Jean-Michel Achard

Fenofibrate Increases Creatininemia by Increasing Metabolic Production of Creatinine

Fenofibrate is a potent hypolipemic agent, widely used in patients with renal insufficiency in whom dyslipidemia is frequent. A moderate reversible increase in creatinine plasma levels is an established side effect of fenofibrate therapy, which mechanism remains unknown. We have previously reported that in 13 patients with normal renal function or moderate renal insufficiency, two weeks of fenofibrate therapy increased creatininemia without any changes in renal plasma flow and glomerular filtration rate [1]. In 13 additional patients, muscular enzymes (AST, GPT, CPK, LDH) and myoglobin were measured before and after 2 weeks on fenofibrate, and the values of creatininemia obtained by the Jaffé technique and HPLC were compared. CPK and AST activity and plasma myoglobin increased in 2 patients with fenofibrate, but muscular enzymes remained unchanged in the population as a whole, and were not correlated to the changes in creatininemia. The changes in creatininemia induced by fenofibrate measured by the Jaffé technique were strongly correlated to those measured by HPLC (r2 = 0.675, p = 0.0006). Analysis of the pooled data of the two arms of the study showed in 26 patients that two weeks of fenofibrate therapy efficiently reduced total cholesterol and triglycerides plasma levels, and raised creatininemia from 139 ± 8 to 160 ± 10 µmol/l (p < 0.0001), but confirmed that creatininuria also increased to the extent that creatinine clearance remained unchanged (68 ± 6 vs. 67 ± 6 ml/min, n.s.). It is concluded that the increase in creatininemia induced by fenofibrate in renal patients does not reflect an impairment of renal function, nor an alteration of tubular creatinine secretion, and is not falsely increased by a dosage interference. Fenofibrate-induced increase of daily creatinine production is neither readily explained by accelerated muscular cell lysis. It is proposed that fenofibrate increases the metabolic production rate of creatinine.

Prevention of dementia by antihypertensive drugs: how AT1-receptor-blockers and dihydropyridines better prevent dementia in hypertensive patients than thiazides and ACE-inhibitors

Our review of cohort studies and clinical trials evaluating antihypertensive drugs in the prevention of cognition decline and all dementia in patients with hypertension indicates that two antihypertensive drug classes have greater protective effects, independent of blood pressure decrease: dihydropyridine calcium-channel blockers as shown in the Syst-Eur trial and angiotensin-AT1 receptor blockers as found in the MOSES and ONTARGET trials. By contrast, diuretics and angiotensin-converting enzyme-inhibitors (ACEIs) prevent dementia only in patients with a stroke history, provided they are combined, and prevent stroke recurrence. A Japanese cohort study and a small trial in patients already suffering from Alzheimer’s disease (AD) suggest, however, that the BBB-penetrating ACEI may slow down cognitive decline. Only cohort studies support the hypothesis that diuretics, (especially potassium-sparing diuretics), may decrease the risk of AD. β-blockers worsen cognition decline, or are neutral, according to whether or not they cross the BBB. Centrally-acting sympatholytic agent have a negative impact on cognition as BBB-penetrating β-blockers, probably by blunting the adrenergic pathways. The AD protective effect of DHP appears related to the blockade of neuronal calcium channels. The ambiguous effect of ACEI on cognitive decline and dementia prevention may be explained by the fact that brain ACE is not specific for angiotensin-I. Brain ACE also catabolizes cognition-enhancing brain peptides, amyloid peptides and converts toxic Aβ42 into less toxic Aβ40. Therefore, ACEIs may have short-term cognition-enhancing properties and may increase in the long term Aβ42 brain burden and cognitive decline. The clinical relevance of this scenario, mainly observed in animals, cannot be excluded in man, since the ACE gene has been associated with AD via the human whole genome analysis. To support the hypothesized deleterious effect of ACEI on human AD, confirmation that the ACE gene polymorphism DD is associated with protection against AD is necessary, since this polymorphism increases ACE activity. Independently of their preventive impact on β-amyloid degenerative neuropathological process by overexpressing insulin degrading enzyme which catabolyses amyloid, the angiotensin AT1-receptor-blockers may have greater cognition protective effects than ACEI (observed in the ONTARGET trial), as they share with ACEI cognition-enhancing effects directly linked with a common AT1-blunting effect. In addition, they increase angiotensin II and IV formation and therefore stimulate non-opposed AT2 and AT4 receptors, whose activation in cognitive processes is well established.

A New Locus on Chromosome 12p13.3 for Pseudohypoaldosteronism Type II, an Autosomal Dominant Form of Hypertension

Pseudohypoaldosteronism type II (PHA2) is a rare autosomal dominant form of volume-dependent low-renin hypertension characterized by hyperkalemia and hyperchloremic acidosis but also by a normal glomerular filtration rate. These features, together with the correction of blood pressure and metabolic abnormalities by small doses of thiazide diuretics, suggest a primary renal tubular defect. Two loci have previously been mapped at low resolution to chromosome 1q31-42 (PHA2A) and 17p11-q21 (PHA2B). We have now analyzed a new, large French pedigree, in which 12 affected members over three generations confirmed the autosomal dominant inheritance. Affected subjects had hypertension together with long-term hyperkalemia (range 5.2-6.2 mmol/liter), hyperchloremia (range: 100-109 mmol/liter), normal plasma creatinine (range: 63-129 mmol/liter) and low renin levels. Genetic linkage was excluded for both PHA2A and PHA2B loci (all LOD scores Z<-3.2 at recombination fraction [theta] 0), as well as for the thiazide-sensitive sodium-chloride cotransporter gene. A genome-wide scan using 383 microsatellite markers showed a strong linkage with the chromosome 12p13 region (maximum LOD score Z=6.18, straight theta=0, at D12S99). Haplotype analysis using 10 additional polymorphic markers led to a minimum 13-cM interval flanked by D12S1652 and D12S336, thus defining a new PHA2C locus. Analysis of two obvious candidate genes (SCNN1A and GNb3) located within the interval showed no deleterious mutation. In conclusion, we hereby demonstrate further genetic heterogeneity of this Mendelian form of hypertension and identify a new PHA2C locus, the most compelling and precise linkage interval described to date.

Familial Hyperkalemic Hypertension

Familial hyperkalemic hypertension (FHHt) syndrome ([1][1],[2][2]), also known as Gordon syndrome ([3][3]) or pseudohypoaldosteronism type 2 ([4][4]), is a rare inherited form of low-renin hypertension associated with hyperkalemia and hyperchloremic metabolic acidosis in patients with a normal GFR (

WNK1 Regulates Vasoconstriction and Blood Pressure Response to α 1 -Adrenergic Stimulation in Mice

Gain-of-function mutations in the human WNK1 (with-no-lysine[K]1) gene are responsible for a monogenic form of arterial hypertension, and WNK1 polymorphisms have been associated with common essential hypertension. The role of WNK1 in renal ionic reabsorption has been established, but no investigation of its possible influence on vascular tone, an essential determinant of blood pressure, has been performed until now. WNK1 complete inactivation in the mouse is embryonically lethal. We, thus, examined in Wnk1+/− haploinsufficient adult mice whether WNK1 could regulate in vivo vascular tone and whether this was correlated with blood pressure variation. Wnk1+/− mice displayed a pronounced decrease in blood pressure responses in vivo and in vascular contractions ex vivo following &agr;1-adrenergic receptor activation with no change in basal blood pressure and renal function. We also observed a major loss of the pressure-induced contractile (myogenic) response in Wnk1+/− arteries associated with a specific alteration of the smooth muscle cell contractile function. These alterations in vascular tone were associated with a decreased phosphorylation level of the WNK1 substrate SPAK (STE20/SPS1-related proline/alanine-rich kinase) and its target NKCC1 (Na+-K+-2Cl− cotransporter 1) in Wnk1+/− arteries. Our study identifies a novel and major role for WNK1 in maintaining in vivo blood pressure and vasoconstriction responses specific to &agr;1-adrenergic receptor activation. Our findings uncover a vascular signaling pathway linking &agr;1-adrenergic receptors and pressure to WNK1, SPAK, and NKCC1 and may, thus, significantly broaden the comprehension of the regulatory mechanisms of vascular tone in arterial hypertension.

Protection against ischemia: a physiological function of the renin-angiotensin system.

The renin-angiotensin system (RAS) is involved in a complex mechanism that serves to preserve the blood supply to organs so that they can maintain cellular function. Angiotensin II exerts this effect, independently of the blood pressure generated, through two time-related events: a fast opening of the reserve collateral circulation and a much slower response of new vessel formation or angiogenesis. This effect is observed in rats with ligation of the abdominal aorta and in gerbils with abrupt or progressive unilateral carotid artery ligation. Inhibition of the angiotensin-converting enzyme (ACE) or the angiotensin II receptor represses this effect, and it appears that it is mediated through a non-AT1 receptor site of angiotensin II. Many tumors, both benign and malignant, express renin and angiotensin. It seems that the stimulating action of angiotensin II on angiogenesis could also be involved in preserving the blood supply to tumor cells. Administration of converting enzyme inhibitors increases survival and decreases tumor size in tumor-bearing rats. These observations support the hypothesis that the RAS, directly or indirectly, is involved in situations in which the restoration of blood supply is critical for the viability of cells and that it is present not only in normal but also in pathological conditions such as tumors. In view of the ubiquitous presence of renins and angiotensins, it is also likely to be involved in other conditions, such as inflammation, arthritis, diabetic retinopathy, and retrolental fibroplasia, among others in which angiogenesis is prominent. In addition, angiotensin II could be involved, through the counterbalance of the AT1 and AT2 receptors, in the rarefaction of blood vessels as an etiologic component of essential hypertension.

Synergistic protective effects of erythropoietin and olmesartan on ischemic stroke survival and post-stroke memory dysfunctions in the gerbil.

Objectives Treatment with erythropoietin and AT1 blockers is protective in experimental acute cerebral ischemia, with promising results in pilot clinical studies in human stroke. This paper examines the effects of using both agents as combination therapy in acute ischemic stroke. Methods We used the single carotid ligation stroke model in the gerbil. Six groups of 50 gerbils were treated either with placebo, erythropoietin (intraperitoneally, 5000 IU/kg, 2 and 48 h after stroke), olmesartan (10 mg/kg per day in drinking water started 36 h after stroke), ramipril (2.5 mg/kg per day in drinking water started 36 h after stroke), erythropoietin + olmesartan, or erythropoietin + ramipril. Long-term (1 month) Kaplan–Meyer survival curves were obtained, and survivors were submitted at day 30 to immediate (object recognition test) and spatial (Morris water maze) memory function tests. Results Erythropoietin alone and olmesartan alone, but not ramipril, significantly increased survival at day 30 compared with untreated controls (38, 30 and 6% versus 12%, respectively). Combined treatment with erythropoietin and olmesartan further increased the survival rate to 56%, whereas combined therapy with erythropoietin and ramipril decreased 30-day survival to 24% (P < 0.0001, erythropoietin + olmesartan versus erythropoietin + ramipril). Untreated stroke survivors had markedly altered performances in both the object recognition test (P = 0.0007) and the Morris water maze (P < 0.0001) tests at day 30 compared with normal gerbils. In erythropoietin-treated animals, ramipril therapy had no beneficial effect whereas olmesartan fully restored normal response to the memory tests. Conclusion Post-infarct treatment with olmesartan combined with early erythropoietin therapy has a protective effect on survival, and markedly improves long-term memory dysfunction in this experimental model.

Control of Predialytic Hyperphosphatemia by Oral Calcium Acetate and Calcium Carbonate

Since Mai et al. found, with the intestinal lavage technique, that the same dose of elemental calcium given as acetate (Ca Ac) complexed in the gut of uremic patients twice as much phosphate as calcium carbonate (CaCO3) while inducing a rather low calcium absorption, we wanted to see if half the dose of elemental calcium given as Ca Ac could control, on medium term, the predialysis plasma phosphate as well as CaCO3 while inducing less frequent hypercalcemia. This was evaluated in a cross-over study of 3 periods of 10 weeks according to the sequence Ca Ac, CaCO3 and Ca Ac, in 12 compliant patients on chronic dialysis previously treated by CaCO3. Because of poor tolerance of Ca Ac during the first period, 4 patients were excluded and the results were assessed only on the 8 patients who completed the study. For half the doses of elemental calcium (620 +/- 250 mg versus 1,310 +/- 560 mg versus 710 +/- 200 mg/day), Ca Ac allowed the same control of predialytic hyperphosphatemia (1.67 +/- 0.34; 1.74 +/- 0.32; 1.75 +/- 0.38) with paradoxically comparable normal mean plasma calcium concentration (2.61 +/- 0.14; 2.56 +/- 0.13; 2.55 +/- 0.14 mmol/l). Plasma alkaline phosphatases and intact PTH concentrations remained also stable during the 3 periods. The frequency of hypercalcemia greater than 2.75 mmol/l (12; 9; 20%) and of hyperphosphatemia greater than 2 mmol/l (17; 22; 27%) were comparable with the 2 treatments. In conclusion, Ca Ac controls predialytic hyperphosphatemia as efficiently as CaCO3 for half the dose of elemental calcium without, however, decreasing the frequency of hypercalcemia.(ABSTRACT TRUNCATED AT 250 WORDS)

PATHOPHYSIOLOGY AND TREATMENT OF IDIOPATHIC HYPERCALCIURIA

Nearly 50 years after its initial description by Dr. F. Albright, the term idiopathic hypercalciuria (IH) is still in use. The exact mechanism of hypercalciuria is still unknown despite extensive pathophysiologic investigations; recent advances represent the focus of this review. A precise definition of true IH is proposed, taking into account the various nutritional conditions influencing calcium excretion. The potential pathogenic mechanisms are discussed, and the limits of the classical Paks pathophysiological classification are recalled. The evidence supporting the role of an increased intestinal calcium absorption, a defect in renal tubular calcium reabsorption, or an increased bone loss as a primary mechanism in IH are successively examined. Since overall available human data indicates that all three mechanisms may be found in IH, the hypothesis that a broader disorder encompassing all these various abnormalities may be involved in IH is discussed. Three global hypotheses to account for IH physiopathology are examined: a diffuse defect in fatty acid content of cell membranes, an increased expression of the vitamin D receptor of the 25(OH) vitamin D 1 alpha-hydroxylase, or of the calcium sensor receptor and a monocyte disease. Finally, the available clinical data justifying the therapeutic approaches are reviewed, and guidelines for dietary recommendations regarding calcium and also animal protein, sodium chloride, alcohol, carbohydrate, phosphate, and potassium intakes are proposed, and drug therapy indications are discussed.

The renin-angiotensin systems: evolving pharmacological perspectives for cerebroprotection.

During the last 20 years, the renin-angiotensin system (RAS) has become an increasingly important focus of basic and clinical cardiovascular research. One main conceptual step forward was made with the discovery of a tissue RAS and the understanding of its critical pathophysiological role in atherogenesis and plaque destabilisation. Major effort to find new strategies for blocking the RAS has produced new classes of drugs which were expected to be clinically important in the management of hypertension and heart failure. As landmark clinical studies have demonstrated that inhibition of the RAS significantly reduces morbidity and mortality from coronary heart disease, myocardial infarction and heart failure, the concept has rapidly emerged that blocking the RAS was the strategy of choice for preventing cardiovascular diseases. More recently, basic research has however continuously extended our understanding of the complexity of the systemic and tissue RASs, that can no longer be viewed as one-way streets in which one single effector, angiotensin II acts solely through its major (AT1) receptor. Meanwhile, clinical trials have challenged the concept that blocking the RAS is the most effective preventive strategy for all patients and all target organs. Consistent with the recent understanding that the RAS encompasses a number of distinct effectors acting through different receptors to promote opposite effects, a growing body of basic and clinical evidence suggests that blunting the RAS is a double-edge sword, with beneficial effects counterbalanced by deleterious ones, resulting in a net effect that critically depends on the experimental conditions, or the clinical characteristics of the study population. Of particular clinical relevance, a number of clinical trials point to the somewhat provocative conclusion that beyond their blood pressure lowering effect antihypertensive drugs that decrease angiotensin II formation are less stroke protective than the ones that increase angiotensin levels. This review focuses on the recent experimental evidence demonstrating that angiotensin II and its derivatives acting through the non-AT1 receptors are involved in protective mechanisms against cerebral ischaemia and discusses in the light of the recent large cardiovascular prevention trials the clinical relevance of this new concept. The perspective of a renewal of therapeutical strategies to optimise the prevention of target organ damage and perhaps even some of the diseases of ageing, such as loss of cognitive function is emphasised.