Microalbuminuria in salt-sensitive patients. A marker for renal and cardiovascular risk factors

Cardiovascular complications in patients with primary aldosteronism

Primary aldosteronism (PA) is widely believed to be a relatively benign form of hypertension associated with a low incidence of vascular complications. However, several recent studies showed that cardiovascular complications were not rare in PA. PA is known as one of the most typical forms of sodium-sensitive hypertension. Recently, we found that the sodium sensitivity of blood pressure was a marker for greater risk for cardiovascular complications, especially stroke, in patients with essential hypertension. Therefore, we investigated cardiovascular complications in 58 patients with PA confirmed to be Conn's adenoma. Cardiovascular complications were found in 34% of 58 patients. Coronary artery disease was found in only one patient (1.7%), as angina pectoris. Stroke was found in nine patients (15.5%), four patients (6.9%) with cerebral infarctions and five patients (8.6%) with cerebral hemorrhages. Proteinuria and renal insufficiency were found in 14 (24.1%) and 4 (6.9%) patients, respectively. The incidence of cerebral infarction and renal insufficiency was greater in men than women. The prevalence of proteinuria was greater in patients with than without stroke (P = 0.03) among those aged older than 40 years. These results indicated that cardiovascular complications, especially stroke and proteinuria, were common in patients with PA, and proteinuria might be an indicator for stroke as target-organ damage.

Genetic polymorphism of CYP11B2 gene and hypertension in Japanese

Low-renin hypertension is characterized by a high ratio of aldosterone to plasma renin activity (ALD/PRA), which may suggest inappropriately increased aldosterone biosynthesis. The genes for the enzymes involved in aldosterone synthesis may contribute to low-renin hypertension. We investigated the associations between genetic variations of CYP11B2 (aldosterone synthase) T(-344)C and hypertension in 482 Japanese subjects. Subjects older than 50 years with a blood pressure <140/85 mm Hg were considered normotensive (n=227 subjects), and subjects younger than 65 years old with a BP >160/95 mm Hg were considered hypertensive (n=255 subjects). The frequency of the TC+CC genotypes in the normotensive group was significantly lower than in the hypertensive group. Logistic analysis on 482 subjects revealed that body mass index, gender, and the genotype of CYP11B2 T(-344)C were significantly associated with hypertension. ALD and PRA were assessed in 97 subjects with hypertension, and the TC+CC genotypes were significantly associated with higher ALD/PRA. Sixty-five subjects with hypertension were assessed by 24-hour ambulatory blood pressure monitoring, and the frequency of nondippers (a difference in mean blood pressure of <10% between the daytime [6 AM to 9 PM] and nighttime [9 PM to 6 AM] hours) was significantly higher in subjects with the TC+CC (hetero+homo mutation) genotype than in subjects with the TT (wild-type) genotype. Echocardiographic assessment (n=136) revealed that the ratio of left ventricular end-diastolic dimension to height tended to be higher in subjects with the TC+CC genotype than in subjects with the TT genotype. The present study suggests that the (-344)C allele of the CYP11B2 gene may be a genetic marker for low-renin hypertension in Japanese.

Microalbuminuria in essential hypertension

Microalbuminuria is frequently seen in patients with established essential hypertension, and is a predictor of a higher risk for cardiovascular and probably renal dysfunction. The presence of microalbuminuria has been shown to correlate with the other cardiovascular risk factors commonly seen in hypertensive patients. This fact indicates that the detection of an increased urinary albumin excretion could probably be the best index of an increased global cardiovascular risk in a given patient. Blood pressure control is accompanied by a fall in the content of albumin in urine. Agents with the capacity to block the renin-angiotensin system have shown a capacity to decrease urinary albumin excretion, which is independent of their ability to lower blood pressure. Whether or not a decrease in urinary albumin excretion is accompanied by an improved renal and cardiovascular prognosis in hypertensive patients remains to be elucidated.

Clustering of endothelial markers of vascular damage in human salt-sensitive hypertension: influence of dietary sodium load and depletion

The contributing role of vascular endothelium in the development of hypertension-related vascular damage is well accepted. Salt-sensitive hypertension is characterized by a cluster of renal, hormonal, and metabolic derangements that might favor the development of cardiovascular and renal damage. To evaluate endothelial involvement in salt-sensitive essential hypertension, plasma levels of several markers of endothelial damage such as endothelin-1 (ET-1), von Willebrand factor (vWf), and soluble (S-) adhesion molecules E-selectin, intercellular adhesion molecule-1 (ICAM-1), vascular cell adhesion molecule-1 (VCAM-1), and 24-hour urinary albumin excretion (UAE) were measured in 39 nondiabetic, nonobese, never-treated essential hypertensive patients after intermediate (120 mmol/d), high (220 mmol/d), and low (20 mmol/d) NaCl diets. Patients were classified as salt sensitive (n=18) or salt resistant (n=21) according to their blood pressure responses to changes in dietary NaCl intake. Salt-sensitive hypertensives showed higher plasma ET-1 (P<0.05), vWf (P<0.005), and S-E-selectin levels (P<0.04) and increased UAE (P<0.05) than salt-resistant hypertensives. By contrast, circulating S-ICAM-1 and S-VCAM-1 concentrations were not significantly higher in salt-sensitive (596. 56+/-177.05 ng/mL and 541.06+/-157.84 ng/mL, respectively) than salt-resistant patients (516.86+/-147.99 ng/mL and 449.48+/-158.91 ng/mL, respectively). During the intermediate NaCl diet, plasma ET-1 responses to oral glucose load were greater in salt-sensitive (P<0. 05) than in salt-resistant patients. A marked (P<0.05) hyperinsulinemic response to oral glucose load was evident in salt-sensitive but not salt-resistant patients after each diet. This study shows increased plasma levels of the endothelium-derived substances E-selectin, vWf, and ET-1 in salt-sensitive hypertensives. Our findings support the hypothesis that salt sensitivity is correlated with an increased risk for developing hypertension-related cardiovascular damage.

Combination of ACE inhibitors and calcium antagonists: a logical approach

An increasing body of evidence indicates that impairment of endothelial function is crucially involved in the pathogenesis of cardiovascular disease. Injury to the endothelium precipitates atherosclerosis by causing smooth-muscle cell migration and proliferation, induction of expression of growth factors, and impairment of plasma coagulation and endogenous fibrinolysis. Angiotensin-converting enzyme (ACE) inhibitors and calcium antagonists are widely used in patients with cardiovascular disease and have beneficial vascular effects beyond blood pressure control alone. Both exhibit a synergistic hemodynamic profile. Whereas calcium antagonists dilate large conduit and resistance arteries, ACE inhibitors inhibit the renin-angiotensin system (RAS) and reduce sympathetic outflow. Certain calcium antagonists, such as verapamil and diltiazem, reduce heart rate, whereas dihydropyridines tend to increase it. In the blood vessel wall, the local vascular effects of ACE inhibitors and calcium antagonists are complementary. ACE inhibitors diminish transformation of angiotensin I (Ang I) into angiotensin II (Ang II) and prevent degradation of bradykinin [which stimulates nitric oxide (NO) and prostacyclin formation]. Calcium antagonists inhibit the effects of Ang I and endothelin-1 (ET-1) at the level of vascular smooth muscle by reducing Ca2+ inflow and facilitating the vasodilator effects of NO. The resistance circulation is particularly dependent on extracellular Ca2+, thereby explaining why nifedipine and verapamil effectively inhibit ET-induced vasoconstriction in vitro and in vivo. In hypertension, ACE inhibitors and calcium antagonists markedly improve structural changes and increase the media/lumen ratio in resistance arteries. Long-term combination therapy with verapamil and trandolapril is particularly effective in reversing endothelial dysfunction in hypertensive animals. ACE inhibitors substantially reduce morbidity and mortality in patients with left ventricular dysfunction after myocardial infarction (MI). There is a strong trend indicating benefit with verapamil as well, but this is confined to patients with a normal left ventricular ejection fraction. Clinical studies have confirmed that calcium antagonists exhibit antiatherogenic properties. However, the clinical relevance of these findings has recently been disputed because short-acting dihydropyridines are reported to increase risk for MI. Because ACE inhibitors and calcium antagonists exhibit synergistic hemodynamic, antiproliferative, antithrombotic, and antiatherogenic properties, combination therapy provides a promising concept in patients with cardiovascular and renal disease.

Salt sensitivity: concept and pathogenesis

Almost two decades ago, the existence of a subset of essential hypertensive patients, who were sensitive (according to the increase in blood pressure levels) to the intake of a diet with a high salt content, was described. These patients are characterized by an increase in blood pressure and in body weight when switched from a low to a high sodium intake. The increase in body weight is due to the incapacity of the kidneys to excrete the whole intake of sodium until renal perfusion pressure (mean blood pressure) attains a level that is able to restore pressure-natriuresis relationship to values that enable the kidney to excrete the salt ingested or administered intravenously. Salt sensitivity does not seem to depend on the existence of an intrinsic renal defect to handle sodium, but on the existence of subtle abnormalities in the regulation of the sympathetic nervous system, the renin-angiotensin system or endothelial function. It is also relevant that organ damage secondary to arterial hypertension, has been shown in animal models and in hypertensive humans sensitive to a high salt intake to be significantly higher when compared with that of salt-resistant animals or humans. Interestingly, in humans, salt sensitivity has been shown to correlate with microalbuminuria, an important predictor of cardiovascular morbidity and mortality, which correlates with most of the cardiovascular risk factors commonly associated with arterial hypertension. One of these factors is insulin resistance, that usually accompanies high blood pressure in overweight and obese hypertensives. Insulin resistance and hyperinsulinism are present in a significant percentage of hypertensive patients developing cardiovascular symptoms or death. For these reasons, therapy of arterial hypertension must be directed, not only to facilitate the lowering of BP level, but also, to halt the mechanisms underlying the increase in BP, when salt intake is increased. Furthermore, therapy must preferably improve the diminished insulin sensitivity present in salt-sensitive subjects that contribute independently to increased cardiovascular risk.

Insulin sensitivity is associated with blood pressure response to sodium in older hypertensives

The purpose of this study was to determine whether sodium-resistant hypertensives are more insulin resistant and whether dietary sodium restriction improves insulin sensitivity in older hypertensives. Insulin sensitivity was assessed by a frequently sampled intravenous glucose tolerance test to determine the insulin sensitivity index (SI) after 1 wk each of low- (20 mmol.l-1.day-1) and high- (200 mmol.l-1.day-1) sodium diets in 21 older (63 +/- 2 yr) hypertensives. Subjects were grouped on the difference in mean arterial blood pressure (MABP) between diets [sodium sensitive (SS): > or = 5-mmHg increase in MABP on the high-sodium diet (n = 14); sodium resistant (SR): < 5-mmHg increase in MABP on the high-sodium diet (n = 7)]. There was no dietary sodium effect on fasting plasma insulin or SI. An analysis of variance indicated a significant (P = 0.0002) group effect, with SS individuals having lower fasting plasma insulins on the low- (13 +/- 2 vs. 27 +/- 3 microU/ml) and high- (12 +/- 2 vs. 22 +/- 3 microU/ml) sodium diets compared with SR individuals. Similarly, there was a significant (P = 0.0002) group effect in regard to SI, with SS individuals having significantly higher SI on the low- (3.26 +/- 0.60 vs. 0.91 +/- 0.31 microU x 10(-4).min-1.ml-1) and high- (3.45 +/- 0.51 vs. 1.01 +/- 0.30 microU x 10(-4).min-1.ml-1) sodium diets compared with SR individuals. We conclude that SR individuals exhibit a greater degree of insulin resistance than SS individuals and that dietary sodium restriction fails to improve insulin sensitivity regardless of sodium sensitivity status.

Salt sensitivity and left ventricular hypertrophy

Essential hypertensive patients with left ventricular hypertrophy (LVH) increase their mortality rates due to all cardiovascular diseases from 3 to 10 times more than hypertensives without signs of cardiac hypertrophy. LVH modifies the equilibrium between the oxygen supply and demand by the myocardium. The coronary reserve is appreciably reduced in hypertensives with LVH even in the absence of any stenosis of coronary arteries. Thus, in patients with normal coronary angiogram, a predisposition toward myocardial ischemia already exists. This process has been associated with the increased incidence of ventricular arrhythmias in essential hypertensives with LVH, what could be linked to the increasing risk of sudden death in these patients. In addition to hemodynamic factors (pressure and volume overload) several non-hemodynamic factors have been involved in the pathogenesis of LVH in hypertension. LVH would develop in subjects with a particular genetic substrate by the overlap of high blood pressure values and several factors linked to the adrenergic system, the renin-angiotensin-aldosterone system, other vasoactive substances, and growth factors. It has been previously reported that NaCl ingestion is a powerful determinant of left ventricular hypertrophy in patients with essential hypertension. Furthermore, a relationship between left ventricular mass and abnormalities in intracellular Na+ or transmembrane Na+ transport has been observed in several studies. Salt-sensitive hypertensive subjects seem to exhibit an increased risk in terms of cardiovascular morbidity. We and others have observed a higher left ventricular mass, an increased albumin excretion rate and a worse lipid profile in salt-sensitive compared with salt-resistant patients. The increase in LVMI in salt-sensitive patients is mainly due to the increase in septal and posterior wall thickness, with normal diastolic diameter, suggesting that myocardial growth in these patients is not volume-dependent. The mechanism of this structural cardiac adaptation is not completely understood. Nevertheless, it is known that salt-sensitive and salt-resistant hypertensive patients differ in some adaptive responses to changes in dietary salt intake. Among them, the renin-aldosterone axis, the sympathetic nervous system and the intracellular ion composition could play a role in the development of myocardial growth. In conclusion, salt-sensitive hypertensive patients exhibited an increased LVMI and a worse lipid profile, compared with salt-resistant hypertensives, even at the same level of blood pressure. These characteristics may confer to salt-sensitive patients an increased risk in terms of cardiovascular morbidity and mortality.

Sodium sensitivity and cardiovascular events in patients with essential hypertension

BACKGROUND

In patients with sodium-sensitive hypertension, glomerular pressure is increased and microalbuminuria, a marker of glomerular hypertension, is a predictor of cardiovascular events. Similarly, the lack of a nocturnal decrease in blood pressure in these patients is also associated with an increased risk of cardiovascular events. We hypothesised that sodium sensitivity may be the common factor and carried out a retrospective study of cardiovascular events in patients with essential hypertension who had had sodium sensitivity measured in our clinic.

METHODS

Sodium sensitivity was assessed in about 350 patients with essential hypertension during the initial investigation of their disorder. The definition of sodium sensitivity was a 10% or greater difference in blood pressure on low-sodium or high-sodium diets. By alphabetical order, the records of 201 patients were obtained and 156 patients without pre-existing disorders were followed up. The records of patients who had a cardiovascular event or died were reviewed without knowledge of the patient's sodium-sensitivity status.

FINDINGS

62 patients were deemed sodium sensitive and 94 non-sodium sensitive. Left-ventricular hypertrophy was found more frequently in the sodium-sensitive group than in the non-sodium-sensitive group (38 vs 16%; p < 0.01), whereas significantly fewer patients in this group smoked (23 vs 42%; p < 0.05). There were 17 cardiovascular events in the sodium-sensitive group and 14 in the non-sodium-sensitive group. The rate of total, non-fatal and fatal cardiovascular events, was 2.0 per 100 patient-years in the non-sodium-sensitive group and 4.3 per 100 patient-years in the sodium-sensitive group. Cox's proportional-hazards model identified sodium sensitivity (p < 0.01), mean arterial pressure (p < 0.01), and smoking (p < 0.01) as independent cardiovascular risk factors.

INTERPRETATION

Cardiovascular events occurred more frequently in patients with sodium-sensitive hypertension. Sodium sensitivity is an independent cardiovascular risk factor in Japanese patients with essential hypertension.

Treatment of patients with essential hypertension and microalbuminuria

There has been increasing interest in the question of whether microalbuminuria can be used in the risk stratification of patients with essential hypertension. A cluster of cardiovascular and/or renal risk factors may be associated with microalbuminuria in hypertension. Despite this, prospective data about the potential role of microalbuminuria as a prognostic marker of cardiovascular and/or renal risk have been sparse and inconclusive until now. Blood pressure values have been considered the most important determinant of microalbuminuria in essential hypertension; however, hyperinsulinaemia--a metabolic component-was noted to be present in conjunction with high blood pressure. Furthermore, 2 other factors may be also related to microalbuminuria: salt sensitivity and renal structural changes (nephrosclerosis). We are now aware that the clinical and physiological implications of abnormal urinary albumin excretion (UAE) are much broader than anticipated, possibly involving haemodynamic, metabolic and vascular components overlapping several clinical syndromes. Achievement of short term UAE reduction with antihypertensive treatment depends on structural abnormalities established in the glomerulus, the extent of blood pressure reduction and the antihypertensive drug class used. In terms of UAE reduction, better results are obtained with ACE inhibitors or angiotensin II antagonists such as losartan and valsartan, than with other antihypertensive classes, although their true impact in preserving renal function needs to be assessed. The capacity of new calcium antagonists, such as amlodipine, lacidipine or mibefradil, to reduce UAE also needs to be assessed further. Thus, microalbuminuria may be seen as an integrated marker of risk and should be assessed in recently diagnosed patients with essential hypertension. In microalbuminuric patients, the target should be to decrease blood pressure < 135/85 mm Hg, reduce salt intake to around 100 mmol/day and prescribe a low-calorie diet if obesity is present. ACE inhibitors or angiotensin II antagonists have more potential benefits than the other classes of antihypertensive drugs in reducing UAE. Finally, a yearly assessment of microalbuminuria is recommended during treatment, to monitor the impact of therapy.

Hypothesis: the role of acquired tubulointerstitial disease in the pathogenesis of salt-dependent hypertension

We present a new hypothesis to explain the development of salt-dependent hypertension in humans. We propose that hypertension has two phases: an early phase in which elevations in blood pressure (BP) are mainly episodic and are mediated by a hyperactive sympathetic nervous or renin-angiotensin system, and a second phase in which BP is persistently elevated and that is primarily mediated by an impaired ability of the kidney to excrete salt (NaCl). We propose that the transition from the first phase to the second occurs as a consequence of catecholamine-induced elevations in BP that preferentially damage regions of the kidney (juxtamedullary and medullary regions) that do not autoregulate well to changes in renal perfusion pressure. The catecholamine response is associated with both an increase in peritubular capillary pressure and a reduction in peritubular capillary plasma flow, resulting in injury to the peritubular capillaries with ischemia to the tubules and interstitium. The local injury triggers the release or activation (angiotensin II, adenosine, renal sympathetic nerves) or inhibition (nitric oxide, prostaglandins, dopamine) of vasoactive mediators that further augment ischemia and result in abnormal tubuloglomerular feedback and enhanced NaCl reabsorption. The peritubular capillary injury with rarefaction simultaneously blunts the pressure natriuresis mechanism. The combined effect of enhanced tubuloglomerular feedback and impaired pressure natriuresis results in a defect in NaCl excretion which, on the exposure to salt, results in the development of persistent hypertension. Evidence is provided to suggest that this may be the major mechanism for the development of salt-dependent hypertension, and particularly for the hypertension associated with blacks, aging and obesity. Thus, essential hypertension may be a type of acquired tubulointerstitial renal disease.

Endothelial dysfunction and cardiorenal injury in experimental salt-sensitive hypertension: effects of antihypertensive therapy

BACKGROUND

Pharmacological control of hypertension has contributed to a significant decrease in cardiovascular morbidity and mortality, although the beneficial effect on cardiac and renal diseases has been far more modest than the reduction in stroke. The endothelium plays a crucial homeostatic role in the regulation of vascular tone thrombogenesis and vascular remodeling. We studied the relationship between endothelial dysfunction and cardiorenal injury in hypertensive rats and evaluated the effects of two classes of antihypertensive agents commonly used in the clinical setting, a diuretic (DIU) and an ACE inhibitor (CEI).

METHODS AND RESULTS

Dahl salt-sensitive rats (DS) given high dietary salt (4% NaCl) developed hypertension (systolic blood pressure [SBP], 218+/-9 versus 147+/-3 mm Hg in DS given 0.5% NaCl; P<.001), which was associated with impaired endothelium-dependent relaxations (EDRs) in aortic rings (ED50, 5.44+/-.18 versus 7.51+/-.10; P<.05) and mesenteric vessels (area under the curve, 299+/-11 versus 217+/-11 arbitrary units; P<.05). Hypertensive DS also demonstrated depressed nitric oxide synthase activity in the aorta (0.76+/-.15 versus 2.83+/-.17 nmol x min(-1) x g protein(-1); P<.05), left ventricular hypertrophy (0.43+/-.02 versus 0.29+/-.02 g ventricular weight/100 g body weight; P<.05), glomerular injury (histological injury score: 151+/-8 versus 11+/-2; P<.05), and increased urinary protein excretion (95+/-21 versus 25+/-5 mg/24 hours; P<.05). Treatment of DS rats with the CEI perindopril (4.56 mg x kg(-1) x d(-1)) did not affect SBP (225+/-6 mm Hg) but modestly improved EDR (ED50: 6.07+/-.37; P<.05 versus hypertensive DS) as well as proteinuria and glomerular histology. Addition of the DIU indapamide (1.44 mg x kg(-1) x d(-1)) normalized SBP (151+/-2 mm Hg; P<.05), EDR (ED50, 7.33+/-.08; P<.05), left ventricular hypertrophy (0.27+/-.01 g/100 g body weight; P<.05), and proteinuria (31+/-4 mg/24 hours; P<.05) and prevented glomerular injury (injury score: 30+/-2; P<.05). Monotherapy with DIU reduced SBP (175+/-3 mm Hg; P<.05) and normalized EDR and left ventricular hypertrophy but did not provide effective renal protection. In hypertensive DS, impaired EDR and left ventricular hypertrophy were positively correlated with SBP. In addition, we found a significant correlation between cardiac hypertrophy and endothelial dysfunction. Indeed, a hierarchical regression analysis revealed that impaired aortic EDR, and therefore decreased aortic compliance, positively contributed to left ventricular hypertrophy in addition to but independently of SBP [F(2,37)=6.29; P=.004].

CONCLUSIONS

These studies suggest a dissociation of the endothelial, cardiac, and renal effects of antihypertensive therapy in hypertension and may explain the variable success of antihypertensive regimens in treating hypertension while preventing cardiac and renal damage.

Implications of the linear pressure-natriuresis relationship and importance of sodium sensitivity in hypertension

Although the concept of the pressure-natriuresis curve is very clear, considerable confusion concerning its importance and utility in understanding the pathophysiology of hypertension persists. We recently showed that the pressure-natriuresis curve could be considered linear. In this brief review, we would like to stress the advantages of treating it as a line. Its linear approximation simplifies understanding of the sodium sensitivity of the blood pressure and mechanisms of hypertension. The blood pressure can be expressed as the sum of two components: the non-sodium-sensitive component determined by the x intercept of the pressure-natriuresis curve and the sodium sensitive one determined by the product of the reciprocal of the slope and the amount of sodium intake. Theoretically, it can be affected in two different ways to cause hypertension; either a parallel shift along the blood pressure axis toward a higher blood pressure level due to the increase in the x intercept or a decrease in the slope. The parallel shift induces non-sodium-sensitive hypertension, whereas the decrease in slope induces sodium-sensitive hypertension. Thus, the linear approximation makes the definition of the sodium sensitivity of the blood pressure very clear and, furthermore, suggests that mechanisms of hypertension can be clarified if the determinants of the x intercept and the slope of the pressure-natriuresis curve are known. A clear definition of sodium sensitivity allows us to study its importance as a marker of a greater risk of renal and cardiovascular complications.

Sodium restriction shifts circadian rhythm of blood pressure from nondipper to dipper in essential hypertension

BACKGROUND

Sodium restriction has been widely used for treatment of hypertension and renal diseases. Whether sodium restriction can transform the circadian rhythm of blood pressure from nondipper to dipper is examined.

METHODS AND RESULTS

Patients (n=42) with essential hypertension were maintained on a high-sodium diet (12 to 15 g of NaCl per day) and a low-sodium diet (1 to 3 g/d) for 1 week each. On the last day of each diet, blood pressures were measured noninvasively every hour for 24 hours with an automatic oscillometric device. Twenty-one patients were classified as non-sodium sensitive whereas 21 were classified as sodium sensitive on the basis of a > or = 10% change in 24-hour mean arterial pressure caused by sodium restriction. Nocturnal blood pressure fall was significant in the non-sodium sensitive subjects but not in sodium-sensitive subjects. There was a significant interaction between sodium restriction and nocturnal fall in blood pressure only in the sodium-sensitive subjects, indicating that the degree of the nocturnal fall was affected by sodium restriction. Furthermore, changes in the nocturnal fall induced by sodium restriction had a positive relationship with sodium sensitivity (r=.38, P<.02) and a negative relationship with the nocturnal fall before sodium restriction (r=-.75, P<.0001).

CONCLUSIONS

These findings show the difference in nocturnal fall in blood pressure between the non-sodium sensitive and sodium-sensitive types of essential hypertension. The diminished nocturnal fall, recognized in the sodium-sensitive type, is restored by sodium restriction, indicating that the circadian rhythm of blood pressure shifted from a nondipper to a dipper pattern. On the other hand, the nocturnal fall is not affected by sodium restriction in the non-sodium sensitive type, and the circadian rhythm remains of the dipper variety.

Nephropathy of type II diabetes: evidence for hereditary factors?

Family studies point to an important genetic element in the genesis of diabetic nephropathy, but it is not known whether renal abnormalities are present prior to the onset of diabetes. To address this issue we examined all consecutive patients suffering from type II diabetes with a duration of more than 10 years who attended a diabetes outpatient clinic. Ninety-four patients had nephropathy, 307 did not. All offspring who were phenotypically normal (no hypertension, normal oral glucose tolerance, non-smoking) and agreed to participate were examined, 26 from nephropathic and 30 from non-nephropathic diabetic parents. They were compared with 30 offspring matched for age, gender and BMI from non-diabetic parents as controls. We measured urinary albumin excretion under baseline conditions and at several time points after ingestion of 300 g cooked beef and submaximal treadmill exercise, respectively. In addition, casual blood pressure, ambulatory blood pressure, urinary albumin and urinary alpha-1-microglobulin were measured. Primary renal disease was excluded by clinical examination. Under baseline conditions, median urinary albumin excretion rate (AER; microgram/min) was significantly (P < 0.005) higher in offspring of nephropathic type II diabetic patients (7.8; range 1.04 to 19.5) than in the offspring of non-nephropathic type II diabetic patients (4.8; 0.36 to 17.5) and controls (4.4; 0.16 to 18.4). Submaximal treadmill exercise caused a greater proportional increase of AER in offspring of nephropathic type II diabetics (median 16-fold) than in offspring of non-nephropathic diabetic patients (6.3-fold) or controls (4.8-fold). In offspring of nephropathic diabetic patients casual and particularly ambulatory systolic blood pressures were significantly higher, but AER was not correlated with blood pressure. In summary, higher values, albeit within the normal range, for baseline and postexercise albuminuria were noted in phenotypically normal offspring of parents with type II diabetes and nephropathy. The observation suggests that changes in transglomerular albumin traffic are demonstrable prior to the onset of diabetes and diabetic nephropathy in subjects with a potential genetic predisposition to these conditions.

Hypertension-related morbidity and mortality in the southeastern United States

Stroke mortality is higher in the Southeast compared with other regions of the United States. The prevalence of hypertension is also higher (black men = 35%, black women = 37.7%, white men = 26.5%, white women = 21.5%), and the proportion of patients whose hypertension is being controlled is poor, especially in white and black men. The prevalence of hypertension-related complications other than stroke is also higher in the Southeast. The five states with the highest death rates for congestive heart failure are all in the southern region. Of the 15 states with the highest rates of end-stage renal disease, 10 are in the Southeast. Obesity is very prevalent (24% to 28%) in the Southeast. Although Michigan tops the ranking for all states, 6 of the top 15 states are in the Southeast, as are 7 of the 10 states with the highest reported prevalence regarding no leisure-time physical activity. Similar to other areas of the United States, dietary sodium and saturated fat intake are high in the Southeast; dietary potassium intake appears to be relatively low. Other factors that may be associated with the high prevalence, poor control, and excess morbidity and mortality of hypertension-related complications in the Southeast include misperceptions of the seriousness of the problem, the severity of the hypertension, lack of adequate follow-up, reduced access to health care, the cost of treatment, and possibly, low birth weights. The Consortium of Southeastern Hypertension Control (COSEHC) is a nonprofit organization created in 1992 in response to a compelling need to improve the disproportionate hypertension-related morbidity and mortality throughout this region. The purpose of this position paper is to summarize the data that document the problem, the consequences, and possible causative factors.

Insulin resistance, elevated glomerular filtration fraction, and renal injury

The development of insulin resistance may be an early step in the development of hypertension; however, the mechanism for this process is not known. The worsening of insulin resistance and hypertension could increase both systemic and glomerular capillary pressures and predispose an individual to renal injury. The purpose of this study was to examine the relationship of insulin resistance to glomerular hemodynamics and dietary salt intake in 10 older (68 +/- 6 years), obese (body mass index, 31 +/- 4 kg/m2), mildly hypertensive (151 +/- 8/82 +/- 2 mm Hg), sedentary subjects without clinical evidence of diabetes or renal disease. They were studied on separate days with radioisotopic renal clearances (glomerular filtration rate by 99mTc-diethylenetriaminepentaacetic acid urinary clearance; renal plasma flow by 131I-hippuran serum disappearance) and a two-dose (40 and 100 mU/m2 per minute) hyperinsulinemic euglycemic clamp for measurement of glucose disposal after 2 weeks of a 3-g and 2 weeks of a 10-g sodium diet. Glomerular filtration rate (68.1 +/- 7.7 to 78.0 +/- 6.6 mL/min per 1.73 m2, P = .08) and glomerular filtration fraction (0.21 +/- 0.02 to 0.22 +/- 0.02, P = .5) did not change significantly after dietary salt was increased. During low dietary salt intake, there was an inverse relationship between glomerular filtration fraction and glucose disposal rate (milligrams per kilogram fat-free mass per minute) at both low (r = -.70, P = .04) and high (r = -.83, P = .006) insulin levels. However, these relationships were attenuated during salt loading. This suggests that a greater degree of insulin resistance, not increased dietary salt, may predispose older mildly hypertensive subjects to renal injury by worsening renal hemodynamics through the elevation of glomerular filtration fraction and resultant glomerular hyperfiltration.

High sodium sensitivity implicates nocturnal hypertension in essential hypertension

We investigated the relationship between sodium sensitivity and diurnal variation of blood pressure in patients with essential hypertension. Twenty-eight inpatients with essential hypertension were maintained on high sodium (12 to 15 g NaCl per day) and low sodium (1 to 3 g NaCl per day) diets for 1 week each. Twenty-four-hour blood pressure and urinary sodium excretion were measured at the end of each diet period, and the sodium sensitivity index was calculated as the ratio of the change in mean arterial pressure to the change in urinary sodium excretion rate by sodium restriction. Patients whose average mean arterial pressure was lowered more than 10% by sodium restriction were assigned to the sodium-sensitive group (n = 16); the remaining patients, whose mean arterial pressure was lowered by less than 10%, were assigned to the non-sodium-sensitive group (n = 12). In the non-sodium-sensitive group, mean arterial pressure and heart rate fell during the nighttime, and average values of systolic, diastolic, and mean arterial pressures during the night were significantly lower than those during the day during both low and high sodium diets. On the other hand, in the sodium-sensitive group, there was no nocturnal fall in mean arterial pressure, and none of the systolic, diastolic, and mean arterial pressure values during the nighttime was different from the respective pressure values during the daytime during either sodium diet. The sodium sensitivity index was positively correlated with the fall in mean arterial pressure during the nighttime during a high sodium diet (r = .55, P < .01). These results indicate that in patients with sodium-sensitive essential hypertension, blood pressure fails to fall during the night. High sodium sensitivity may be a marker of greater risk of renal and cardiovascular complications, as has been found in nondippers, patients whose blood pressure fails to fall during the night.

Salt sensitivity of blood pressure in humans

A variety of different techniques have been used for the assessment of the blood pressure response to changes in salt and water balance in humans. These have generally been found to be reproducible and to yield congruent results. This review surveys the characteristics of subjects identified as salt sensitive and salt resistant by different investigators from demographic and physiological perspectives.

Does the renin-angiotensin system determine the renal and systemic hemodynamic response to sodium in patients with essential hypertension?

Many patients with essential hypertension respond to a high dietary sodium intake with a rise in blood pressure. Experimental evidence suggests that the renal hemodynamic response to sodium determines, at least partially, this rise in blood pressure. Our aim was to clarify the role of the renin-angiotensin system in the renal and systemic adaptation to a change in dietary sodium. We studied changes in mean arterial pressure (MAP) (millimeters of mercury), effective renal plasma flow (ERPF), body weight, and immunoreactive renin in 17 patients with essential hypertension and 15 normotensive control subjects, randomly crossing over between a 3-week sodium-restricted (50 mmol/24 h) and a sodium-replete (200 mmol/24 h) diet period. In addition, the effects of renin inhibition by remikiren (600 mg, single oral dose) were studied during the high sodium period. In normotensive control subjects, high sodium intake had no effect on MAP or body weight, whereas ERPF increased (490 +/- 19 to 535 +/- 21 mL/min, P < .05) and immunoreactive renin decreased (32 +/- 6 to 14 +/- 1 pg/mL). In hypertensive subjects, high sodium intake induced a heterogeneous response of MAP (median change, 2.6 mm Hg; range, -4.7 to +21.2; P = NS) and ERPF (median change, 21 mL/min; range, -33 to +98; P = NS). Body weight increased from 81.3 +/- 1.9 to 82.5 +/- 2.0 kg (P < .05), and immunoreactive renin decreased from 18 +/- 3 to 10 +/- 1 pg/mL (P < .05). Interestingly, the patients with a distinct rise in MAP showed a blunted ERPF response to high sodium intake (r = -.70, P < .01) and an increase in body weight (r = .76, P < .001). Moreover, the increase of ERPF was more pronounced in patients with a larger fall in immunoreactive renin (r = .77, P < .001). After administration of remikiren, a heterogeneous response in ERPF was observed: the patients with the blunted ERPF response to high sodium intake showed the largest ERPF rise (r = .70, P < .01). The remikiren-induced rise in ERPF correlated (r = .68, P < .01) with the fall in MAP (114 +/- 2 to 110 +/- 2 mm Hg). In conclusion, in patients with essential hypertension a rise in blood pressure in response to high sodium intake appears to partially be the result of insufficient renal vasodilatation. This seems to be due to an inadequate (intrarenal?) renin-angiotensin system response to increased sodium intake.

Insulin resistance in microalbuminuric hypertension. Sites and mechanisms

Microalbuminuria in patients with essential hypertension is a marker of incipient glomerular dysfunction and clusters with lipid and hemodynamic abnormalities. Recent evidence has shown that hypertensive patients with microalbuminuria have a hyperinsulinemic response to oral glucose, suggesting the presence of insulin resistance. To directly test this possibility we studied insulin action in two accurately matched groups (n = 10 each) of hypertensive patients with or without microalbuminuria (14 +/- 2 versus 52 +/- 7 mg/24 h-1, mean of three 24-hour collections). In response to glucose ingestion microalbuminuric patients showed slight hyperglycemia (area under the curve, 928 +/- 43 versus 784 +/-19 nmol/L-1/2h-1, P < .02) and a marked hyperinsulinemia (26.8 +/- 3.3 versus 49.8 +/- 3.7 nmol/L-1/2h-1, P < 0.01). Basal arterial blood pressure, heart rate, and forearm blood flow were similar in the two groups and did not change significantly during a 2-hour euglycemic insulin clamp. Insulin-stimulated wholebody glucose uptake was 25% lower in microalbuminuric patients (33.5 +/- 2.5 versus 25.2 +/- 2.1 mumol/min-1/kg-1, P < .02). This difference was entirely due to a 40% reduction in glycogen synthesis (12.9 +/- 1.8 versus 21.3 +/- 3.2 mumol/min-1/kg-1, P < .05) as glucose oxidation was similarly stimulated in the two groups. In contrast there was no difference in the ability of insulin to suppress hepatic glucose production (by approximately 100% at the end of the clamp), to decrease fractional sodium and potassium excretions (by 35%), to lower circulating free fatty acids (by 80%), and to reduce plasma potassium concentrations (by 10%).(ABSTRACT TRUNCATED AT 250 WORDS)

Vascular protective effects of ACE inhibitors and calcium antagonists: theoretical basis for a combination therapy in hypertension and other cardiovascular diseases

Hypertension is an important cardiovascular risk factor. High blood pressure per se is not a disease but a hemodynamic alteration associated with vascular disease. Two classes of drugs are especially effective in lowering blood pressure and preventing cardiovascular complications, angiotensin converting enzyme (ACE) inhibitors and calcium antagonists. The hemodynamic effects of ACE inhibitors and calcium antagonists are complementary. While ACE inhibitors inhibit the renin-angiotensin system and reduce sympathetic outflow, calcium antagonists dilate large conduit and resistance arteries. Certain calcium antagonists, such as verapamil, lower heart rate. In the blood vessel wall, the local vascular effects of ACE inhibitors and calcium antagonists are also complementary. While ACE inhibitors inhibit activation of angiotensin I into angiotensin II and prevent the breakdown of bradykinin (which stimulates nitric oxide and prostacyclin formation), calcium antagonists inhibit the effects of vasoconstrictor hormones such as angiotensin II at the level of vascular smooth muscle by reducing calcium inflow and facilitating the vasodilator effects of nitric oxide. Calcium antagonists reduce smooth muscle cell proliferation and atherosclerosis. In hypertensive animals, verapamil and trandolapril normalize endothelial dysfunction. In large angiographic trials, nifedipine and nicardipine reduced the development of new atherosclerotic plaques. After myocardial infarction, verapamil reduces mortality and cardiac events in patients without heart failure. In contrast, ACE inhibitors are effective after myocardial infarction in patients with impaired left ventricular function. Urinary albumin excretion rate decreases during ACE inhibitor therapy or with a calcium antagonist such as verapamil; combination of the two drugs has an additive effect. In resistance arteries, hypertension is associated with an increased media/lumen ratio. ACE inhibitors, but not beta-blockers, markedly improve these structural changes. In summary, ACE inhibitors and calcium antagonists have a complementary profile, both in their hemodynamic and local vascular action. Hence, combination therapy with these two classes of drugs appears particularly useful in patients with hypertension, not only to lower blood pressure, but hopefully to achieve improved cardiovascular protection.

Salt-induced increases in systolic blood pressure affect renal hemodynamics and proteinuria

Nine white and 13 black hypertensive patients with normal serum creatinine were randomized to receive either 2 weeks of a low-salt (40 mEq Na+/d) or high-salt (200 mEq Na+/d) diet followed by 2 weeks of the other diet separated by a 1-week washout on their regular diet. The entire study was conducted in an outpatient setting with intensive dietary instruction and monitoring of blood pressure and 24-hour collections of urine for analysis. Urine electrolyte measurement showed that the patients were able to achieve only a modestly reduced (100 +/- 14 mEq Na+/24 h [mean +/- SEM]) low-salt diet as outpatients, while the higher-salt diet (236 +/- 22 mEq Na+/24 h) was more easily achieved. Eleven patients (8 black, 3 white) were classified as modestly salt sensitive on the basis of an increase or decrease in mean arterial pressure of > or = 3 mm Hg going from lower- to high- or high- to lower-salt diets, respectively. In the salt-sensitive patients, the increase in dietary salt intake increased glomerular filtration rate by 29% (71.2 +/- 6.6 to 85.8 +/- 7.3 mL.min-1.1.73 m2, P = .05), with no significant change in renal plasma flow (412.7 +/- 36.4 to 399.6 +/- 27.8 mL.min-1.1.73 m2). There were no changes in these parameters in the salt-resistant patients.(ABSTRACT TRUNCATED AT 250 WORDS)

Salt sensitivity in hypertension. Renal and cardiovascular implications

The mechanisms responsible for the increase in blood pressure response to high salt intake in salt-sensitive patients with essential hypertension are complex and only partially understood. A complex interaction between neuroendocrine factors and the kidney may underlie the propensity for such patients to retain salt and develop salt-dependent hypertension. The possible role of vasodilator and natriuretic agents, such as the prostaglandins, endothelium-derived relaxing factor, atrial natriuretic factor, and kinin-kallikrein system, requires further investigation. An association between salt sensitivity and a greater propensity to develop renal failure has been described in certain groups of hypertensive patients, such as blacks, the elderly, and those with diabetes mellitus. Salt-sensitive patients with essential hypertension manifest a deranged renal hemodynamic adaptation to a high dietary salt intake. During a low salt diet, salt-sensitive and salt-resistant patients have similar mean arterial pressure, glomerular filtration rate, effective renal plasma flow, and filtration fraction. On the other hand, during a high salt intake glomerular filtration rate does not change in either group, and effective renal blood flow increases in salt-resistant but decreases in salt-sensitive patients; filtration fraction and glomerular capillary pressure decrease in salt-resistant but increase in salt-sensitive patients. Salt-sensitive patients are also more likely than salt-resistant patients to manifest left ventricular hypertrophy, microalbuminuria, and metabolic abnormalities that may predispose them to cardiovascular diseases. In conclusion, salt sensitivity in hypertension is associated with substantial renal, hemodynamic, and metabolic abnormalities that may enhance the risk of cardiovascular and renal morbidity.