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1-91 Relation Between Sodium Intake, Renal Function, and the Regulation of Arterial Pressure Jeffrey L. Osborn Downloaded from http://hyper.ahajournals.org/ by guest on June 16, 2017 The long-term regulation of arterial pressure requires the maintenance of a balance between sodium and water intake and sodium and water excretion. Normal salt and water balance leads to stable body fluid volumes and the maintenance of normal renal function is critical to establishing extracellular fluid volume homeostasis. This review focuses on the role of the kidney in the long-term control of salt and water balance with particular emphasis on the relations between sodium intake, the renin-angiotensin-aldosterone system, renal sympathetic nerve activity, and the regulation of arterial pressure via renal sodium and water excretion. The accumulation of evidence in recent years demonstrates that low level elevation of renin release, circulating angiotensin II or aldosterone, or activation of renal sympathetic outflow may alter renal function such that normal natriuretic and diuretic responses to arterial pressure are significantly impeded. Under these circumstances, the maintenance of normal sodium and water excretion requires a significant elevation of arterial pressure. Thus, compromised renal function leads to elevation of arterial pressure to maintain adequate sodium and water balance during periods of increased sodium intake. The resultant chronic elevation of arterial pressure then becomes a compromise that is used by the kidneys to maintain normal extracellular body fluid volumes. (Hypertension 1991;17[suppl I]:I-91-I-96) T he regulation of the extracellular fluid volume encompasses the continuous, ongoing maintenance of normal sodium and water balance as a relation between sodium intake and excretion. As humans, we exist as intermittent sodium and water consumers, leaving the bulk of the task of regulating our constant expansion of extracellular fluid volumes to the renal excretory processes. There are many factors that influence renal sodium excretion and thereby participate in this regulatory process. These factors can be subdivided into extrinsic and intrinsic mechanisms. Extrinsic mechanisms include the production of angiotensin II (Ang II) and aldosterone, the release of atrial natriuretic factor, and the alterations of renal sympathetic outflow; some intrinsic mechanisms are the regulation of glomerular filtration rate, renal hemodynamics, intrarenal physical forces controlling tubular reabsorp- From the Department of Physiology, Medical College of Wisconsin, Milwaukee, Wis. Supported by an American Heart Association Established Investigator Award, by an American Heart Association Grant-inAid, and by National Heart, Lung, and Blood Institute grants HL-40137 and HL-29587. Address for correspondence: Jeffrey L. Osborn, PhD, Department of Physiology, Medical College of Wisconsin, Milwaukee, WI 53226. tion, and intrarenal hormonal systems such as kinins, Ang n, and prostaglandins. Renal Function and Arterial Pressure A close correlation between normal kidney function and blood pressure control has been demonstrated in several experimental forms of hypertension including the spontaneously hypertensive rat (SHR)1 and the Dahl salt-sensitive (DS) rat.2 The spontaneously hypertensive strain of rats develops elevated arterial pressure spontaneously with age, and in some strains this hypertension is exacerbated with elevated sodium chloride intake. Kawabe et al3 have shown that in this strain, replacement at an early age of the SHR kidneys by transplantation with kidneys from age-matched normotensive control rats results in a substantial diminution of the blood pressure. This same response has been shown in other genetic models of hypertension including the Milan hypertensive strain4 and the DS rat.5 Thus, a direct correlation has been documented between renal function and arterial pressure in several genetic models of hypertension, and in some strains a critical interaction exists between sodium intake and the magnitude of the hypertension. The complex relations between the natriuretic responses to increased arterial pressure in the SHR 1-92 Supplement I Hypertension Vol 17, No 1, January 1991 30 WKY 18 8HR 10 IB 80 100 110 140 160 RENAL PCRFUSKW PRESSURE 180 tOO raHg Downloaded from http://hyper.ahajournals.org/ by guest on June 16, 2017 FIGURE 1. Line graph showing urinary sodium excretion responses to step changes in arterial pressure in anesthetized Wistar-Kyoto (WKY) rats and spontaneously hypertensive rats (SHR). Rats were studied at 3-5, 6-9, and 12 weeks of age. Reprinted with permission from Roman.6 have recently been carefully examined by Roman.6 Anesthetized SHR and Wistar-Kyoto (WKY) rats were studied between 3 and 12 weeks of age, and the urinary sodium excretion responses were measured after arterial pressure was increased and decreased by mechanical aortic constriction above and below the kidneys. Circulating factors that may influence urinary sodium excretion (i.e., Ang II, norepinephrine, aldosterone, arginine vasopressin, and atrial natriuretic factor) were held constant by intravenous infusion at low physiological doses. Normotensive WKY rats exhibited a steep natriuretic response to step increases in arterial pressure, and this pressure natriuresis occurred regardless of the age of the rat studied (Figure 1). In contrast, SHR at 3-5 and 6-9 weeks of age exhibited a diminished natriuresis in response to the same step increases in arterial pressure. Furthermore, by 12 weeks of age when the hypertension in these animals was well established, the slope of the pressure natriuresis curve was even further reduced (Figure 1). These results indicated that in the Okamoto strain of SHR, a reduced ability to excrete sodium in response to elevated arterial pressure occurs at very early ages before the onset of the hypertension. At older ages, when the hypertension is well established, the reduction in pressure natriuresis becomes even more pronounced. Thus, a reduced renal capacity to increase sodium excretion in response to an increase in arterial pressure may be responsible in part for the chronic elevation of arterial pressure. As previously described, this notion is further documented by the fact that replacement of the SHR kidney with that of a normotensive WKY rat results in a substantial reduction in the level of the hypertension.3-4 Angiotensin n and Renal Function in Blood Pressure Control One of the factors that may be responsible for limiting the ability of the kidney to respond normally to arterial pressure is the renin-angiotensin-aldosterone axis. In conscious dogs with normal renal function, elevation of sodium intake results in little or no change in arterial pressure because urinary sodium excretion is rapidly elevated to maintain normal sodium and extracellular fluid volume balance and thereby prevent further volume-mediated elevations of arterial pressure.7 Hall et al8 have demonstrated that Ang II blockade with converting enzyme inhibition (SQ 14,225) markedly shifts the pressure-natriuresis relation toward lower arterial pressures. This leftward shift in the pressure-natriuresis curve is particularly pronounced during states of low sodium intake due to the large activation of renin release and subsequent Ang II production in response to sodium depletion. Conversely, low level infusion of Ang II (5.0 ng/kg/min i.v.), which does not alter arterial pressure alone, shifts the renal pressure-natriuresis and -diuresis curves toward higher perfusion pressures necessary to achieve similar rates of urinary sodium excretion.7 The shift in the renal pressure-natriuresis and -diuresis curves toward higher pressures may result from direct tubular antinatriuretic effects of Ang II. Antinatriuresis during chronic Ang II infusion may be a result of activation of aldosterone release from the adrenal glomerulosa. Distal tubular elevation of sodium reabsorption would then result in a net decrease in overall sodium excretion for any given step change in systemic arterial pressure. In addition, pressure natriuresis may be blunted by Ang II at more proximal nephron sites. Specific Ang II receptors have been identified on proximal tubular cells9 and intrarenal Ang II has been shown to increase sodium reabsorption at this site by specific activation of sodium-hydrogen exchange.1011 Intrarenal Ang II then may directly decrease net sodium excretion by increasing total sodium chloride/bicarbonate reabsorption. Thus, the overall influence of Ang II on urinary sodium excretion during step increases in arterial pressure is to limit the natriuretic capacity of the kidney by elevating tubular sodium reabsorption at proximal and distal nephron sites. Normal renal natriuretic and diuretic responses to elevated arterial pressure are essential to the maintenance of body fluid volumes and consequently of arterial pressure homeostasis during low level infusion of circulating hormones such as Ang II, aldosterone, and arginine vasopressin. When renal excretory function is allowed to respond normally to changes in arterial pressure, low level infusions of Ang II or aldosterone do not markedly alter arterial pressure. In contrast, when renal perfusion pressure is held constant at a normal arterial pressure of approximately 100 mm Hg, low level infusion of either Ang II8 or aldosterone12 produces overt and, in some cases, malignant hypertension. This hypertension is associated with continual sodium and water retention and expansion of the extracellular fluid volume. Thus, small alterations in extrinsic circulating hormonal factors do not produce hypertension Osbom under normal conditions; however, in the presence of compromised renal function, such that the kidneys do not respond normally to transient elevations of arterial pressure, low level activation of the reninangiotensin-aldosterone axis produces sodium and water retention and the development of severe arterial hypertension. Renal Sympathetic Nerves, Renal Function, and Arterial Pressure Downloaded from http://hyper.ahajournals.org/ by guest on June 16, 2017 From the previous discussion, a large body of evidence indicates that alteration of renal function by some intrinsic or extrinsic mechanism is required for the chronic elevation of arterial pressure. There are multiple routes by which elevation of renal sympathetic nerve activity may function as the mediator of this alteration in renal function, including stimulation of renin release, elevation of intrarenal or circulating Ang II, redistribution of intrarenal blood flow or glomerular filtration rate, and activation of renal tubular sodium reabsorption. Ultimately, the kidney must function to maintain extracellular fluid volume constant via regulation of urinary sodium excretion. Thus, important interactions must exist between the relative rates of sodium intake, sodium excretion, level of renal sympathetic nerve activity, and arterial pressure. Renal sympathetic nerve activity may alter urinary sodium and water excretion by activating sodium reabsorption by at least two specific mechanisms. First, release of neuroadrenergic transmitter at the juxtaglomerular granular cells increases the release of renin via /3i-adrenergic receptor activation.13-15 This adrenergic stimulation of renin release will consequently increase circulating Ang II and aldosterone and subsequently decrease urinary sodium excretion by the mechanisms previously discussed. Second, renal sympathetic outflow also directly stimulates renal tubular sodium reabsorption at the proximal convoluted tubule16"18 or at the thick ascending limb of the loop of Henle.16 Direct sympathetic innervation of these tubular structures has been identified,19 and the adrenergic receptor mediating these responses has been described by several investigators as a.16-18 Recent evidence indicates that a-adrenergic receptor activation of renal tubular structures increases sodium reabsorption by activation of sodium-hydrogen exchange, eliciting net increases in renal sodium bicarbonate reabsorption.20 It is important to note that direct neurogenic activation of tubular sodium reabsorption will concomitantly decrease the distal delivery of sodium chloride, leading to further activation of renin release via the macula densa. Thus, renal sympathetic nerve activity may have an important influence on the net renal excretion of sodium and water. Under these conditions of elevated renal sympathetic nerve activity, the renal pressure-natriuresis relation can be significantly shifted toward higher pressures, thereby requiring elevated arterial pressure to achieve adequate sodium excretion. Renal Function and Blood Pressure 1-93 Important interactions likely exist between renal sympathetic outflow, renal function, and the ability of the kidney to excrete salt and water. We have evaluated the influence of increasing and decreasing sodium intake on the renal hemodynamic and renin secretion responses to direct electrical stimulation of the renal nerves.21 In that study, sodium depletion enhanced and sodium loading suppressed the renin secretion responses to 0.5,1.0, and 2.0 Hz renal nerve stimulation. These changes in the responses to neural activation of renin secretion likely resulted from an interaction between direct neurotransmitter stimulation of ft-adrenergic receptors and alterations in tubular sodium chloride delivery out of the proximal nephrons to the distal macula densa mechanism for renin release. These results indicated that important interactions exist between sodium chloride intake and the neural control of renin secretion; however, the data also suggested that these responses in normal kidneys would be protective against expansion of the extracellular fluid volume (i.e., sodiumdepleted states lead to exacerbated renin responses and the reverse is also true). In contrast, renal hemodynamic responses to renal nerve stimulation demonstrated markedly different results. Figure 2 documents that elevation of sodium intake rendered the renal vasculature more responsive to renal nerve stimulation. In sodium-depleted anesthetized dogs, renal nerve stimulation did not elicit renal vasoconstriction at 0.5 or 1.0 Hz, whereas dogs placed on a high sodium intake significantly decreased renal bloodfloweven at 0.5 Hz renal nerve stimulation. These data demonstrated that elevation of sodium intake enhanced the renal vascular responses to renal sympathetic outflow either by increasing the release of sympathetic neurotransmitter in the kidney or by increasing the renal vascular responsiveness to intrarenal norepinephrine. Recent evidence also suggests that elevation of renal perfusion pressure interacts with vascular smooth muscle to enhance the renal vascular responsiveness to norepinephrine.22 Thus, important interactions between sodium chloride intake, renal perfusion pressure, and the level of renal sympathetic outflow may result in subtle alterations in renal function, which lead to expansion of the extracellular fluid volume and consequently to elevation of arterial pressure. Recent evidence from this laboratory indicates that the renal sympathetic nerves also have an important influence on the regulation of sodium balance by precisely regulating the rate of decreasing urinary sodium excretion after a step decrease in sodium intake. In six conscious dogs, renal sympathetic efferent nerve activity was continuously monitored, and urinary sodium excretion was simultaneously measured at hourly intervals. Dogs were placed on a high sodium intake by intravenous infusion (5.0 meq/hr) for 7 days. Renal nerve recording electrodes then were implanted, and after recovery, control high sodium intake measurements were made, at which time dogs were switched to a low sodium intake (0.2 1-94 Supplement I Hypertension Vol 17, No 1, January 1991 0.5 Hz LOW NORM HIOH -10 FIGURE 2. Bar graph showing changes in renal blood flow (RBF) in response to renal efferent nerve stimulation (15 V, 1.0 msec) at 0.5, 1.0, and 2.0 Hz. Renal hemodynamic responses were studied in dogs on low, normal, and high sodium intakes. Reprinted with permission from Osborn and Kinstetter.21 -20 "30 ARBF (ml/mln) * =Dilf«r«nt from 0 • = Dlllarant Iron High N»+ OUt -40 -50 Downloaded from http://hyper.ahajournals.org/ by guest on June 16, 2017 -80 -70 _ meq/hr). Measurements were then continued for an additional 30 hours during low sodium intake. As shown in Figure 3, urinary sodium excretion decreased by approximately 3 meq/hr within 12 hours (from a total intake of 5 meq/hr) after sodium intake was decreased. This reduction in sodium excretion was associated with a significant increase in renal sympathetic nerve activity over the same time interval (Figure 3). Subsequent bilateral renal denervation markedly increased the time interval over which dogs achieved sodium balance such that similar decreases in urinary sodium excretion did not occur until 20 hours after reduction of sodium intake. Plasma renin activity and plasma aldosterone concentrations were not significantly altered at 6 and 24 hours after the step decrease in sodium intake.23 These results have been interpreted to suggest that the renal nerves may A A ARSNA «AUN«V Sodium and Water Retention as a Function of Hypertension 400 300 5 en 35 > -2 too -3 0 2 4 8 8 function as an important rapid controller of sodium excretion when sodium intake is altered. Clearly, there exist numerous mechanisms for the maintenance of normal sodium balance when sodium intake changes. The rate at which sodium balance is achieved, however, may primarily be controlled by the renal nerves by induction of rapid alterations in tubular sodium transport. Thus, functional aberrations in the regulation of efferent renal sympathetic outflow could potentially cause transient but significant expansion of the extracellular fluid volume after step changes in sodium intake. These continual expansions and contractions of body fluid volumes could potentially result in a chronic resetting of the renal pressure-natriuresis and -diuresis curves and thereby produce prolonged elevation of arterial pressure. 10 12 14 16 18 20 22 24 28 28 30 32 HOURS AFTER DECREASING Na INTAKE FIGURE 3. Graph showing changes in urinary sodium excretion (UNtV) and renal sympathetic nerve activity (RSNA) of conscious dogs for 30 consecutive hours after sodium intake was decreased. Sodium intake was delivered intravenously at 5.0 meqihr in control (120 meq/day) and decreased to 0.2 meqihr (5.0 meq/day). The hypothesis that sodium and water retention precedes the onset of arterial hypertension has been extensively investigated. For the purposes of the present discussion, recent studies will be presented, which indicate that minimal changes in blood volume are required to elicit significant changes in arterial pressure. In conscious areflexic rats, Hinojosa-Laborde et al24 recently reported that elevation of blood volume by as little as 5% can significantly increase arterial pressure. This significant finding suggested that a very low level elevation of body fluid volume can indeed elevate arterial pressure by increasing cardiac output. It is critical to note, however, that for blood volume increases to lead to chronic elevation of arterial pressure, baroreceptor reflex control of arterial pressure must either be completely reset or impairment of low or high pressure baroreceptor Osbom Na Intake Renal Function Extrinsic Mechanism Intrlnmtc Mechanism Rand Merve /kottvltu taolotenslan II AtTtal Ifatrlu-eflc Factor Aldosterone Ptyslcttl Factors Anglotenslon n Prostaglondlns KtnM CFR Extracellular Fluid Volume Na' Balance Cardiac Output Urinary Na+ Excretion Arterial Pressure Downloaded from http://hyper.ahajournals.org/ by guest on June 16, 2017 FIGURE 4. Schematic diagram of relations between sodium intake and sodium excretion in regulation of extracellular fluid volume and arterial pressure. Intrinsic and extrinsic mechanisms controlling renal function exist in parallel with arterial pressure to regulate urinary sodium excretion and extracellular fluid volume. GFR, glomerular filtration rate. reflexes must exist. Krieger et al25 have similarly shown in normal conscious dogs that low dose Ang II infusion (5 ng/kg/min i.v.) in combination with a high sodium chloride intake (120 meq/day) elicits arterial hypertension that is preceded by sodium and water retention and elevation of cardiac output. The calculated elevation of blood volume from this sodium and water retention was approximately 5% of that in the normotensive state. This arterial hypertension was prevented under conditions in which sodium and water retention was prevented by fixing total body water constant by a servocontrol system. Thus, recent evidence in both conscious rats and dogs indicates that small changes in blood volume may significantly elevate cardiac output and arterial pressure. For this elevation of arterial pressure to result in chronic hypertension, some alteration in baroreceptor reflex control of sympathetic outflow would be required. However, alterations in renal sympathetic outflow may also contribute to the increase in arterial pressure by further facilitating renal sodium and water retention. Renal Function, Sodium Balance, and Control of Arterial Pressure The regulation of extracellular fluid volume and cardiac output are known to be important controllers of arterial pressure.26 The relations between extracellular fluid volume, sodium intake, sodium excretion, and arterial pressure are depicted in Figure 4. Compensation for changes in sodium intake, and consequently control of extracellular fluid volume, must be achieved by increasing and decreasing urinary sodium excretion. Previous studies have shown the steep relation between arterial pressure and the excretion of sodium by the kidneys. However, this relation is dependent on normal renal function and the proper balance between both the intrinsic and extrinsic mechanisms that continually influence renal function. Renal Function and Blood Pressure 1-95 Renal function and ultimately the renal responses to arterial pressure can be markedly influenced by the extrinsic and intrinsic factors. Activation of the renin-angiotensin-aldosterone axis and alteration of renal sympathetic outflow may directly affect intrarenal handling of sodium and water, which may interrupt the normal maintenance of extracellular fluid volume homeostasis. These factors also do not function in a fashion that is mutually exclusive. In this regard, elevation of circulating Ang II or activation of renal sympathetic outflow may also cause major changes in intrarenal physical factors, Ang II, prostaglandins, kinins, glomerular filtration rate, or intrarenal hemodynamics. Any one or a combination of these factors may sufficiently alter renal function in such a way that the renal ability to rapidly elevate urinary sodium excretion in response to a challenge of increased sodium intake is reduced. Under these circumstances, the resultant expansion of extracellular fluid volume elevates arterial pressure to overcome this excretory deficit and thereby return body fluid volumes to a normal state. Thus, the kidney functions in a vital capacity in the long-term control of arterial pressure by regulation of extracellular fluid volume. Subtle alterations in renal excretory function during periods of elevated sodium intake result in the maintenance of normal bodyfluidvolumes at the expense of chronically elevating arterial pressure and thus producing the onset of arterial hypertension. References 1. Cowley AC, Roman RJ: Renal dysfunction in essential hypertension—Implications of experimental studies. Am J Nephrol 1983^:59-72 2. Tobian L, Lange J, Azar S, Iwai J, Koop D, Coffee K, Johnson MA: Reduction of natriuretic capacity and renin release in isolated blood-perfused kidneys of Dahl hypertension-prone rats. Ore Res 1978;43(suppl I):I-92-I-98 3. Kawabe K, Watanabe TX, Shiono K, Sokabe H: Influence on blood pressure of renal isografts between spontaneously hypertensive and normotensive rats utilizing F] hybrids. Jpn Heart J 1978;19:886-894 4. Fox U, Bianchi G: The primary role of the kidney in causing the blood pressure difference between the Milan hypertensive strain (MHS) and normotensive rats. Clin Exp Pharmacol Physiol 1976;3(suppl):71-74 5. Dahl LK, Heine M: Primary role of renal homographs in setting chronic blood pressure levels in rats. Ore Res 1975^36: 692-696 6. Roman RJ: Altered pressure natriuresis relationships in young spontaneously hypertensive rats. Hypertension 1987;9(suppl III): m-130-m-136 7. Hall JE, Guyton AC, Smith MJ Jr, Coleman TG: Blood pressure and renal function during chronic changes in sodium intake: Role of angiotensin. Am J Physiol 1980;239:F271-F280 8. Hall JE, Granger JP, Hester RL, Coleman TG, Smith MJ Jr, Cross RB: Mechanisms of escape from sodium retention during angiotensin II hypertension. Am J Physiol 1984;246: F627-F634 9. Douglas JG: Angiotensin II receptor subtypes of the kidney cortex. Am J Physiol 1987;253:F1-F7 10. Liu FY, Cogan MG: Angiotensin II stimulation of hydrogen ion secretion in the rat early proximal tubule: Modes of action, mechanism and kinetics. / Clin Invest 1988;82:601-608 1-96 Supplement I Hypertension Vol 17, No 1, January 1991 Downloaded from http://hyper.ahajournals.org/ by guest on June 16, 2017 11. Liu FY, Cogan MG: Angiotensin II stimulates early proximal bicarbonate absorption in the rat by decreasing cyclic adenosine monophosphate. / Clin Invest 1989;84:83-91 12. Hall JE, Granger JP, Smith MJ Jr, Premen AJ: Role of renal hemodynamics and arterial pressure aldosterone "escape." Hypertension 1984;6(suppl I):I-183-I-192 13. Osborn JL, DiBona GF, Thames MD: ft Receptor mediation of renin secretion elicited by low frequency renal nerve stimulation. / Pharmacol Exp Ther 1981;216:265-269 14. Johns EJ: An investigation into the type of 0-adrenoceptor mediating sympathetically activated renin release in the cat Br /Pharmacol 1981;73:749-754 15. Kopp UC, Aurell IM, Nilsson IG, Ablad B: The role of /3-adrenoceptors in the renin release response to renal sympathetic nerve stimulation. PflugersArch 1980-387:107-113 16. DiBona GF: Neural control of renal function: Role of renal o-adrenoceptors. / Cardiovasc Pharmacol 1985;8:S18-S23 17. Hesse IFA, Johns EJ: The role of o-adrenoceptors in the regulation of renal tubular sodium reabsorption and renin secretion in the rabbit. Br J Pharmacol 1985;84:715-724 18. Osborn JL, Holdaas H, Thames MD, DiBona GF: Renal adrenoceptor mediation of antinatriuretic and renin secretion responses to low frequency renal nerve stimulation in the dog. Ore Res 1983^3:298-305 19. Barajas L, Powers L, Wang P: Innervation of the renal cortical tubules: A quantitative study. Am J Physiol 1984;247:F50-F60 20. Osborn JL, Harland RW: arAdrenoceptor mediation of urinary bicarbonate excretion. Am J Physiol 1988;255: F1116-F1121 21. Osborn JL, Kinstetter DD: Effects of altered N a d intake on renal hemodynamic and renin release responses to RNS. Am J Physiol 1987;253:F976-F981 22. Lombard JH, Eskinder H, Kauser K, Osborn JL, Harder DR: Enhanced norepinephrine sensitivity in renal arteries at elevated transmural pressure. Am J Physiol 1990-,259:H29-H33 23. Osborn JL: Neurogenic mediation of antinatriuresis following reduction of sodium intake in conscious dogs. Kidney Int 1989;35:471 24. Hinojosa-Laborde C, Greene AS, Cowley AW Jr: Whole body autoregulation in conscious areflexic rats during hypoxia and byptroxiz.AmJ Physiol 1989;256:H1023-H1029 25. Krieger JE, Roman RJ, Cowley AW Jr: Hemodynamics and blood volume in angiotensin II salt-dependent hypertension in dogs. Am J Physiol 1989;257:H14O2-H1412 26. Cowley AW Jr, Barber WJ, Lombard JH, Osborn JL, liard JF: Relationship between body fluid volumes and arterial pressure. Fed Proc 1986;45:2864-2870 KEY WORDS • renal function • sodium excretion • blood pressure • kidney Relation between sodium intake, renal function, and the regulation of arterial pressure. J L Osborn Hypertension. 1991;17:I91 doi: 10.1161/01.HYP.17.1_Suppl.I91 Downloaded from http://hyper.ahajournals.org/ by guest on June 16, 2017 Hypertension is published by the American Heart Association, 7272 Greenville Avenue, Dallas, TX 75231 Copyright © 1991 American Heart Association, Inc. All rights reserved. Print ISSN: 0194-911X. Online ISSN: 1524-4563 The online version of this article, along with updated information and services, is located on the World Wide Web at: http://hyper.ahajournals.org/content/17/1_Suppl/I91 Permissions: Requests for permissions to reproduce figures, tables, or portions of articles originally published in Hypertension can be obtained via RightsLink, a service of the Copyright Clearance Center, not the Editorial Office. 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