Central nervous system circuitry and peripheral neural sympathetic activity responsible for essential hypertension.

Both clinical and experimental studies dealing with patients affected by idiopathic or essential hypertension (EH) are devoted to the great deal of physiological, pharmacological and pathological as well as therapeutical issues of EH. However, most articles devoted to EH do not refer to the central nervous system mechanisms underlying this disease and the channels which allow that these mechanisms are funneled to the peripheral autonomic nervous system and trigger this cardiovascular disorder. In the present review article we attempted to reach this target devoted to the central nervous system circuitry involved in the cardiovascular pathophysiology. We postulated that EH depends on the predominance of the binomial A5 noradrenergic (NA) nucleus + median raphe serotonergic (5-HT) nucleus over the (A6)-NA + dorsal raphe-5HT nuclei. This hypothesis receives additional support from our results obtained throughout the neuropharmacological therapy of this type of neurophysiological disorder. Our therapeutical strategy is addressed to enhance the activity of the (A6)-NA + dorsal raphe-5HT binomial circuitry.

Three-dimensional return map: a new tool for quantification of heart rate variability.

BACKGROUND: Several methods are used to study heart rate variability, but they have limitations, which might be overcome by the use of a three-dimensional return map. OBJECTIVES: To evaluate the performance of three-dimensional return map-derived indices to detect (1) sympathetic and parasympathetic modulation to the sinus node and (2) autonomic dysfunction in diabetic patients. METHODS: Six healthy subjects underwent partial and total pharmacological autonomic blockade in a protocol that incorporated vagal and sympathetic predominance. Twenty-two patients with type 2 diabetes mellitus and 12 normal controls participated in the subsequent validation experiment. Three-dimensional return maps were constructed by plotting RRn intervals versus the difference between adjacent RR intervals [(RRn+1)-(RRn)] versus the number of counts, and four derived indices (P1, P2, P3, MN) were created for quantification. RESULTS: Both indices P1 and MN were significantly increased after sympathetic blockade with propranolol, while all indices except P1 were modified after parasympathetic blockade (P < 0.05). During the validation experiments, P1 and MN detected differences between normal controls, and diabetic patients with and without autonomic neuropathy. The overall accuracy of most three-dimensional indices to detect autonomic dysfunction, estimated by the area under the ROC curve, was significantly better than traditional time domain indices. Three-dimensional return map-derived indices also showed adequate reproducibility on two different recording days (intra-class correlation coefficients of 0.69 to 0.82; P < 0.001). CONCLUSIONS: Three-dimensional return map-derived indices are reproducible, quantify parasympathetic as well as sympathetic modulation to the sinus node, and are capable of detecting autonomic dysfunction in diabetic patients.