Pathophysiology of Radiocontrast Nephropathy

Heyman, Samuel N.; Reichman, J.M.; Brezis, M

doi:10.1097/00004424-199911000-00004

Cited by 167 publications

(112 citation statements)

References 56 publications

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“…This is in agreement with clinical observations of medullary vulnerability to abrupt decreases in renal perfusion. (4,5,23) Hypoxia occurs despite the lack of an overall O 2 delivery and consumption mismatch, thus implying that global measures of renal hemodynamics are insufficient to fully explain regional differences.…”

Section: Discussionmentioning

confidence: 99%

Regional decreases in renal oxygenation during graded acute renal arterial stenosis: a case for renal ischemia

Warner

Gomez

Bolterman

et al. 2009

American Journal of Physiology-Regulatory, Integrative and Comp

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. Regional decreases in renal oxygenation during graded acute renal arterial stenosis: a case for renal ischemia. Am J Physiol Regul Integr Comp Physiol 296: R67-R71, 2009. First published October 29, 2008 doi:10.1152/ajpregu.90677.2008.-Ischemic nephropathy describes progressive renal failure, defined by significantly reduced glomerular filtration rate, and may be due to renal artery stenosis (RAS), a narrowing of the renal artery. It is unclear whether ischemia is present during RAS since a decrease in renal blood flow (RBF), O 2 delivery, and O2 consumption occurs. The present study tests the hypothesis that despite proportional changes in whole kidney O 2 delivery and consumption, acute progressive RAS leads to decreases in regional renal tissue O 2. Unilateral acute RAS was induced in eight pigs with an extravascular cuff. RBF was measured with an ultrasound flow probe. Cortical and medullary tissue oxygen ͑P t O 2 ͒ of the stenotic kidney was measured continuously with sensors during baseline, three sequentially graded decreases in RBF, and recovery. O 2 consumption decreased proportionally to O2 delivery during the graded stenosis (19 Ϯ 10.8, 48.2 Ϯ 9.1, 58.9 Ϯ 4.7 vs. 15.1 Ϯ 5, 35.4 Ϯ 3.5, 57 Ϯ 2.3%, respectively) while arterial venous O 2 differences were unchanged. Acute RAS produced a sharp reduction in O 2 efficiency for sodium reabsorption (P Ͻ 0.01). Cortical ͑P t O 2 ͒ decreases are exceeded by medullary decreases during stenosis (34.8 Ϯ 1.3%). Decreases in tissue oxygenation, more pronounced in the medulla than the cortex, occur despite proportional reductions in O 2 delivery and consumption. This demonstrates for the first time that hypoxia is present in the early stages of RAS and suggests a role for hypoxia in the pathophysiology of this disease. Furthermore, the notion that arteriovenous shunting and increased stoichiometric energy requirements are potential contributors toward ensuing hypoxia with graded and progressive acute RAS cannot be excluded.ischemia; renal tissue oxygenation; renal blood flow; pig THE TERM "ISCHEMIC NEPHROPATHY" has been used to describe progressive renal failure, defined by a significantly reduced glomerular filtration rate (GFR) or loss of renal parenchyma due to renal artery stenosis, a narrowing of one or more of the renal arteries. Ischemia, however, results from a rate of blood flow that is insufficient to satisfy metabolic demands, thereby leading to tissue hypoxia. There is little evidence to suggest that ischemic nephropathy is accompanied by renal tissue hypoxia (24). In fact, the kidney has a high blood flow relative to its weight (3), which results in very small arterial-venous differences in oxygenation, suggesting a large O 2 supply and limited O 2 consumption. Importantly, Nielsen et al. (15) found in patients with significant unilateral renal artery stenosis that O 2 consumption decreased with limited blood flow, suggesting that a decrease in O 2 supply is not enough to cause ischemic renal disease (22). Moreover, the reduced O 2 supply and demand s...

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Section: Discussionmentioning

confidence: 99%

Regional decreases in renal oxygenation during graded acute renal arterial stenosis: a case for renal ischemia

Warner

Gomez

Bolterman

et al. 2009

American Journal of Physiology-Regulatory, Integrative and Comp

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“…All hypertonic solutions significantly increased elimination half-life, increasing with the osmolality of the agents. Apart from the direct exposure of red blood cells, endothelial cells, and tubular cells to the hypertonic solutions injected into the renal artery, the CM also represent an osmotic load to the kidneys with secondary diuresis and natriuresis (1,55,56). Osmotic load may activate the tubuloglomerular feedback mechanism mediating vasoconstrictive agents, increase medullary oxygen demand for active reabsorption of the increased tubular sodium load resulting in hypoxic injuries, or increase intratubular pressure with elevation of interstitial pressure and secondary vascular compression beneath the rigid renal capsula.…”

Section: Discussionmentioning

confidence: 99%

Gadolinium contrast media are more nephrotoxic than a low osmolar iodine medium employing doses with equal x-ray attenuation in renal arteriography: An experimental study in pigs1

et al. 2004

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“…Thus far, several pathophysiological mechanisms of CIN have been proposed, including direct toxicity to renal tubular epithelium, oxidative stress, ischemic injury, and tubular obstruction [6,7]. Low blood flow in the medulla leading to medullary hypoxia might result from increased perivascular hydrostatic pressure, increased intratubular pressure secondary to contrastinduced diuresis, vasoconstriction due to redundance of vasoactive substances as adenosin and endothelin, and decrease of nitric oxide and prostaglandins [8,9]. Excretion of the contrast medium requires significant urine volume to clear the osmotic load.…”

Section: Pathogenesis Of Cinmentioning

confidence: 99%

Contrast‐induced nephropathy

Pučelíková

Dangas

Mehran

2007

Cathet Cardio Intervent

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Contrast induced nephropathy (CIN) is an iatrogenic disorder, resulting from exposure to contrast media. Contrast-induced hemodynamic and direct cytotoxic effects on renal structures are highly evident in its pathogenesis, whereas other mechanisms are still poorly understood. CIN is typically defined as an increase in serum creatinine by either 0.5 mg/dl or by 25% from baseline within the first 2-3 days after contrast administration. Although rare in the general population, CIN has a high incidence in patients with an underlying renal disorder, in diabetics, and the elderly. The risk factors are synergistic in their ability to produce CIN. The best way to prevent CIN is to identify the patients at risk and to provide adequate peri-procedural hydration. The role of various drugs in prevention of CIN is still controversial and warrants future studies. Despite remaining uncertainty regarding the degree of nephrotoxicity produced by various contrast agents, in current practice non-ionic low-osmolar contrast media are preferred over the high-osmolar contrast media in patients with renal impairment.

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Pathophysiology of Radiocontrast Nephropathy

Cited by 167 publications

References 56 publications

Regional decreases in renal oxygenation during graded acute renal arterial stenosis: a case for renal ischemia

Regional decreases in renal oxygenation during graded acute renal arterial stenosis: a case for renal ischemia

Gadolinium contrast media are more nephrotoxic than a low osmolar iodine medium employing doses with equal x-ray attenuation in renal arteriography: An experimental study in pigs1

Contrast‐induced nephropathy

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