Colecalciferol regula os parâmetros hematológicos e a produção de citocinas pró-inflamatórias renais em camundongos diabéticos e nas células RAW 264. 7 / Colecalciferol regulates haematological parameters and the production of renal proinflammatory cytokines in diabetic mice and RAW 264. 7 cells

Os efeitos causados pelo tratamento em conjunto da insulina e do colecalciferol em indivíduos diabéticos não estão completamente elucidados. O presente trabalho avaliou o efeito de ambos os hormônios nos rins, no fígado, no coração e nos parâmetros hematológicos de camundongos machos (C57BL/6) sadios e diabéticos, bem como a ação do colecalciferol (in vitro) na resposta imunológica desenvolvida pelas células RAW 264.7 e pelos macrófagos peritoneais (MP) após estímulo com lipopolissacarídeo (LPS). Após dez dias da administração da aloxana (60 mg/kg), animais diabéticos exibiram redução do ganho de peso corporal e hiperglicemia quando comparados aos animais que receberam salina. No sétimo dia do período experimental, foi verificado que animais diabéticos que não receberam nenhum hormônio, em relação aos não diabéticos, exibiram redução do peso corporal, dos níveis de hemoglobina (Hb), hematócrito, hematimetria, insulina, TNF-α e IL-6 (coração) e aumento da glicemia, da relação peso corpóreo/peso rim esquerdo, das concentrações séricas de ureia, creatinina, Fosfatase Alcalina (FAL), Lactato desidrogenase (LDH) e lactato, fator de necrose tumoral (TNF)-α, interleucina (IL)-6 e IL-10 (no rim); o tratamento com insulina (1 UI/300 mg/dL glicemia), em relação aos animais diabéticos não tratados, promoveu aumento do peso corporal, das concentrações séricas de insulina e redução da glicemia, das concentrações séricas de ureia e da razão TNF-α/IL-10 (coração); o tratamento com colecalciferol (800 UI/dia), em relação aos animais diabéticos não tratados, promoveu aumento das concentrações séricas de 25-hidroxicolecalciferol [25(OH)D], Hb, hematócrito, hematimetria, IL-10 (coração) e reduziu IL-6, IL-10, TNF-α e EPO (rim); os animais diabéticos tratados com insulina, em relação aos animais diabéticos suplementados com colecalciferol apresentaram aumento do peso corpóreo, de ureia sérica, IL-6 e TNF-α (coração) e redução da glicemia, das concentrações séricas de lactato, de IL-6, TNF-α, IL-10 e EPO (rim); os animais -que receberam ambos os hormônios, em relação aos animais tratados com insulina, apresentaram aumento sérico de insulina e lactato; os animais diabéticos que receberam ambos os hormônios, em relação aos animais diabéticos tratados com colecalciferol, exibiram aumento sérico de 25(OH)D, de insulina, além da redução das concentrações de IL-10, da razão de TNF-α/IL-10 e TNF-α/IL-6 (coração); animais diabéticos que receberam ambos os hormônios, em relação aos diabéticos não suplementados com colecalciferol, exibiram: aumento de insulina sérica e redução das concentrações séricas de ureia e das razões renal e hepática de TNF-α/IL-6; células RAW 264.7 estimuladas pelo LPS e tratadas com 100 nM colecalciferol exibiram maior expressão da CYP27B1 e redução na liberação de mediadores inflamatórios quando comparadas ao grupo estimulado pelo LPS. Entretanto, não foi observado o mesmo efeito nos MP. Em conjunto, os resultados sugerem que: 1) em animais diabéticos, o colecalciferol pode modular parâmetros hematológicos e que a insulina pode melhorar a função renal, bem como a recuperação do peso corporal; 2) o colecalciferol pode ser metabolizado pelas células RAW 264.7 e modular a resposta imunológica desencadeada pelo LPS

The effects caused by the treatment of insulin and cholecalciferol in diabetic subjects are not completely elucidated. The present study evaluated the effect of both hormones on the kidneys, liver, heart and hematological parameters of healthy and diabetic male mice (C57BL/6), as well as the action of cholecalciferol (in vitro) on the immune response developed by the cells RAW 264.7 and peritoneal macrophages (MP) after stimulation with lipopolysaccharide (LPS). After ten days of alloxan administration (60 mg/kg), diabetic animals exhibited a reduction in body weight gain and hyperglycemia when compared to animals that received saline. On the seventh day of the experimental period, it was verified that diabetic animals that did not receive any hormones, in relation to non-diabetics, showed reduction of body weight, hemoglobin (Hb), hematocrit, hematimetry, insulin, TNF-α and IL- 6 (heart) and increased glycemia, body weight / left kidney weight, serum urea, creatinine, Phosphatase Alkaline, lactate dehydrogenase (LDH) and lactate levels, tumor necrosis factor (TNF) interleukin (IL) -6 and IL-10 (in the kidney); diabetic mice treated with insulin (1 IU / 300 mg/dL glycemia) in relation to untreated diabetic animals promoted increased body weight, serum insulin levels and blood glucose lowering, serum urea levels and TNF-α ratio / IL-10 (heart); diabetic animals treated with cholecalciferol (800 IU/day), in relation to untreated diabetic animals, exhibited increased serum levels of 25-hydroxycholecalciferol [25 (OH) D], Hb, hematocrit, hematimetry, IL-10 (heart) and reduced IL-6, IL-10, TNF-α and EPO (kidney);insulin-treated diabetic animals compared to diabetic animals supplemented with cholecalciferol exhibited an increase of body weight, serum urea, IL-6 and TNF-α (heart) and a reduction of glycaemia, serum lactate levels, IL-6, TNF- α, IL-10 and EPO (kidney); animals that received both hormones, compared to animals treated with insulin exhibited an increase of insulin and lactate serum levels; diabetic animals that received both hormones, compared to diabetic animals treated with cholecalciferol, exhibited an increase of 25(OH)D and insulin serum levels, and a reduction of IL-10, TNF-α/IL-10 and TNF-α/IL-6 ratios (heart); diabetic animals that received both hormones, compared to diabetic animals not supplemented with cholecalciferol, exhibited an increase of insulin and reduced urea serum levels and reduced renal and hepatic TNF-α/IL-6 ratios; LPS-stimulated RAW 264.7 cells and treated with 100 nM cholecalciferol exhibited greater CYP27B1 expression and reduced release of inflammatory mediators when compared to the LPS-stimulated group. However, the same effect was not observed in PM. Taken together, the results suggest that: 1) in diabetic animals, cholecalciferol may modulate hematological parameters and that insulin may improve renal function as well as recovery of body weight; 2) cholecalciferol can be metabolized by RAW 264.7 cells and modulate the immune response triggered by LPS

Hormonal profile effects following dehydroepiandrosterone (DHEA) administration to schizophrenic patients.

Dehydroepiandrosterone (DHEA) is an important neurosteroid and has demonstrated efficacy in the improvement of mood and energy. The authors previously reported the efficacy of DHEA augmentation in the management of negative, depressive, and anxiety symptoms of schizophrenia. To characterize further the effects of DHEA administration and to describe any hormonal effects following DHEA augmentation of antipsychotic medication, several hormones were measured (TSH, prolactin, testosterone, insulin, and estradiol) in 27 chronic schizophrenic inpatients receiving DHEA or placebo augmentation for 6 weeks. No significant changes in hormonal blood measures were noted. At the study end point, an association was noted between DHEA-S and TSH levels (P < 0.05) as well as a change in DHEA-S and insulin levels (P < 0.001). A modest nonsignificant decrease in plasma testosterone was observed following DHEA treatment. In subjects receiving DHEA, change in testosterone levels was associated with improvement in anxiety (P < 0.05) and illness severity (P < 0.05). Findings in this preliminary study demonstrate minimal effects on hormonal profiles despite the theoretic possibility that DHEA may elevate various hormones (eg, testosterone) with potential long-term adverse effects. DHEA's clinical efficacy appears to be mediated by other mechanisms, including direct effects on membrane channel-coupled receptors.

Persistence of nutritional deficiencies after short-term weight recovery in adolescents with anorexia nervosa.

OBJECTIVES: To study nutritional abnormalities in adolescent anorexia nervosa and to establish whether certain abnormalities persist after short-term refeeding. METHOD: Sixty-one patients (10-19 years old) admitted to a reference unit for eating disorders between 1999 and 2000 with a diagnosis of anorexia nervosa were evaluated at admission and at discharge. A range of biochemical, nutritional, and hormonal parameters were determined. RESULTS: At admission, no protein or lipid deficiencies were found, although many patients presented with hormonal abnormalities and red blood cell folate and zinc deficiencies. Hormonal abnormalities reverted significantly (p <.000) after renutrition. There were decreases in erythrocytes and in levels of hemoglobin (p <.000) and folic acid (p <.05). Red blood cell folate and zinc increased but did not reach normal levels. CONCLUSIONS: In a large proportion of adolescent anorexic patients, supplementation of folic acid and zinc is recommended although protein or hormonal replacement does not seem to be necessary.

Searching for an inhibitory action of blood-borne beta-endorphin on LH release.

Concentrations of beta-endorphin were quantified in peripheral blood plasma of sheep by a radioimmunoassay that cross-reacted with beta-lipotrophin. Plasma concentrations of beta-endorphin increased abruptly after physical confinement, bacteraemia, and electroacupuncture treatment for induction of analgesia. In these experimental situations in which plasma concentrations of beta-endorphin increased, plasma concentrations of LH often decreased. To test the hypothesis that increases in blood-borne beta-endorphin actually caused the decrease in LH release, naloxone was administered to antagonize the opioid receptors at which blood-borne beta-endorphin might act. In no case did administration of naloxone disrupt the temporal correlation between experimentally induced increases in plasma beta-endorphin and decreases in plasma LH. It was concluded that the increases in blood-borne beta-endorphin did not cause the decrease in LH release. Other research investigated whether beta-endorphin might be delivered via blood from pituitary to hypothalamus in locally enriched concentrations. Even when pituitary release of beta-endorphin was acutely stimulated, it was not possible to demonstrate retrograde delivery of beta-endorphin to the hypothalamus without dilution in the systemic circulation. In conclusion, it is unlikely that blood-borne beta-endorphin inhibits the release of LH, and beta-endorphin should not be classified as a hormone until blood concentrations of the peptide can be shown to exert some effect at a location distant from its site of secretion.