Hypertension and the Metabolic Syndrome: Closely Related Central Origin?

In primary hypertension a mild hyperresponsiveness of hypothalamic, sympatho-hormonal centres to psychosocial stimuli forms a major pathogenetic element, although high salt intake in some subjects may contribute via volume expansion. Hypertension is often associated with another ?civilisation? disorder, the metabolic syndrome, defined as abdominal obesity, insulin resistance and dyslipidaemia. According to recent research, the metabolic syndrome has in all likelihood a central neuroendocrine origin in the form of enhanced engagement of the hypothalamic-pituitary-adrenal (HPA) axis. Here the peripheral endocrine perturbations act as triggers for both central obesity and the metabolic abnormalities. The reaction pattern characterising early primary hypertension is identical with, or closely related to, the ?defence reaction?, while that leading to the metabolic syndrome is similar to that of the ?defeat reaction?. Both belong to the primitive survival reactions, common to all mammals, though man can control, or at least mask, his outward-behavioural part but not the neuro-hormonal expressions. Animal experiments show how frequent or chronic mental challenges are capable of engaging these limbic-hypothalamic centres, affecting blood pressure regulation as well as endocrine-metabolic regulation. Furthermore, these centres are tightly coupled functionally, and their signals to the periphery often combined. On a long-term basis their engagements appear to be decisive for the development of both primary hypertension and the metabolic syndrome, as suggested by intervention studies. In both these ?disorders of civilisation?, observations strongly indicate that psychosocial stress, socioeconomic handicaps, lack of exercise, abuse and also psychiatric traits are involved. Such factors, characteristic of current competitive society, probably cause mixed engagements of the two above-mentioned neuro-hormonal patterns, and thereby, with time, primary hypertension and the metabolic syndrome, with end-points such as coronary artery disease, diabetes mellitus type2 and stroke. Susceptibilty to such developments is probably enhanced by genetic factors. This overview of recent developments therefore serves to emphasise how both primary hypertension and the metabolic syndrome seem to have a common central origin. Central regulatory factors are often overlooked, partly because it is not realised that limbic-hypothalamic centres are the major regulators of both circulatory and metabolic events, and partly because of the long period of time required before these disease end-points are reached.

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