[Cost-effectiveness of treatment of type 2 diabetes mellitus in México]. / Costo-efectividad del tratamiento de la diabetes mellitus tipo 2 en México.

Background: Type 2 Diabetes Mellitus (DM2) is a public health and socioeconomic problem, generating direct medical costs for its treatment. Objective: To analyze the cost-effectiveness of monotherapy and bitherapy treatments in patients with DM2. Methods: Cost-effectiveness, observational, ambispective, cross-sectional and analytical analysis of files in a first level medical unit. The data in the cost matrix was executed with the Office Excel 2010 program; the most prescribed drug was identified and compared with monotherapy and bitherapy. Results: The annual direct medical costs of the total population were drug cost $118,561.70MN, hospitalization cost $243,756.00MN, consultation cost $327,414.00MN and clinical trial cost $2416.79MN, obtaining an annual total of $692,148.58MN. metformin was the most indicated in monotherapy (88.4%) and as standard therapy it has higher cost-effectiveness compared to glibenclamide. In bitherapy it was metformin/glibenclamide (35.7%) versus the therapeutics of metformin/NPH insulin, metformin/insulin glargine and metformin/dapagliflozin, which had a better cost-effective result, with an incremental cost effectiveness of -$1,128,428.50MN, -$34,365.00 MN, -$119,848.97MN respectively. Conclusions: Metformin presented a better cost-effectiveness ratio in monotherapy, while in bitherapy it was the metformin/NPH insulin association.

Introducción: La Diabetes Mellitus tipo 2 (DM2) es un problema de salud pública y socioeconómico, tanto por su alta incidencia como por la generación de los costos médicos directos para su tratamiento. Objetivo: Analizar el costo-efectividad de los tratamientos en monoterapia y biterapia en pacientes con DM2. Métodos: Análisis costo-efectividad, observacional, ambispectivo, transversal y analítico. Análisis de expedientes en una unidad médica de primer nivel. Se ejecutaron los datos en la matriz de costos con el programa Office Excel 2010; se identificó el fármaco más prescrito, se comparó con monoterapia y biterapia. Resultados: Los costos médicos directos anuales del total de la población fueron: costo del medicamento $118,561.70MN, costo por hospitalización $243,756.00MN, costo por consultas $ 327,414.00MN y costo por estudios clínicos $2416.79MN, obteniendo un total anual de $692,148.58MN. La metformina fue la más indicada en monoterapia (88.4%) y como terapéutica estándar tiene mayor costo-efectividad comparada con la glibenclamida. En biterapia fue metformina/glibenclamida (35.7%) versus las terapéuticas de metformina/insulina NPH, metformina/insulina glargina y metformina/dapagliflozina, las cuales tuvieron un resultando más costo-efectivo, con un costo efectividad incremental de -$1,128,428.50MN, -$34,365.00MN, -$119,848.97MN respectivamente. Conclusiones: La metformina presento mejor relación costo efectividad en monoterapia, mientras que en biterapia fue la asociación metformina/Insulina NPH.

Ketogenic Diet Provided During Three Months Increases KCC2 Expression but Not NKCC1 in the Rat Dentate Gyrus.

Ketogenic diet, a high fat and low carbohydrate diet, has been used as a non-pharmacological treatment in refractory epilepsy since 1920. In recent years, it has demonstrated to be effective in the treatment of numerous neurological and non-neurological diseases. Some neurological and neuropsychiatric disorders are known to be caused by gamma-aminobutyric acid (GABA)-mediated neurotransmission dysfunction. The strength and polarity of GABA-mediated neurotransmission are determined by the intracellular chloride concentration, which in turn is regulated by cation-chloride cotransporters NKCC1 and KCC2. Currently, it is unknown if the effect of ketogenic diet is due to the modulation of these cotransporters. Thus, we analyzed the effect of a ketogenic diet on the cation-chloride cotransporters expression in the dentate gyrus. We estimated the total number of NKCC1 immunoreactive (NKCC1-IR) neuronal and glial cells by stereology and determined KCC2 labeling intensity by densitometry in the molecular and granule layers as well as in the hilus of dentate gyrus of rats fed with normal or ketogenic diet for 3 months. The results indicated that ketogenic diet provided during 3 months increased KCC2 expression, but not NKCC1 in the dentate gyrus of the rat. The significant increase of KCC2 expression could explain, at least in part, the beneficial effect of ketogenic diet in the diseases where the GABAergic system is altered by increasing its inhibitory efficiency.

Docosahexaenoic acid protection in a rotenone induced Parkinson's model: Prevention of tubulin and synaptophysin loss, but no association with mitochondrial function.

Rotenone, a classic mitochondrial complex I inhibitor, leads to dopaminergic neuronal death resulting in a Parkinson's-like-disease. Docosahexaenoic acid (DHA) has shown neuroprotective effects in other experimental models of Parkinson's disease, but its effect on the rotenone-induced parkinsonism is still unknown. We tested whether DHA in vivo exerts a neuroprotective effect on rotenone-induced parkinsonism and explored the mechanisms involved, including mitochondrial function and ultrastructure as well as the expression of tubulin and synaptophysin. We pretreated eighty male Wistar rats with DHA (35 mg/kg/day) for seven days and then administered rotenone for eight days. We then measured rearing behavior, number of dopaminergic neurons, tyrosine hydroxylase content, tubulin and synaptophysin expression, mitochondrial complex I, respiratory control ratio, mitochondrial transmembrane potential, ATP production activity and mitochondrial ultrastructure. We found that in vivo DHA supply exerted a neuroprotective effect, evidenced by decreased dopaminergic neuron cell death. Although we detected rotenone induced mitochondrial ultrastructure alterations, these were not associated with mitochondrial dysfunction. Rotenone had no effect on mitochondrial complex I, respiratory control ratio, mitochondrial transmembrane potential or ATP production activity. DHA also prevented a rotenone-induced decrease in tubulin and synaptophysin expression. Our results support the neuroprotective effect of DHA on rotenone-induced parkinsonism, and a possible effect on early stage Parkinson's disease. This protective effect is not associated with mitochondrial function improvement, but rather with preventing loss of tubulin and synaptophysin, proteins relevant to synaptic transmission.