FOLKOW, B., Id. HALLBACK, Y. LUNDGREN and L. WEISS. Background of increared flow resistance and vascular renctiuity in spontaneously hypertensive rats. Acta physiol. scand. 1970. 80. 93-106. The hindquarte-s of a spontaneously hypertensive rat (SHR) and a matched normotensive control rat (NCR) were perfused at a constant rate of flow with oxygenated plasma substitute in 15 paired experiments. As is the case in the entire systemic vascular bed (Folkow et al. 1969), flow resistance was raised even during maximal dilatation in SHR (p
FOLKOW, B., M. HALLBACK, Y. LUNDGREN and L. WEISS. Structurally based increase of flow resistance in spontaneously hypertensive rats. Acta physiol. scand. 1970. 79. 373-378. The resistance to flow in the maximally dilated systemic vascular bed (except the coronaries) was compared in spontaneously hypertensive rats (SHR) and normotensive controls. -The aortic root was cannulated for perfusion with an oxygenated plasma substitute, both the aortic inflow and the venous effluent via the right heart being recorded continuously. Temperature and viscosity of the perfusate were kept constant and it was checked with supramaximal doses of vasodilator drugs that complete vascular relaxation was a t hand. Pressure-flow curves were plotted and flow resistances at equal pressure heads and transmural pressures were compared.-Flow resistance in the maximally dilated systemic vessels was increased in the spontaneously hypertensive rats to an extent that largely equalled their raised blood pressure during "resting" conditions, the difference to the control animals being highly significant. -The results suggest the presence of a morphological adaptation of the resistance vessels of the entire systemic circuit which raises the structurally set "baseline" for functional vascular adjustments, and which therefore may largely account for the increased flow resistance during rest. These findings are in agreement with earlier studies concerning the regional flow resistance in hypertensive man (Folkow 1956, Sivertsson andOlander 1968).
In a series of studies (cf. Folkow et al. 1973) the design, and reactivity, of the resistance vessels in hypertension has been hemodynamically analyzed, comparing constant flow perfusion of, preferentially, the hindquarter vascular beds of hypertensive (SHR) and paired normotensive control rats (NCR). Measurements of the resistance at maximal dilatation, the 'threshold sensitivity' to noradrenaline (NA), the entire dose-response curve to NA and its steepness, and the maximal pressor response to supramaximal concentrations of constrictor agents, revealed important differences in resistance vessel design. Thus, in both SHR and rats with renovascular hypertension ( R H R ) , resistance vessel design is rapidly changed towards a luminal narrowing associated with a hypertrophic wall increase. This type of 'structural autoregulation', of the resistance vessels, triggered by functional pressor influences, appears to be of great importance in hypertension since resistance is then raised also when smooth muscle tone is normal.To get more insight into hypertensive vascular beds, methods are needed allowing separate quantitative estimations of e.g. precapillary resistance vessels, capillary exchange vessels, postcapillary resistance and capacitance vessels, which are specialized both in design and function. For such purposes hindquarters of rats were isolated by thorough ligations of all vascular connections except the aorta and caval vein.Arterial inflow pressure (4\) was measured in the tail artery and venous outflow pressure (Pv) in a caval branch. The caval vein was connected to a wide outflow tube whereby P,could be set at desired levels. The preparation was connected to a constant flow perfusion pump delivering a body-warm plasma substitute (oxygenated Tyrode solution with 4 % Ficoll, m.w. about 80,000, AB Pharmacia, Sweden), a t known flows (Q) and levels of P.% and Pv. The hindquarters were connected to a force displacement transducer allowing continuous, precise recordings of weight shifts of the preparation. From these shifts, changes in intravascular fluid content and in transcapillary fluid transfer could be separately deduced (for details see e.g. Mellander 1960). I n this way PA,, Pv and Q could be set a t desired levels and 1 Inst. of Physiology, Czechoslovak Academy of Sciences, Praha; guest research scientist of the Royal Academy of Sciences, Sweden.
LUNDGREN, Y., M. HALLBACK, L. WEISS and B. FOLKOW. Rate and extent of adaptive cardiovascular changes in rats during experimental renal hytertension. Acta physiol. scand. 1974. 91. 103-115. To study the extent and exact time course of cardiovascular structural adaptation to increases in pressure load, renal hypertension was induced in normotensive male Wistar rats by renal artery constriction. At different intervals after operation the hemodynamic characteristics of the hypertensive rats and normotensive control rats were explored in paired hindquarter perfusions, from maximal dilatation up to maximal constriction (cf . Folkow et al. 1970 b).At the same time intervals the extent of left ventricular hypertrophy and of water content of the aortic wall were examined. The results reveal the presence of left ventricular hypertrophy in the hypertensive rats already after one week, soon followed by adaptive structural changes of the resistance vessels, in the form mainly of media hypertrophy, these processes being largely completed 2-3 weeks after operation. In these animals, lacking genetic predisposition for hypertension, the extent of the structural vascular changes seems large enough to explain a considerable part, but not all, of the pressure rise. An increased water content of the hypertensive aortic wall is found first 4.5 months after operation, indicating that some water logging of arterial and maybe also arteriolar walls might occur in late phases of chronic renal hypertension.
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