ABSTRACT
El Sndrome Metablico (SM) se ha asociado recientemente con una disminucin en la densidad mineral sea, y con un aumento en la incidencia de fracturas osteoporticas. Recientemente encontramos que la Metformina por va oral en ratas, promueve la diferenciacin osteognica de clulas progenitoras de mdula sea e incrementa la reparacin de lesiones seas. En este trabajo evaluamos los efectos del SM inducido por Fructosa sobre la microarquitectura sea en ratas, y la modulacin de estos efectos por Metformina administrada en forma oral. Utilizamos ratas Sprague Dawley macho jvenes: C (control sin tratamiento), C+M (100mg/kg/da Metformina en el agua de bebida), F (10 % Fructosa en el agua de bebida) y F+M (Fructosa+Metformina en el agua de bebida). Los tratamientos se continuaron por 3 semanas luego de lo cual se tomaron muestras de sangre, previas al sacrificio de los animales. Se disecaron los fmures para evaluacin histomorfomtrica de la microarquitectura metafisaria por tincin con Hematoxilina-Eosina (H-E). Se observ un incremento en la glucemia y trigliceridemia en el grupo F versus el C, compatible con el desarrollo de SM. El anlisis de las metfisis femorales mostr un aumento en la densidad osteoctica trabecular para el grupo C+M (118 % del control, p<0,05). El tratamiento con Fructosa sola disminuy la densidad osteoctica (79 % del control, p<0,05), mientras que el co-tratamiento Fructosa+Metformina (grupo F+M) revirti parcialmente este descenso (88 % del control). Similarmente, el porcentaje de hueso trabecular en la metfisis femoral aument luego del tratamiento slo con Metformina (129 % respecto del control), se redujo en las ratas tratadas con Fructosa (89 % respecto del control), y fue intermedia en el grupo F+M (94 % respecto del control). Estos resultados muestran que el SM inducido por Fructosa en ratas altera la microarquitectura metafisaria femoral; y que estos efectos deletreos pueden ser parcialmente prevenidos por un tratamiento oral con Metformina.
Several clinical studies have demonstrated that the Metabolic Syndrome (MS) is associated with a decrease in bone mineral density, and with an increased risk for non-vertebral osteoporotic fractures. We have recently found that orally administered Metformin induces osteogenic effects in rats, promoting osteoblastic differentiation of bone marrow progenitor cells and increasing the repair of bone lesions. In the present work we have evaluated the effects of Fructose-induced MS on bone micro-architecture in rats, and the possible modulation of these effects by orally administered Metformin. We utilized young male Sprague-Dawley rats, divided into four groups: C (non-treated controls); C+M (100 mg/kg/day of Metformin in drinking water); F (10 % of Fructose in drinking water); and F+M (Fructose+Metformin in drinking water). After three weeks of all treatments blood samples were taken, after which animals were sacrificed by cervical dislocation under anaesthesia. Femurs were then dissected for evaluation of metaphyseal micro-architecture after Haematoxilin-Eosin staining of 5 μm histological slices of decalcified bone. In particular, osteocytic density and relative trabecular volume were determined. An increase in serum glucose and triglycerides was observed in Fructose-treated rats, in accordance with the development of MS. In rats treated with Metformin alone (group C+M), the analysis of femoral metaphyses showed an increase in trabecular osteocytic density (118 % of control [group C], p<0.05). Treatment with Fructose alone (group F) significantly decreased ostecytic density (79 % of control, p<0.05), while co-treatment with Fructose and Metformin partially reverted this decrease (group F+M, 88 % of control). Similarly, the relative trabecular volume of femoral metaphysic was increased by treatment with Metformin alone (129% of control), was reduced in Fructose-treated rats (89 % of control), and tended to revert back to control values after Fructose-Metformin co-treatment (94 % of control). These results show for the first time that (a) Fructose-induced MS in rats alters their femoral metaphysis micro-architecture; and that (b) these deleterious effects can be partially prevented by orally administered Metformin.