Effect of 5'-adenosine monophosphate-activated protein kinase agonists on insulin and glucose dynamics in experimentally induced insulin dysregulation in horses.

BACKGROUND: 5'-adenosine monophosphate-activated protein kinase (AMPK) agonists, particularly resveratrol (RES), have not been extensively evaluated for their effect on insulin dysregulation (ID) in horses. OBJECTIVES: Evaluate the effects of treatment with RES (10 mg/kg PO q12h), metformin (MET; 30 mg/kg PO q12h), and aspirin (ASP; 20 mg/kg PO q24h) on experimentally induced ID. ANIMALS: Thirty-three healthy, adult, light-breed horses. METHODS: Unblinded, placebo-controlled, experimental trial evaluating effects of AMPK agonists (RES, MET, and ASP) on experimentally induced ID. Horses were randomly assigned to a treatment group (RES, MET/ASP, RES/ASP, RES/MET/ASP, or placebo [CON]) after induction of ID with dexamethasone (0.08 mg/kg PO q24h for 7 days). Frequently sampled insulin-modified IV glucose tolerance tests (FSIGTT) and oral sugar tests (OST) were performed at baseline, 7 days after ID, and ID plus 7 days of treatment. Minimal model and OST variables were compared between (1-way ANOVA) and within (1-way ANOVA for repeated measures) groups over time to determine effects of treatment on ID. RESULTS: Administration of dexamethasone for 14 days resulted in significantly altered insulin and glucose dynamics (SI, DI, basal [glucose], and [insulin]) and produced clinical signs of laminitis in 5 out of 33 (15%) of horses included in the study. Combination therapy with RES, MET, and ASP did not significantly improve insulin and glucose dynamics in horses with experimentally induced ID. CONCLUSIONS AND CLINICAL IMPORTANCE: Metabolic testing before glucocorticoid administration should be considered in horses with clinical signs of metabolic syndrome.

Diagnostic evaluation of insulin and glucose dynamics in light-breed horses receiving dexamethasone.

Objective: Insulin dysregulation is a hallmark of equine metabolic syndrome (EMS) and increases the risk for development of laminitis. Accurate diagnosis of insulin dysregulation is crucial for implementation of preventative strategies in this population. The objective was to assess the effects of dexamethasone administration on insulin and glucose dynamics in light-breed horses and assess the agreement of various diagnostic tests for insulin dysregulation [basal [insulin] (BI), oral sugar test (OST), and combined glucose-insulin test (CGIT)]. Animal: Fourteen adult light-breed horses. Procedure: Prospective, experimental study to assess insulin and glucose dynamics by performing basal insulin, OST, and CGIT before (baseline) and post-dexamethasone administration (0.08 mg/kg, PO, q24h) for 7 d. Insulin and glucose dynamics were assessed by the BI, OST, CGIT, and insulin sensitivity proxy measurements (RISQI, QUICKI, FGIR, HOMA-IR, IG) at the baseline and post-dexamethasone time points. Results: The OST area under the insulin and glucose curves were increased following dexamethasone treatment (P < 0.001 and P < 0.01, respectively). Basal insulin, OST [insulin] at 60 min and CGIT [insulin] at 45 min were increased at the post-dexamethasone time point (P < 0.001, < 0.001, and < 0.01). Similarly, time spent in the positive glucose phase during the CGIT was longer at the post-dexamethasone time point (P < 0.001). The proxy measurements for insulin sensitivity (RISQI, QUICKI, FGIR) were decreased (P < 0.01) and the proxy measurements for insulin resistance (HOMA-IR) and ß-cell function (IG) were increased after dexamethasone administration (P < 0.01). More horses were classified with following dexamethasone administration, based on the diagnostic criteria for basal insulin (P = 0.03), OST (P = 0.01), and CGIT (P < 0.01). Kappa coefficients, measuring agreement between basal insulin, OST, and CGIT, showed none to moderate agreement at the baseline time point. Conclusion: Dexamethasone administration at 0.08 mg/kg, PO, q24h for 7 d worsened insulin dysregulation in adult light-breed horses based on findings of a basal insulin, OST, CGIT, and insulin sensitivity proxy measurements. There was none to moderate agreement between the basal insulin, OST, CGIT for the diagnosis of insulin dysregulation. Clinical relevance: Horses administered dexamethasone at a dose of 0.08 mg/kg, PO, q24h for 7 d should be considered insulin dysregulation and appropriate preventative strategies should be implemented. The variability of diagnostic performance of common tests for insulin dysregulation (basal insulin, OST, CGIT) may affect clinical decisions; therefore, performing multiple tests, including proxy measurements, may improve diagnostic accuracy of insulin dysregulation.

Objectif: La dysrégulation de l'insuline est une caractéristique du syndrome métabolique équin (EMS) et augmente le risque de développement de la fourbure. Un diagnostic précis de la dysrégulation de l'insuline est crucial pour la mise en oeuvre de stratégies préventives dans cette population. L'objectif était d'évaluer les effets de l'administration de dexaméthasone sur la dynamique de l'insuline et du glucose chez les chevaux de race légère et d'évaluer la concordance de divers tests de diagnostic pour le dérèglement de l'insuline [insuline basale] (BI), test de sucre oral (OST) et un test glucose-insuline combiné (CGIT). Animal: Quatorze chevaux adultes de race légère. Procédure: Étude prospective et expérimentale pour évaluer la dynamique de l'insuline et du glucose en effectuant l'insuline basale, l'OST et le CGIT avant (valeur de base) et après l'administration de dexaméthasone (0,08 mg/kg, PO, q24h) pendant 7 jours. La dynamique de l'insuline et du glucose a été évaluée par les mesures indirectes de BI, de l'OST, du CGIT et de la sensibilité à l'insuline (RISQI, QUICKI, FGIR, HOMA-IR, IG) aux points temporels de base et post-dexaméthasone. Résultats: La zone OST sous les courbes d'insuline et de glucose a augmenté après le traitement à la dexaméthasone (P < 0,001 et P < 0,01, respectivement). L'insuline basale, l'OST [insuline] à 60 minutes et le CGIT [insuline] à 45 minutes ont augmenté au point temporel post-dexaméthasone (P < 0,001, < 0,001 et < 0,01). De même, le temps passé dans la phase de glucose positif pendant le CGIT était plus long au moment post-dexaméthasone (P < 0,001). Les mesures indirectes de la sensibilité à l'insuline (RISQI, QUICKI, FGIR) ont diminué (P < 0,01) et les mesures indirectes de la résistance à l'insuline (HOMA-IR) et de la fonction des cellules ß (IG) ont augmenté après l'administration de dexaméthasone (P < 0,01). Plus de chevaux ont été classés avec l'administration suivante de dexaméthasone, sur la base des critères de diagnostic de l'insuline basale (P = 0,03), OST (P = 0,01) et CGIT (P < 0,01). Les coefficients Kappa, mesurant la concordance entre l'insuline basale, l'OST et le CGIT, ont montré une concordance nulle à modérée au point de référence. Conclusion: L'administration de dexaméthasone à 0,08 mg/kg, PO, toutes les 24 h pendant 7 jours a aggravé la dysrégulation de l'insuline chez les chevaux adultes de race légère d'après les résultats d'une insuline basale, d'OST, de CGIT et de mesures indirectes de la sensibilité à l'insuline. Il n'y avait aucun accord à modéré entre l'insuline basale, l'OST, le CGIT pour le diagnostic de dysrégulation de l'insuline. Pertinence clinique: Les chevaux ayant reçu de la dexaméthasone à une dose de 0,08 mg/kg, PO, q24h pendant 7 jours doivent être considérés comme ayant un dérèglement de l'insuline et des stratégies préventives appropriées doivent être mises en oeuvre. La variabilité des performances diagnostiques des tests courants de dysrégulation de l'insuline (insuline basale, OST, CGIT) peut affecter les décisions cliniques; par conséquent, la réalisation de plusieurs tests, y compris des mesures indirectes, peut améliorer la précision du diagnostic du dérèglement de l'insuline.(Traduit par Dr Serge Messier).

Multiple adrenocortical steroid response to administration of exogenous adrenocorticotropic hormone to hospitalized foals.

BACKGROUND: The hypothalamic-pituitary-adrenal axis regulates the response to sepsis-associated stress. Relative adrenal insufficiency or adrenocorticotropic hormone (ACTH):cortisol imbalance, defined as a poor cortisol response to administration of ACTH, is common and associated with death in hospitalized foals. However, information on other adrenal steroid response to ACTH stimulation in sick foals is minimal. OBJECTIVE: To investigate the response of multiple adrenocortical steroids to administration of ACTH in foals. ANIMALS: Hospitalized (n = 34) and healthy (n = 13) foals. METHODS: In this prospective study, hospitalized foals were categorized into 2 groups using cluster analysis based on adrenal steroids response to ACTH stimulation: Cluster 1 (n = 11) and Cluster 2 (n = 23). After baseline blood sample collection, foals received 10 µg of ACTH with additional samples collected at 30 and 90 minutes after ACTH. Steroid and ACTH concentrations were determined by immunoassays. The area under the curve (AUC) and Delta0-30 were calculated for each hormone. RESULTS: The AUC for cortisol, aldosterone, androstenedione, pregnenolone, 17α-OH-progesterone, and progesterone were higher in critically ill (Cluster 1) compared to healthy foals (P < .01). Delta0-30 for cortisol and 17α-OH-progesterone was lower in Cluster 1 (24%, 26.7%) and Cluster 2 (16%, 11.2%) compared to healthy foals (125%, 71%), respectively (P < .05). Foals that died had increased AUC for endogenous ACTH (269 versus 76.4 pg/mL/h, P < .05) accompanied by a low AUC for cortisol (5.5 versus 15.5 µg/dL/h, P < .05), suggesting adrenocortical dysfunction. CONCLUSION AND CLINICAL IMPORTANCE: The 17α-OH-progesterone response to administration of ACTH was a good predictor of disease severity and death in hospitalized foals.