Monosodium Glutamate Dietary Consumption Decreases Pancreatic β-Cell Mass in Adult Wistar Rats

In newborn mice subcutaneous injectionis of monosodium glutamate induced acute neuronal necrosis in several regions of developing brain including the hypothanamus. As adults, treated animals showed stunted skeletal development, marked obesity, and female sterility. Pathological changes were also found in several organs associated with endocrine function. Studies of food consumption failed to demonstrate hyperphagia to explain the obesity. It is postulated that the aduls syndrome represents a multifacted nueroendocrine disturbance arising from the disruption of developing nueral centers concered in the mediation of endocrine function.

Update of the Hohenheim consensus on monosodium glutamate from 1997: Summary and evaluation of recent knowledge with respect to physiology and safety of monosodium glutamate. Experts from a range of relevant disciplines received and considered a series of questions related to aspects of the topic. University of Hohenheim, Stuttgart, Germany. The experts met and discussed the questions and arrived at a consensus. Total intake of glutamate from food in European countries is generally stable and ranged from 5 to 12 g/day (free: ca. 1 g, protein-bound: ca. 10 g, added as flavor: ca. 0.4 g). L-Glutamate (GLU) from all sources is mainly used as energy fuel in enterocytes. A maximum intake of 6.000 [corrected] mg/kg body weight is regarded as safe. The general use of glutamate salts (monosodium-L-glutamate and others) as food additive can, thus, be regarded as harmless for the whole population. Even in unphysiologically high doses GLU will not trespass into fetal circulation. Further research work should, however, be done concerning the effects of high doses of a bolus supply at presence of an impaired blood brain barrier function. In situations with decreased appetite (e.g., elderly persons) palatability can be improved by low dose use of monosodium-L-glutamate.

Due to the high prevalence of diabetes worldwide, extensive research is still being performed to develop new antidiabetic agents and determine their mechanisms of action. Consequently, a number of diabetic animal models have been developed and improved over the years, of which rodent models are the most thoroughly described. These rodent models can be classified into two broad categories: 1) genetically induced spontaneous diabetes models; and 2) experimentally induced nonspontaneous diabetes models. The popularity of using experimentally induced nonspontaneous models for diabetes research over that of the genetically induced spontaneous models is due to their comparatively lower cost, ease of diabetes induction, ease of maintenance and wider availability. The various experimentally induced type 2 diabetes (T2D) rodent models developed over the last 30-plus years for both routine pharmacological screening and mechanistic diabetes-linked research trials include: adult streptozotocin (STZ)/alloxan rat models, neonatal STZ/alloxan models, partial pancreatectomy models, long-term high-fat (HF) diet-fed models, HF diet-fed STZ models, nicotinamide/STZ models, intrauterine growth retardation (IUGR) models, the STZ-induced progressive diabetic model and monosodium glutamate (MSG)-induced model. The use of these models, however, is not without limitations. A T2D model should ideally portray an identical biochemical blood profile and pathogenesis to T2D in humans. Hence, this review will comparatively evaluate experimentally induced rodent T2D models considering the above-mentioned criteria, in order to guide diabetes research groups to more accurately select the most appropriate models given their specific research requirements. Copyright 2009 Prous Science, S.A.U. or its licensors. All rights reserved.