. L. (2005). Endocannabinoid signaling system and brain reward: Emphasis on dopamine. Pharmacology, Biochemistry and Behavior, 81(2), 263-284.
Gong, J. P., Onaivi, E. S., Ishiguro, H., Liu, Q. R., Tagliaferro, P. A., Brusco, A. & Uhla, G. R. (2006). Cannabinoid CB2 receptors: Immunohistochemical localization in rat brain. Brain Research, 1071,10-23.
Escartín-Pérez, R. E., Cendejas-Trejo, N. M., Cruz-Martínez, A. M., González-Hernández B., Mancilla-Díaz, J. M. & Florán-Garduño, B. (2009). Role of cannabinoid CB1 receptors on macronutrient selection and satiety in rats. Physiology and Behavior, 96, 646-650.
Drews, E., Schneider, M. & Koch, M. (2005). Effects of the cannabinoid receptor agonist win 55,212-2 on operant behavior and locomotor activity in rats. Pharmacology Biochemistry and Behavior, 80(1),145-150.
Bassareo, V. & Di Chiara, G. (1999). Modulation of feedinginduced activation of mesolimbic dopamine transmission by appetitive stimuli and its relation to motivational state. European Journal of Neuroscience, 11(12), 4389-4397.
Berner, L. A., Avena, N. M. & Hoebel, B. G. (2008). Bingeing, self-restriction, and increased body weight in rats with limited access to a sweet-fat diet. Obesity (Silver Spring) 16,1998-2002. Cota, D., Marsicano, G., Tschöp, M., Grübler, Y., Flachskamm, C., Schubert, M., Auer, D., Yassouridis, A., Thöne-Reineke, C., Ortmann, S., Tomassoni, F., Cervino, C., Nisoli, E., Linthorst, A. C., Pasquali, R., Lutz, B., Stalla, G. K. & Pagotto, U. (2003). The endogenous cannabinoid system affects energy balance via central orexigenic drive and peripheral lipogenesis. Journal of Clinical Investigation, 112, 423-431.
Di Patrizio, N. V. & Simansky, K. J. (2008). Activating parabrachial cannabinoid CB1 receptors selectively stimulates feeding of palatable foods in rats.Journal of Neuroscience, 28(39),9702-9709.
Dimitriou, S. G., Rice, H. B. & Corwin, R. L. (2000). Effects of limited access to a fat option on food intake and body composition in female rats. International Journal of Eating Disorders, 28,436-445.
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