1 The discovery of insulin in 1921 rather spoilt this line of res

1 The discovery of insulin in 1921 rather spoilt this line of research, and scientists and clinicians subsequently

became overly focused on defective Selleckchem Y27632 insulin secretion and action, meaning that the pancreatic islet cell overshadowed the brain as the centre of our understanding of diabetes and the target for therapeutic intervention. The problem with this approach is that it serves to control rather than cure the disease.2 Insulin-independent mechanisms account for approximately 50% of overall glucose disposal, but we know very little about them. Sometimes described as ‘glucose effectiveness’, there is a growing research body which suggests that the brain is in control of dynamically regulating the process of glucose control in order to improve and normalise dysglycaemia. Indeed, defects in such mechanisms are postulated as contributory causes to the emergence of diabetes, an example of which was outlined

in a recent leader in this journal ‘Type 3 Diabetes’ on the relationship between Alzheimer’s and diabetes.3 What then is the evidence for a brain-centred gluco-regulatory system (BCGS)? There is a growing research literature establishing the role of the brain in glucose homeostasis. This can be as a direct effect of insulin action – injection of insulin into discrete hypothalamic areas can lower blood glucose levels and increase liver insulin sensitivity,4 and this has been confirmed by deletion click here of hypothalamic insulin receptors causing glucose intolerance and systemic insulin resistance.5 On the other hand, it has recently become clear that there are insulin-independent mechanisms through which the brain influences glycaemic control. For example, there have been several animal models demonstrating the effects of leptin acting centrally to normalise blood glucose even in the context of severe insulin deficiency. Leptin action in Astemizole the brain can coordinate several complex and connected processes between different tissue types to lower blood glucose despite the absence of insulin signalling.6,7

In clinical practice, physiological leptin infusion can block or attenuate many neuro-endocrine responses induced by insulin deficient diabetes; however, it does not normalise hyperglycaemia. If exogenous leptin can activate the BCGS why is this the case? The likely answer is that there is an extensive overlap between the peripheral and central gluco-regulatory mechanisms. Insulin deficiency has marked effects on adipose tissue and thus its ability to secrete leptin. It is therefore believed that insulin deficiency leads to leptin deficiency and failure to trigger the BCGS as neither insulin nor leptin are able to work on the brain. Other hormones, such as FGF-19 (fibroblast growth factor), a gut hormone which is secreted in response to meals, have been shown to act in the brain to promote insulin-independent glucose lowering.

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