Intrarenal mechanisms of salt retention after bile duct ligation in rats.

Yarger, William E.; Schrader, Nell W.; Boyd, Marley

doi:10.1172/jci108292

Cited by 53 publications

(36 citation statements)

References 27 publications

(51 reference statements)

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“…Selkurt and colleagues (87)(88)(89) showed that changes in renal perfusion pressure, within a range in which RBF remains unchanged (RBF autoregulation), were followed by dramatic changes in sodium excretion. This situation is comparable to that seen in the early stages of hepatic cirrhosis, where increased sodium reabsorption occurs without a change in RBF (2,12,79,104).…”

supporting

confidence: 78%

“…The increase in renal vascular resistance in patients with cirrhosis appears to mainly affect the superficial cortex, sparing medullary blood flow, as suggested by studies using either ultrasound (83,84) or xenon-washout techniques (52). Thus, because more of the RBF is shunted toward the deeper nephrons, which have an enhanced sodium reabsorbing capability, it is possible that this redistribution is contributing to the enhanced sodium and water retention that is typically seen in cirrhosis (104). In addition, changes in intrarenal blood flow may be implicated in the progression of human (79) and experimental cirrhosis (2, 12).…”

Section: Use Of Micro-ct To Investigate Disease Conditions In the Kidneymentioning

confidence: 99%

“…They suggested this shift to be the major explanation for the lack of urine flow, despite a preservation of renal blood flow (RBF). The shift of blood flow within the renal cortex from superficial short nephrons to deep long nephrons was later observed in sodium-retaining states such as cardiac insufficiency, hepatic cirrhosis, or hypovolemia (1,18,53,104). Selkurt and colleagues (87)(88)(89) showed that changes in renal perfusion pressure, within a range in which RBF remains unchanged (RBF autoregulation), were followed by dramatic changes in sodium excretion.…”

mentioning

confidence: 99%

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The use of microcomputed tomography to study microvasculature in small rodents

Bentley

Ortiz

Ritman

et al. 2002

American Journal of Physiology-Regulatory, Integrative and Comp

135

109

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The use of microcomputed tomography to study microvasculature in small rodents. Am J Physiol Regulatory Integrative Comp Physiol 282: R1267-R1279, 2002 10.1152/ajpregu.00560.2001.-Appropriate nephron function is dependent on the intrarenal arrangement of blood vessels. The preferred and primary means to study the architecture of intrarenal circulation has been by filling it with opaque substances such as india ink, radio-opaque contrast material, or various polymers for study by light or scanning electron microscopy. With such methodologies, superficial vessels may obscure deep vessels and little quantitative information may be obtained. Serial-section microtomy has not been practical because of problems relating to alignment and registration of adjacent sections, lost sections, and preparation time and effort. Microcomputed tomography (micro-CT) overcomes such limitations and provides a means to study the three-dimensional architecture of filled vessels within an intact rodent kidney and to obtain more quantitative information. As an example of micro-CT's capabilities, we review the use of micro-CT to study the alterations in renal microvasculature caused by the development of liver cirrhosis after chronic bile duct ligation. In this example, micro-CT evidence shows a selective decrease in cortical vascular filling in the kidney, with a maintenance of medullary vascular filling. These changes may contribute to the salt and water retention that accompanies cirrhosis. These results indicate that micro-CT is a promising method to evaluate renal vascular architecture in the intact rodent kidney relative to physiological and pathological function. kidney; imaging; microcirculation; vasculature APPROPRIATE NEPHRON FUNCTION appears to be dependent on the detailed three-dimensional interrelationship of blood vessels with the tubular components. Many techniques and/or methods have been developed to examine the microanatomic arrangement of pre-and postglomerular vasculature (4,29,36,40,54,55,59,71,98). In this respect, such efforts were prompted by early studies showing that urinary excretion varied in relation to the intrarenal environment and was dependent on the coupling of renal microcirculation and tubular components. In 1947, Trueta and colleagues (96), studying the crush syndrome in rabbits, observed that there was a shift of blood flow from the renal cortex to the medulla during hemorrhage. They suggested this shift to be the major explanation for the lack of urine flow, despite a preservation of renal blood flow (RBF). The shift of blood flow within the renal cortex from superficial short nephrons to deep long nephrons was later observed in sodium-retaining states such as cardiac insufficiency, hepatic cirrhosis, or hypovolemia (1,18,53,104). showed that changes in renal perfusion pressure, within a range (75-130 mmHg) in which RBF remains unchanged (RBF autoregulation), were followed by dramatic changes in sodium excretion. This situation is comparable to that seen in the early stages Address for reprint requ...

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supporting

confidence: 78%

Section: Use Of Micro-ct To Investigate Disease Conditions In the Kidneymentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

The use of microcomputed tomography to study microvasculature in small rodents

Bentley

Ortiz

Ritman

et al. 2002

American Journal of Physiology-Regulatory, Integrative and Comp

135

109

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“…In the absence longed cholestasis, characterized by the reten tion of bile compounds, may cause renal dam age (reduction in renal hemodynamics, im pairment of renal excretion of water and salts and sensitization of the kidney to anoxic dam age) which sometimes leads to renal failure [1][2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

“…The pathophysiological cause of renal damage in the course of bile flow impairment is not well understood, even if several phe nomena, such as increased access of various bile constituents into the kidney (bilirubin and bile salts), have been suggested [1,3,5]. The nephrotoxic mechanism of these sub stances appears to be either indirect, because of their proinflammatory capacity (cytokines, acute-phase proteins, or leukocyte activation) or direct, because of hemolysis [6], Endotoxemia may also have a toxic effect on renal function; clinical and experimental works have focused on the role of endotoxins gut absorption in causing renal impairment during cholestasis, as well as in chronic renal failure [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Renal Functional Alterations in Extrahepatic Cholestasis: Can Oxidative Stress Be Involved?

Panozzo

Basso

Bálint³

et al. 1995

Eur Surg Res

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Renal function may be compromised by extrahepatic cholestasis. In this context, the nephrotoxic role of bile salts is well known. Recently, however, it has been claimed that other factors, such as lipid peroxides, are involved. We therefore created bile duct ligation in 40 Sprague-Dawley rats. During the follow-up (from 1 to 28 days), significant variations were found in liver histological parameters, but not in renal morphology. Fourteen days after ligation, significant increases were found in serum and urinary thiobarbituric-acid-reactive species and phospholipase A₂ (indirect indices of lipid peroxidation), whereas 8-10 days after ligation, a significant decrease was observed in erythrocytic and hepatic GSH levels. The variations in urinary thiobarbituric-acid-reactive species and in phospholipase A₂ were not correlated with concomitant variations in the sera. Urinary lipid peroxides were directly correlated with the degree of liver morphological alterations and inversely with circulating GSH. Urinary outputs of lipid peroxides, phospholipase A₂ and N-acetyl-glucosaminidase were correlated with each other. These results suggest that there is an imbalance in the oxidative-antioxidant hepatic system in experimental extrahepatic cholestasis. The reduced bioavailability of blood GSH may alter the oxidative equilibrium in other organs, such as the kidney, triggering and favoring the lipoperoxidative cascade.

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