Effect of antihypertensive treatment on kidney function in diabetic nephropathy.

The effect of long term, aggressive antihypertensive treatment on kidney function in diabetic nephropathy was studied prospectively in 11 insulin dependent diabetics (mean age 30). During the mean pretreatment period of 32 (range 23-66) months the glomerular filtration rate decreased significantly and albuminuria and the arterial blood pressure increased significantly. During the 72 (range 32-91) month period of antihypertensive treatment the average arterial blood pressure fell from 143/96 mm Hg to 129/84 mm Hg and albuminuria decreased from 1038 micrograms/min to 504 micrograms/min. The rate of decline in the glomerular filtration rate decreased from 0.89 (range 0.44-1.46) ml/min/month before treatment to 0.22 (range 0.01-0.40) ml/min/month during treatment. The rate of decline in the glomerular filtration rate was significantly smaller during the second three years compared with the first three years in patients who received long term antihypertensive treatment (greater than or equal to 6 years). One patient died from acute myocardial infarction (glomerular filtration rate 46 ml/min/1.74 m2). Effective antihypertensive treatment postpones renal insufficiency in diabetic nephropathy.     

Effect of adrenergic blockade with bretylium and phentolamine on glomerular filtration rate in the rainbow trout, Salmo gairdneri Rich., adapting to saline water

In resting conscious trout, Salmo gairdneri, a gradual increase in external salinity (brackish water) resulted in an immediate decline of glomerular filtration rate and urine flow. These renal responses were partly blocked by the administration of bretylium and phentolamine. The presence of adrenergic nerve endings in the trout kidney and these pharmacological results together provide evidence of neural control of renal haemodynamics. The action of vasoactive substances and innervation is discussed briefly in relation to their importance for normal renal function.     

Effect of felodipine on renal hemodynamics and excretion in the dog

The effects of felodipine on renal hemodynamics and excretion were evaluated in the anesthetized dog. Unilateral renal arterial infusion of felodipine produced ipsilateral increases in the absolute and fractional excretion of sodium and water which were greater than those of potassium; these effects occurred in the absence of changes in mean arterial pressure, renal blood flow, or glomerular filtration rate. There were no significant effects on renal hemodynamic or excretory function in the contralateral kidney. The unilateral renal arterial infusion of isotonic saline or vehicle produced no significant effects on renal hemodynamic or excretory function in either ipsilateral or contralateral kidney. Felodipine, a calcium antagonist with vasodilator antihypertensive properties, in doses which do not affect systemic or renal hemodynamics in the dog, increased urinary flow rate and sodium excretion by decreasing renal tubular water and sodium reabsorption. As a vasodilator antihypertensive agent, felodipine possesses potentially advantageous diuretic and natriuretic properties.     

Effects of acetaminophen and ibuprofen on renal function in anesthetized normal and sodium-depleted dogs

In certain conditions, renal prostaglandins (PGs) are importantdeterminants of kidney function. Under these "renal PG-dependent states," pharmacological inhibition of vasodilatory PG may result inexcessive renal vasoconstriction and adversely affect kidney function.The purposes of this study were to determine whether acetaminophen(Acet), a weak PG-synthesis inhibitor, influences kidney function inthe renal PG-dependent state of anesthesia and sodium depletion.Comparisons were made with ibuprofen (Ibu). Measurements ofPGE₂ excretion were used to assessrenal PG synthesis. Acet (15 mg/kg) and Ibu (10 mg/kg) both decreasedrenal blood flow and glomerular filtration rate by ~20-30% innormal, anesthetized, sodium-replete dogs. Although Acet producedsimilar changes in renal blood flow and glomerular filtration rate inthe low-sodium dogs, Ibu caused a significantly greater renalvasoconstriction (64 ± 10%) in these animals. Both Acet and Ibuinhibited urinary PGE₂ excretionin sodium-replete and low-sodium dogs. Ibu tended to have a greater andmore prolonged effect than did Acet. These results suggest that Acetalters PGE₂ excretion and kidneyfunction under renal PG-dependent conditions; the effects, however, are less severe than those seen with Ibu.     

Early renal hemodynamic modifications following the ablation of the controlateral kidney]

Instantaneous measurements of renal blood flow (RBF) and glomerular filtration rate (GFR) have been performed in anesthetized dogs to determine if removal of one kidney induces early functional adaptation in the remaining kidney. Increases in RBF (10%) and GFR (20%) were observed within the first minutes after exclusion of controlateral kidney; these are the earliest events described until now. These observations favour the concept that a functional adjustement may contribute to development of compensatory renal hypertrophy.     

Long-term antihypertensive treatment inhibiting progression of diabetic nephropathy

Six men aged 26-35 years with proteinuria due to insulindependent juvenile-onset diabetes were treated for moderate hypertension (mean blood pressure 162/103 mm Hg) and studied for a mean of 73 months for the effect on the progression of nephropathy. All patients were of normal weight. During a mean control period of 28 months before treatment the mean glomerular filtration rate (three or four measurements) was 86·1 ml/min and mean 24-hour urinary albumin excretion (also three or four measurements) 3·9 g (range 0·5-8·8 g).During antihypertensive treatment the mean systolic blood pressure fell to 144 mm Hg and mean diastolic pressure to 95 mm Hg. In the control period five patients had shown a mean monthly decline in glomerular filtration rate of 1·23 ml/min; with antihypertensive treatment, however, this decline fell to 0·49 ml/min (2p=0·042). In the remaining patient the glomerular filtration rate was 137 ml/min before treatment and 135 ml/min at the end of the treatment period. In all patients the mean yearly increase in albumin clearance (expressed as a percentage of the glomerular filtration rate) fell from 107% before treatment to 5% during treatment (2p=0·0099).This small study indicates that antihypertensive treatment slows the decline in renal function in diabetic nephropathy. Clinical trials beginning treatment in the incipient phase of diabetic nephropathy will define the optimal modality of treatment in this large patient population.     

Cyclooxygenase-2 and kidney failure

Cyclooxygenase (COX)-dependent prostaglandins are necessary for normal kidney function. These prostaglandins are associated with inflammation, maintenance of sodium and water homeostasis, control of renin release, renal vasodilation, vasoconstriction attenuation, and prenatal renal development. COX-2 expression is regulated by the renin-angiotensin system, glucocorticoids or mineralcorticoids, and aldosterone, supporting a role for COX-2 in kidney function. Indeed, COX-2 mRNA and protein levels as well as enzyme activity are increased, along with PGE2, during kidney failure. In addition, changes in COX-2 expression are associated with increased blood pressure, urinary volume, sodium and protein and decreased urinary osmolarity. Intrarenal mechanisms such as angiotensin II (Ang II) production, increased sodium delivery, glomerular hypertension, and renal tubular inflammation have been suggested to be responsible for the increase in COX-2 expression. Although, specific COX-2 pharmacological inhibition has been related to the prevention of kidney damage, clinical studies have reported that COX-2 inhibition may cause side effects such as edema or a modest elevation in blood pressure and could possibly interfere with antihypertensive drugs and increase the risk of cardiovascular complications. Thus, administration of COX-2 inhibitors requires caution, especially in the presence of underlying cardiovascular disease.     

The effects of clonidine on the kidney function in the anesthetized dog

Studies were performed to determine the mechanism by which the antihypertensive agent clonidine increased urine flow. The response of the kidney has been examined in four combinations. The parameters of renal function have been compared during volume expansion by 1.5-2.0% body weight Ringer solution. In the control animals, volume expansion by 2% body weight, resulted in a slight increase in sodium excretion and urine flow. In 10 anesthetized dogs 1.0 microgram/kg/min of clonidine infused i.v. during 30 minutes (the total amount of clonidine infused was 30 micrograms/kg) decreased the arterial blood pressure from 136 +/- 13 mmHg to 127 +/- 12 mmHg and elevated urine flow from 2.95 +/- 1.65 ml/min to 4.34 +/- 1.77 ml/min while the urine osmolality diminished from 399 +/- 107 mosm/l to 265 +/- 90 mosm/l and the glomerular filtration remained constant. In 5 animals 0.1 microgram/kg/min of clonidine was infused into the left renal artery (this dose is corresponding to the renal fraction of the cardiac output) without any effects in the left kidney. 1.0 microgram/kg/min of clonidine infused directly into the left renal artery produced vasoconstriction in the ipsilateral kidney, decreased the glomerular filtration rate and the urine flow. By contrast in the right kidney the urine flow rose without hemodynamic changes, and the urine osmolality became hypoosmotic compared to the plasma. In ten dogs 1.0 microgram/kg/min of clonidine and 1 mU/kg/min of arginine-vasopressin were infused intravenously. The vasopressin infusion superimposed on the clonidine could not inhibit the increase of the urine excretion, and the fall of the urine osmolality. The results suggest that the clonidine increases the renal medullary blood flow possibly via a direct mechanism, decreases the sympathetic outflow to the kidney and via an indirect pathway, mediated by the renin-angiotensin system. The renal medullary flow increase produces a washout of the medullary osmotic gradient, and the water reabsorption diminishes.     

Specificity of neural effect on renal tubular sodium reabsorption.

Low level direct renal nerve stimulation increases renal tubular sodium reabsorption in the absence of changes in glomerular filtration rate, renal blood flow, or intrarenal distribution of blood flow. Blockade of this response with phenoxybenzamine (or guanethidine) supports the interpretation that it is mediated by direct adrenergic innervation of the renal tubule.     

Renal effects of atrial natriuretic factor in domestic fowl

The renal hemodynamic and tubular effects of ANF were investigated using the Sperber technique in chickens. This technique takes advantage of the unique portal circulation of the avian kidney and permits direct access to the renal peritubular space independent of renal arterial blood flow and glomerular filtration. Infusion of ANF into the avian renal portal system increased urine flow rate and sodium excretion by as much as 300% and 100%, respectively. These changes occurred in the absence of significant alterations in glomerular filtration rate or renal plasma flow. There was no significant difference in urine flow, sodium excretion or glomerular filtration rate between the ANF-infused kidney and the contralateral, non-infused kidney. We conclude that the diuretic and natriuretic effects of ANF do not depend on changes in glomerular filtration rate and that the site of action of ANF is the renal medulla.     

Glomerular hyperfiltration in hypertensive fawn-hooded rats

The glomerular filtration rate (GFR), effective renal plasma flow (ERPF), systolic blood pressure (SBP) and urinary protein excretion (UpV) were determined in 12-week-old male rats of the spontaneously hypertensive Fawn-Hooded (FH) strain. These data were compared with those of either age-matched or weight-matched male, normotensive Wistar Albino Glaxo (WAG) rats. The GFR was significantly higher in FH rats than in both WAG control groups. In contrast, the ERPF did not differ between the FH and WAG rats. Thus, a higher filtration fraction was present in the FH rats. As no differences were found in the total number of glomeruli per kidney comparing FH and WAG rats, the high GFR was not due to an increase in the number of glomeruli. The SBP and the UpV were significantly higher in FH rats than in WAG rats. To our opinion, the arterial hypertension associated with glomerular hyperfiltration proteinuria suggests the presence of glomerular hypertension in FH rats.     

Age and renal prostaglandin inhibition during exercise and heat stress.

Aging is associated with a number of physiological changes that may cause the kidney to rely to a greater extent on vasodilatory PGs for normal functioning. Acute exercise has been shown to cause renal vasoconstriction that may be partially buffered by vasodilatory PGs. To determine the relative importance of renal PGs during exercise in older adults, we compared the renal effects of the PG inhibitor ibuprofen (1.2 g/day for 3 days) vs. a placebo control in a cohort of eight younger (24 +/- 2 yr) and eight older (64 +/- 2 yr) women during treadmill exercise ( approximately 57% maximal oxygen consumption) in the heat (36 degrees C). This over-the-counter dose of ibuprofen reduced renal PG (i.e., PGE2) excretion by 47% (P < 0. 05). Acute exercise in the heat caused dramatic decreases in glomerular filtration rate, renal blood flow, and sodium excretion in both age groups. PG inhibition was associated with greater decreases in urine production and free water clearance (P < 0.05). There were no drug-related declines in glomerular filtration rate or renal blood flow. We conclude that PG inhibition has only modest effects on renal function during exercise. Also, the lack of hemodynamic changes with PG inhibition indicates that healthy well-hydrated older women are not in a renal PG-dependent state.     

Dose effect of captopril on renal hemodynamics and proteinuria in conscious, partially nephrectomized rats

The effect of varying doses of captopril, an angiotensin I-converting enzyme inhibitor, on renal hemodynamics, systemic arterial pressure, and the progression of chronic renal disease in conscious, three-quarter nephrectomized adult male Sprague-Dawley rats was studied. Six weeks following nephrectomy (Week 0), rats were randomly divided into five groups. Group 2 (n = 8), 3 (n = 8), 4 (n = 9), and 5 (n = 5) were given 5, 10, 20, and 40 mg/kg captopril, respectively, daily in drinking water. Group 1 (n = 7) and sham-operated controls (n = 7) were given water only. On Weeks -6, 0, 2, and 4, renal function was assessed by 24-hr urinary protein excretion and plasma creatinine. Systolic blood pressure was measured at these times by the tail cuff method. Following Week 4, glomerular filtration rate and effective renal plasma flow were measured in conscious rats by single injection clearance of [3H]inulin and [14C]tetraethylammonium bromide, respectively. Group 1 had significantly higher (P less than 0.05) 24-h urinary protein excretion, plasma creatinine, and systolic pressure compared with Group 5 and controls by Week 4, whereas values for these parameters for Groups 2-4 ranged between these extremes. Although systolic pressures were not significantly different (P greater than 0.05), Group 2 had significantly lower proteinuria than Group 1 (P less than 0.05) at Week 4. Total kidney glomerular filtration rate was similarly decreased in Groups 1-5 compared with control rats. Total kidney effective renal plasma flow was higher in captopril-treated groups than in Group 1, whereas systolic blood pressure was similar or lower, indicating that captopril reduced renal vascular resistance. Furthermore, unlike Groups 1-3, the groups receiving higher doses of captopril (4 and 5) did not develop anemia associated with chronic renal disease. In conclusion, captopril attenuated renal functional deterioration in a dose-related manner. The effect on proteinuria was evident at low doses of captopril which did not significantly reduce systemic blood pressure and was accompanied by an increase in effective renal plasma flow and a decrease in renal vascular resistance.     

Serum hippurate and its excretion in conservatively treated and dialysed patients with chronic renal failure.

54 healthy volunteers or patients with normal kidney and liver function, 17 patients with decreased kidney function and 12 dialysed patients were evaluated for their serum hippurate accumulation and kidney excretion. It was found that there was an inverse relationship between serum hippurate and the clearance of endogenous creatinine (CCr) and a free relationship between fractional excretion of hippurate and CCr. The excretory capacity in residual nephrons was increased. This was caused by the greater glomerular filtration load which increased up to 25 times and tubular secretion which increased 7 times in dialysed patients. The relative contribution of glomerular filtration to hippurate excretion rose from about 20% in controls to almost 50% in dialysed patients. True kidney adaptation was localized in the organic anion transport system of proximal tubules.     

Loxosceles gaucho venom-induced acute kidney injury--in vivo and in vitro studies

Background

Accidents caused by Loxosceles spider may cause severe systemic reactions, including acute kidney injury (AKI). There are few experimental studies assessing Loxosceles venom effects on kidney function in vivo.

Methodology/Principal Findings

In order to test Loxosceles gaucho venom (LV) nephrotoxicity and to assess some of the possible mechanisms of renal injury, rats were studied up to 60 minutes after LV 0.24 mg/kg or saline IV injection (control). LV caused a sharp and significant drop in glomerular filtration rate, renal blood flow and urinary output and increased renal vascular resistance, without changing blood pressure. Venom infusion increased significantly serum creatine kinase and aspartate aminotransferase. In the LV group renal histology analysis found acute epithelial tubular cells degenerative changes, presence of cell debris and detached epithelial cells in tubular lumen without glomerular or vascular changes. Immunohistochemistry disclosed renal deposition of myoglobin and hemoglobin. LV did not cause injury to a suspension of fresh proximal tubules isolated from rats.

Conclusions/Significance

Loxosceles gaucho venom injection caused early AKI, which occurred without blood pressure variation. Changes in glomerular function occurred likely due to renal vasoconstriction and rhabdomyolysis. Direct nephrotoxicity could not be demonstrated in vitro. The development of a consistent model of Loxosceles venom-induced AKI and a better understanding of the mechanisms involved in the renal injury may allow more efficient ways to prevent or attenuate the systemic injury after Loxosceles bite.     

Telmisartan in the treatment of hypertension in patients with chronic renal insufficiency

The primary aim of this study was evaluation of the efficacy of telmisartan (angiotensin II receptor blocker- AT(1) blocker) on blood pressure in 10 patients with renal impairment in moderate or advanced stages of renal insufficiency and not dependent on haemodialysis. Its effect on proteinuria, renal function (represented by serum urea, creatinine, glomerular filtration), evaluation of overall therapy compliance in comparison with a previously prescribed angiotensin converting enzyme inhibitors (ACEI) were secondary aims. Considering the presence of left ventricle hypertrophy in all patients as a marker of hypertensive cardiopathy, the effect of telmisartan therapy on non-invasive cardiovascular parameters (ECG, echocardiography, and assessment of heart rate variability-HRV) was also evaluated. The study group involved 10 hypertensive patients (6 women, 4 men) with diabetic and non-diabetic renal impairment, proteinuria above 1 g/24 hours, hypertensive cardiopathy and intolerance of ACEI (cough). Telmisartan was added to their long-term antihypertensive combination therapy in a dose of 40 mg for the first 14 days, after which the dose increased to the maximal of 80 mg. The average initial daytime systolic blood pressure (SBP) was 149 +/- 19.7 mm Hg, average night-time SBP 145 +/- 23.0 mm Hg, average initial daytime diastolic BP (DBP) 90.6 +/- 2.5 mm Hg, night-time DBP 88.9 +/- 13.5 mm Hg. Average initial serum creatinine was 207.2 +/- 48.5 micromol/l, urea 15.1 +/- 4.4 mmol/l, GF 0.5 +/- 0.1 ml/s. Echocardiography revealed left ventricular (LV) hypertrophy with well preserved systolic and moderately impaired diastolic LV function. Also the HRV assessment revealed impaired neurovegetative (e.g. sympathovagal) balance. After 1 year of combination therapy with telmisartan, there was a clearly significant reduction in both SBP and DBP in both day and night-time (SBP daytime 149.6 vs.116.6 mm Hg, night-time 145.8 vs. 129.5 mm Hg; DBP daytime 90.6 vs. 83.5 mm Hg, night-time 88.9 vs. 79.3 mm Hg) and proteinuria (2.37 vs. 1.27 g/24 hour, p < 0.05). There were no significant changes in serum creatinine, urea values, and LV functions. On the other hand, further progression of the sympathovagal balance impairment was noted (continuing reduction of HRV in 9 from 10 patients), which can be described as the priority finding. The total compliance of telmisartan therapy was very good and without adverse clinical side effects. In conclusion - telmisartan reduces blood pressure and proteinuria safely and effectively in patients with various types of nephropathy in moderate or advanced stages of renal insufficiency.     

Diet and kidney disease: the role of dietary fatty acids

Several general principles with respect to the role of the fatty acids in the progression of kidney disease have begun to emerge from the mass of observational detail. Interventions that increase renal exposure to prostaglandins of the E series appear to be beneficial. They include administration of prostaglandin analogues and dietary supplementation with their fatty acid precursor, linoleate. The beneficial effects may be attributed to preservation of renal blood flow and glomerular filtration, reduction in blood pressure, direct effects on the lipid composition and function of cell membranes, and immune suppression. Interventions that inhibit thromboxane and leukotriene production, such as omega-3 fatty acid supplementation of the diet or administration of enzyme or receptor inhibitors, are also protective. Prevention of vasoconstriction, inhibition of platelet activation, and regulation of cell proliferation and matrix production have all been implicated in the mediation of the observed retardation of sclerosis. Fish oil may have synergistic, suppressive effects on various parameters of immune activation. Essential fatty acid deficiency, of course, inhibits both prostaglandin E and thromboxane production, cancelling out the protective and injurious components of arachidonate oxidation. Yet, studies on its beneficial effects have revealed another aspect of eicosanoid metabolism, independent of cyclooxygenase and lipoxygenase activity, that appears to regulate monocyte migration into injured tissue. Dietary interruption of this pathway has proven protective to renal structure and function. Alterations in lipid metabolism may represent a common, mediating pathway of glomerular and interstitial susceptibility to progressive sclerosis in the kidney. The process appears to be amenable to manipulation by pharmacologic or dietary modulation of fatty acid metabolism. Eicosanoid metabolites and tissue-leukocyte signaling are two mechanisms by which lipid alterations can affect renal function. There are doubtless many others awaiting elucidation. Delineation of all the mechanisms whereby fatty acid metabolism can contribute to progressive kidney injury may provide a useful model for the examination of progressive sclerosis affecting other tissues subsequent to immune, vascular, or metabolic injury.     

Diuretic treatment of resistant hypertension.

In patients with hypertension resistant to three or four drugs including a thiazide diuretic substitution of frusemide for the thiazide, or the addition of spironolactone, produced significant reductions in blood pressure and body weight. The response did not depend on the presence of overt fluid retention, renal impairment, or the use of antihypertensive drugs of high potency. Women had larger responses than men. Expansion of the plasma or extracellular fluid volume is an important cause of resistance to treatment even when a thiazide diuretic is used. An increase in diuretic treatment should be tried before using the postganglionic adrenergic blockers or minoxidil in resistant hypertension.     

Control and Modulation of Fluid Flow in the Rat Kidney

We have developed a mathematical model of the rat’s renal hemodynamics in the nephron level, and used that model to study flow control and signal transduction in the rat kidney. The model represents an afferent arteriole, glomerular filtration, and a segment of a short-loop nephron. The model afferent arteriole is myogenically active and represents smooth muscle membrane potential and electrical coupling. The myogenic mechanism is based on the assumption that the activity of nonselective cation channels is shifted by changes in transmural pressure, such that elevation in pressure induces vasoconstriction, which increases resistance to blood flow. From the afferent arteriole’s fluid delivery output, glomerular filtration rate is computed, based on conservation of plasma and plasma protein. Chloride concentration is then computed along the renal tubule based on solute conservation that represents water reabsorption along the proximal tubule and the water-permeable segment of the descending limb, and chloride fluxes driven by passive diffusion and active transport. The model’s autoregulatory response is predicted to maintain stable renal blood flow within a physiologic range of blood pressure values. Power spectra associated with time series predicted by the model reveal a prominent fundamental peak at ～165 mHz arising from the afferent arteriole’s spontaneous vasomotion. Periodic external forcings interact with vasomotion to introduce heterodynes into the power spectra, significantly increasing their complexity.     

Renal autoregulation: new perspectives regarding the protective and regulatory roles of the underlying mechanisms

When the kidney is subjected to acute increases in blood pressure (BP), renal blood flow (RBF) and glomerular filtration rate (GFR) are observed to remain relatively constant. Two mechanisms, tubuloglomerular feedback (TGF) and the myogenic response, are thought to act in concert to achieve a precise moment-by-moment regulation of GFR and distal salt delivery. The current view is that this mechanism insulates renal excretory function from fluctuations in BP. Indeed, the concept that renal autoregulation is necessary for normal renal function and volume homeostasis has long been a cornerstone of renal physiology. This article presents a very different view, at least regarding the myogenic component of this response. We suggest that its primary purpose is to protect the kidney against the damaging effects of hypertension. The arguments advanced take into consideration the unique properties of the afferent arteriolar myogenic response that allow it to protect against the oscillating systolic pressure and the accruing evidence that when this response is impaired, the primary consequence is not a disturbed volume homeostasis but rather an increased susceptibility to hypertensive injury. It is suggested that redundant and compensatory mechanisms achieve volume regulation, despite considerable fluctuations in distal delivery, and the assumed moment-by-moment regulation of renal hemodynamics is questioned. Evidence is presented suggesting that additional mechanisms exist to maintain ambient levels of RBF and GFR within normal range, despite chronic alterations in BP and severely impaired acute responses to pressure. Finally, the implications of this new perspective on the divergent roles of the myogenic response to pressure vs. the TGF response to changes in distal delivery are considered, and it is proposed that in addition to TGF-induced vasoconstriction, vasodepressor responses to reduced distal delivery may play a critical role in modulating afferent arteriolar reactivity to integrate the regulatory and protective functions of the renal microvasculature.