1.
[Effects of weightlessness on baroreflex function].
Shen, XY
Hang tian yi xue yu yi xue gong cheng = Space medicine & medical engineering. 2002;(6):465-8
Abstract
The declination of baroreceptor reflex function is one of the important factor causing orthostatic intolerance after space flight. The change of baroreceptor reflex function during weightlessness and simulated weightlessness is introduced, and the influence of elevatory upper body blood pressure and electrolyte changes caused by weightlessness on baroreflex function are analyzed.
2.
[Clinical implications of blood pressure variability].
Lantelme, P, Custaud, MA, Vincent, M, Milon, H
Archives des maladies du coeur et des vaisseaux. 2002;(9):787-92
Abstract
There are many variations in blood pressure, ranging from that observed between systole and diastole (pulse pressure) to slower daily or seasonal variations. This variability has many facets, for example the simple concept of variation around the mean blood pressure and the more complex spectral, chaos or fractal analysis... Some of these concepts are still the subject of fundamental research and have no current clinical applications. Others, however, are already part of our evaluation of hypertensive patients or used as prognostic factors in cardiac failure or myocardial infarction. Blood pressure variability, either the pulse pressure or 24 hour variability, is associated with a higher incidence of cardiovascular complications. Although the causality of the relationship is uncertain, patients with the greatest variability seem to be at higher risk. In addition to this prognostic impact, the study of changes in blood pressure by spectral analysis may also provide indices of adrenergic tone or sympathovagal equilibrium which may be useful clinically. Finally, the combined study of blood pressure variability and heart rate lead to the baroreflex, the sensitivity of which integrates major risk factors such as blood pressure, age, heart rate and serum cholesterol. This baroreflex could be a useful parameter for stratification of cardiovascular risk. This has already been demonstrated in patients at high risk, such as those with cardiac failure or myocardial infarction.
3.
Arterial baroreceptor and cardiopulmonary reflex control of sympathetic outflow in human heart failure.
Floras, JS
Annals of the New York Academy of Sciences. 2001;:500-13
Abstract
Several observations indicate that the arterial baroreflex control of sympathetic nerve activity is preserved, even in advanced heart failure. These include: (1) augmentation of muscle sympathetic nerve activity burst amplitude and duration following a premature beat; (2) rapid recognition of changes in blood pressure induced by ventricular arrhythmias; (3) muscle sympathetic alternans and a steep inverse relationship between changes in diastolic pressure and the subsequent sympathetic burst amplitude during pulsus alternans; (4) similar inhibition of muscle sympathetic nerve activity in subjects with normal and impaired left ventricular systolic function by increases in intrathoracic aortic transmural pressure; (5) documentation, by cross-spectral analysis, of similar gain in the transfer function between blood pressure and muscle sympathetic nerve activity in these two groups; and (6) during sodium nitroprusside infusion, similar reflex increases in total body norepinephrine spillover in normal and heart-failure subjects. When nonhypotensive lower-body negative pressure was applied to test the hypothesis that selective reduction of atrial and pulmonary pressures would exert a cardiac sympathoinhibitory response in heart failure, there was no effect in control subjects, but cardiac norepinephrine spillover fell by 25% (P < .05) in those with systolic dysfunction. In summary, human heart failure is characterized by a rapidly responsive and sensitive arterial baroreflex, and by activation of a cardiac sympathoexcitatory reflex related to increased cardiopulmonary filling pressures.