Attenuated buffering of renal perfusion pressure  variation in juxtamedullary cortex in SHR

Roald, Anca Beatrice; Ofstad, J.; Iversen, Bjarne M.

doi:10.1152/ajprenal.00199.2001

Cited by 20 publications

(23 citation statements)

References 19 publications

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confidence: 71%

“…In the hypertensive animal, proteinuia develops from juxtamedullary nephrons and P GC is higher in glomeruli in juxtamedullar than superficial glomeruli in hypertensive rats (11). The early development of juxtamedullary degeneration in hypertensive animals has also been supported by a recent study where we found that autoregulation of renal blood flow (RBF) was less effective in hypertensive than in normotensive animals and less effective in inner than in outer cortex, i.e., pattern similar to that seen in glomerulosclerosis and tubular degeneration (27).Proteinuria has been suggested to be the main pathogenic factor in tubular degeneration, whereas P GC and increased stretch are thought to be important in the development of the glomerulosclerosis. The primary intention of the present study was to conduct experiments to demonstrate a parallel progression of glomerulosclerosis and tubular damage in Wistar-Kyoto rats (WKY) and spontaneously hypertensive rats (SHR).…”

supporting

confidence: 62%

“…In old SHR, degeneration was accompanied by proteinuria but no further increase of the P GC . Based on these observations, and our previous work on RBF autoregulation (15,18,27), we suggest that pressure variation in glomeruli and tubuli during every day pressure variation of the systemic blood pressure might play a pathogenetic role in development of glomerular and tubular degeneration in SHR.…”

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confidence: 60%

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Glomerular and tubular damage in normotensive and hypertensive rats

Ofstad¹,

Iversen²

2005

American Journal of Physiology-Renal Physiology

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Tubular cell damage is an important mediator of interstitial fibrosis in chronic renal diseases. Glomerular and tubular damage in genetic hypertension was therefore studied. Tubular and glomerular damage was investigated in 10-, 40-, and 70-wk-old spontaneously hypertensive rats (SHR) and Wistar-Kyoto rats (WKY) and compared with glomerular capillary pressure (PGC) and glomerulosclerosis in superficial (OC) and juxtamedullary (JMC). Tubular vimentin was used as criterion of tubular damage. Variation in tubular diameter was measured during change in perfusion pressure, and ureter ligation was used to demonstrate the relationship between tubular pressure and appearance of vimentin-positive cells. Tubular and glomerular damage was most pronounced in JMC and greater in SHR than in WKY. It was absent in 10-wk-old WKY and significantly higher in JMC of SHR compared with WKY at 70 wk of age. Numbers of vimentin-positive segments were 18 Ϯ 9 vs. 38 Ϯ 7% in JMC of 70-wk-old WKY and SHR (P Ͻ 0.02), and glomerulosclerosis was seen in 8 Ϯ 3 vs. 19 Ϯ 5% of glomeruli in JMC of 70-wk-old WKY and SHR, respectively (P Ͻ 0.01). P GC was 45 Ϯ 3 mmHg in JMC of WKY and 57 Ϯ 3 mmHg in JMC of 70-wk-old SHR (P Ͻ 0.001). Tubular diameter variation was greatest in SHR (P Ͻ 0.05) during pressure variation. Proteinuria was present only in 40-and 70-wk-old SHR and did not correlate with tissue damage. Tubular and glomerular damage in both strains develops in parallel and may be caused by a common mechanism, which may be glomerular capillary and tubular wall stretch during acute blood pressure variation which is greatest in JMC in SHR.vimentin; sclerosis index; glomerular capillary pressure; proteinuria IN PROGRESSIVE HYPERTENSIVE disease, physical factors such as increased glomerular capillary pressure (P GC ), filtration rate, and flow are considered to be important mediators of glomerulosclerosis (15,21). Recent research has focused on other aspects, such as growth, tubular damage, accumulation of collagens, and appearance of immune cells in the peritubular interstitium. Altered tubular cell function seems to play a pivotal role in development of the tubulointerstitial pathology (25). In diseased kidneys, tubular cells may acquire macrophage-like attributes and synthesize complement, MCH class II molecules, actin of the smooth muscle cell type, growth factors, chemokines, and other cytokines, i.e., orchestrate a chronic immune process in the peritubular interstitium and disturb the balance of growth and structure (17,20,28).It is well documented that glomerulosclerosis in hypertension is greater in the deep than in the superficial cortex (11,22), and the tubular derangement in inner cortex is also more pronounced than in the outer cortex (24). In the hypertensive animal, proteinuia develops from juxtamedullary nephrons and P GC is higher in glomeruli in juxtamedullar than superficial glomeruli in hypertensive rats (11). The early development of juxtamedullary degeneration in hypertensive animals has also been supported by a recent study w...

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confidence: 71%

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confidence: 62%

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confidence: 60%

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Glomerular and tubular damage in normotensive and hypertensive rats

Ofstad¹,

Iversen²

2005

American Journal of Physiology-Renal Physiology

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“…This may relate to the observation that the intermediate segments of the interlobular artery in this strain exhibit an enhanced myogenic response (69), which would provide added protection for the distal superficial glomeruli but not the juxtamedullary nephrons. Autoregulatory responses are also reported to be slower in the juxtamedullary cortex of the aged SHR (127), and this could contribute to the pattern of injury. Finally, when autoregulatory capacity in the SHR is reduced by 5/6 renal ablation, these animals rapidly develop malignant nephrosclerosis (17).…”

Section: Consequences Of Impaired Renal Autoregulation On Renal Protementioning

confidence: 99%

Renal autoregulation: new perspectives regarding the protective and regulatory roles of the underlying mechanisms

Loutzenhiser

Griffin²,

Bidani³

2006

American Journal of Physiology-Regulatory, Integrative and Comp

238

244

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dani. Renal autoregulation: new perspectives regarding the protective and regulatory roles of the underlying mechanisms. Am J Physiol Regul Integr Comp Physiol 290: R1153-R1167, 2006. doi:10.1152/ajpregu.00402.2005.-When the kidney is subjected to acute increases in blood pressure (BP), renal blood flow (RBF) and glomerular filtration rate (GFR) are observed to remain relatively constant. Two mechanisms, tubuloglomerular feedback (TGF) and the myogenic response, are thought to act in concert to achieve a precise moment-by-moment regulation of GFR and distal salt delivery. The current view is that this mechanism insulates renal excretory function from fluctuations in BP. Indeed, the concept that renal autoregulation is necessary for normal renal function and volume homeostasis has long been a cornerstone of renal physiology. This article presents a very different view, at least regarding the myogenic component of this response. We suggest that its primary purpose is to protect the kidney against the damaging effects of hypertension. The arguments advanced take into consideration the unique properties of the afferent arteriolar myogenic response that allow it to protect against the oscillating systolic pressure and the accruing evidence that when this response is impaired, the primary consequence is not a disturbed volume homeostasis but rather an increased susceptibility to hypertensive injury. It is suggested that redundant and compensatory mechanisms achieve volume regulation, despite considerable fluctuations in distal delivery, and the assumed moment-by-moment regulation of renal hemodynamics is questioned. Evidence is presented suggesting that additional mechanisms exist to maintain ambient levels of RBF and GFR within normal range, despite chronic alterations in BP and severely impaired acute responses to pressure. Finally, the implications of this new perspective on the divergent roles of the myogenic response to pressure vs. the TGF response to changes in distal delivery are considered, and it is proposed that in addition to TGF-induced vasoconstriction, vasodepressor responses to reduced distal delivery may play a critical role in modulating afferent arteriolar reactivity to integrate the regulatory and protective functions of the renal microvasculature. renal microcirculation; afferent arteriole; myogenic; tubuloglomerular feedback ONE OF THE MOST STRIKING CHARACTERISTICS of the renal circulation is the ability of the kidney to maintain a constant renal blood flow (RBF) and glomerular filtration rate (GFR) as renal perfusion pressure is altered. The dual regulation of both RBF and GFR is achieved by proportionate changes in the preglomerular resistance and is believed to be mediated by two mechanisms, tubuloglomerular feedback (TGF) and the renal myogenic response. TGF involves a flow-dependent signal that is sensed at the macula densa and alters tone in the adjacent segment of the afferent arteriole via a mechanism that remains controversial but likely involves adenosine and/or ATP (30,80,144). The myo...

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“…Interestingly, it is reported that in SHRs, such transient changes in glomerular capillary pressure of the juxtamedullary nephron are much greater than in normotensive Wistar-Kyoto rats. 46 In addition, micropuncture studies have shown that only juxtamedullary (but not superficial) glomerular capillary pressure is elevated in SHR as compared with WKY, and this elevation becomes prominent in old SHRs. 31 Finally, it is reported that uninephrectomy causes selective deep nephron hyperfiltration in SHRs but not in WKY.…”

Section: Albuminuria and Endothelial Dysfunctionmentioning

confidence: 99%

Strain vessel hypothesis: a viewpoint for linkage of albuminuria and cerebro-cardiovascular risk

et al. 2009

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Albuminuria is closely associated with stroke and cardiovascular diseases (CVDs) as well as the salt sensitivity of blood pressure (BP). Although albuminuria may reflect generalized endothelial dysfunction, there may be more specific hemodynamic mechanisms underlying these associations. Cerebral hemorrhage and infarction occur most frequently in the area of small perforating arteries that are exposed to high pressure and that have to maintain strong vascular tone in order to provide large pressure gradients from the parent vessels to the capillaries. Analogous to the perforating arteries are the glomerular afferent arterioles of the juxtamedullary nephrons. Hypertensive vascular damage occurs first and more severely in the juxtamedullary glomeruli. Therefore, albuminuria may be an early sign of vascular damages imposed on 'strain vessels' such as perforating arteries and juxtamedullary afferent arterioles. Coronary circulation also occurs under unique hemodynamic conditions, in which the entire epicardial segments are exposed to very high pressure with little flow during systolic phases. From the evolutionary point of view, we speculate that such circulatory systems in the vital organs are mandatory for survival under the danger of hypoperfusion due to difficult access to salt and water as well as high risks of wound injuries. In addition, albuminuria would indicate an impairment of renal medullary circulation, downstream from the juxtamedullary glomeruli, and therefore an impaired pressure natriuresis, which would lead to salt sensitivity of BP. Our 'strain vessel hypothesis' may explain why hypertension and diabetes, unforeseen in the concept of evolution, preferentially affect vital organs such as the brain, heart and kidney.

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Attenuated buffering of renal perfusion pressure variation in juxtamedullary cortex in SHR

Cited by 20 publications

References 19 publications

Glomerular and tubular damage in normotensive and hypertensive rats

Glomerular and tubular damage in normotensive and hypertensive rats

Renal autoregulation: new perspectives regarding the protective and regulatory roles of the underlying mechanisms

Strain vessel hypothesis: a viewpoint for linkage of albuminuria and cerebro-cardiovascular risk

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