OBJECTIVES: The purpose of this study was to define "significant" renal artery stenosis (i.e., a stenosis able to induce arterial hypertension). BACKGROUND: The degree of renal artery stenosis that justifies an attempt at revascularization is unknown. METHODS: In 15 patients, transstenotic pressure measurements were obtained before and after unilateral stenting. After stenting, graded stenoses were created in the stented segment by progressive inflation of a balloon catheter. Stenosis severity was expressed as the ratio of distal pressure (P(d)) corrected for aortic pressure (P(a)). Balloon inflation pressure was adjusted to create 6 degrees of stenosis (P(d)/P(a) from 1.0 to 0.5, each step during 10 min). Plasma renin concentration was measured at the end of each step in the aorta and in both renal veins. RESULTS: For a P(d)/P(a) ratio >0.90, no significant change in plasma renin concentration was observed. However, when P(d)/P(a) became <0.90, a significant increase in renin was observed in the renal vein of the stenotic kidney, finally reaching a maximal increase of 346 +/- 145% for P(d)/P(a) of 0.50 (p = 0.006). These values returned to baseline when the stenosis was relieved. In addition, plasma renin concentration increased significantly in the vein from the non-stenotic kidney (p = 0.02). CONCLUSIONS: In renal artery stenoses, a P(d)/P(a) ratio of 0.90 can be considered a threshold value below which the stenosis is likely responsible for an up-regulation of renin production and, thus, for renovascular hypertension. These findings might contribute to better patient selection for renal angioplasty.
OBJECTIVES: The purpose of this study was to define "significant" renal artery stenosis (i.e., a stenosis able to induce arterial hypertension). BACKGROUND: The degree of renal artery stenosis that justifies an attempt at revascularization is unknown. METHODS: In 15 patients, transstenotic pressure measurements were obtained before and after unilateral stenting. After stenting, graded stenoses were created in the stented segment by progressive inflation of a balloon catheter. Stenosis severity was expressed as the ratio of distal pressure (P(d)) corrected for aortic pressure (P(a)). Balloon inflation pressure was adjusted to create 6 degrees of stenosis (P(d)/P(a) from 1.0 to 0.5, each step during 10 min). Plasma renin concentration was measured at the end of each step in the aorta and in both renal veins. RESULTS: For a P(d)/P(a) ratio >0.90, no significant change in plasma renin concentration was observed. However, when P(d)/P(a) became <0.90, a significant increase in renin was observed in the renal vein of the stenotic kidney, finally reaching a maximal increase of 346 +/- 145% for P(d)/P(a) of 0.50 (p = 0.006). These values returned to baseline when the stenosis was relieved. In addition, plasma renin concentration increased significantly in the vein from the non-stenotic kidney (p = 0.02). CONCLUSIONS: In renal artery stenoses, a P(d)/P(a) ratio of 0.90 can be considered a threshold value below which the stenosis is likely responsible for an up-regulation of renin production and, thus, for renovascular hypertension. These findings might contribute to better patient selection for renal angioplasty.
Authors: Heinrich Wieneke; Thomas Friedrich Michael Konorza; Holger Eggebrecht; Christoph Kurt Naber; Sebastian Philipp; Thomas Philipp; Andreas Kribben; Raimund Erbel Journal: Med Klin (Munich) Date: 2009-05-16
Authors: Thorsten A Bley; Kevin M Johnson; Christopher J François; Scott B Reeder; Mark L Schiebler; Benjamin R Landgraf; Daniel Consigny; Thomas M Grist; Oliver Wieben Journal: Radiology Date: 2011-08-03 Impact factor: 11.105
Authors: Timothy P Murphy; Christopher J Cooper; Alan H Matsumoto; Donald E Cutlip; Karol M Pencina; Kenneth Jamerson; Katherine R Tuttle; Joseph I Shapiro; Ralph D'Agostino; Joseph Massaro; William Henrich; Lance D Dworkin Journal: J Am Coll Cardiol Date: 2015-12-08 Impact factor: 24.094