Blood pressure in diabetic nephropathy--current controversies.

Hypertension has been recognized as an early and constant feature of diabetic nephropathy, but recent studies also suggest that a genetic predisposition to hypertension is an important risk factor for diabetic nephropathy. Antihypertensive treatment attenuates progression in diabetic nephropathy, but there is increasing evidence that very early treatment and very low target blood pressures should be implemented. There is also evidence for local activation of the renin system in the kidney as a result of hyperglycaemia. Apart from blood pressure, proteinuria should be monitored and dosing of ACE inhibitors should be guided, also by reduction of protein excretion.

Management of disturbed calcium metabolism in uraemic patients: 1. Use of vitamin D metabolites.

Chronic renal failure is characterized by diminished synthesis of, and resistance to, the active vitamin D metabolite 1,25-dihydroxy-vitamin D3 (1,25(OH)2D3, calcitriol). Calcitriol results from the biotransformation of the precursor 25-hydroxy-vitamin D3 (25(OH)D3) to 1,25(OH)2D3. 25(OH)D3 is synthesized in the liver, and 1alpha-hydroxylase, the rate-limiting enzyme for its biotransformation into the most active metabolite, 1,25(OH)2D3, is located in the kidney. The regulation of 1alpha-hydroxylase in renal failure is not well known. Recent work indicates that, in contrast to previous opinion, 1alpha-hydroxylase is predominantly expressed not in the proximal tubule but in the distal tubule [1]. In vivo, the main stimulatory signal is presumably parathyroid hormone (PTH) and the main inhibitory signal hyperphosphataemia. Both signals are altered in renal failure. There is also evidence that the renal 1alpha-hydroxylase becomes substrate-dependent in patients with renal failure. This means that a higher concentration of the precursor 25(OH)2D3 will result in a higher rate of transformation into the active metabolite 1,25(OH)2D3 in renal patients. Calcitriol is not exclusively synthesized in the kidney, but may also be synthesized in extra-renal tissues, e.g. activated monocytes/macrophages [2], particularly in granuloma [3] as shown by anephric uraemic patients who develop hypercalcaemia and elevated calcitriol concentrations when sarcoidosis [4] or tuberculosis [5] supervenes. On the other hand, calcitriol is less effective in uraemia. This may be to some extent due to diminished expression of vitamin D receptors [6], particularly in parathyroid glands when they undergo nodular transformation [7], but there may also be resistance to calcitriol at the post-receptor level [8]. In a series of elegant experiments [9,10], calcitriol resistance has been related to disturbed genomic effects of active vitamin D because the interaction of the vitamin D receptor ligand complex with vitamin D-responsive elements (VDREs) upstream of vitamin D-regulated genes was disturbed by the action of low molecular weight substances in uraemia, which have not been completely characterized. The role of genetically determined polymorphisms of the vitamin D receptor in the genesis of disturbed calcium metabolism of renal failure is currently unclear.

Circadian rhythm of blood pressure in renal disease.

Ambulatory blood pressure (BP) measurement has added a new dimension to the evaluation of abnormal BP in patients with various stages of renal disease. Although there is not complete consensus concerning the definition of normal values, a high prevalence of an abnormal circadian BP profile is noted in patients with essential hypertension with renal involvement (ie, microalbuminuria), in diabetic patients (particularly those with microalbuminuria or overt proteinuria), and in patients with primary chronic renal disease. Studies in diabetic patients point to an important role of both hypervolemia and disturbed autonomic innervation in the genesis of an abnormal circadian BP profile. In both patients with diabetic renal disease and patients with nondiabetic renal disease, retrospective studies suggest that an abnormal nocturnal decline in BP is associated with more rapid progression independent of 24-hour mean arterial pressure. The abnormal circadian BP profile persists in dialyzed patients, is ameliorated by long and frequent dialysis sessions, but is not completely normalized after successful renal transplantation.

[Diuretics and kidney diseases]. / Diuretika und Nierenerkrankungen.

The main indications for diuretic treatment of renal patients are edema and hypertension. Pharmacokinetics and pharmacodynamics of diuretics are altered in patients with proteinuria and/or impaired renal function. These patients exhibit avid sodium retention. Diuretics are partially inactivated by binding to proteins in tubular fluid. The natriuretic response to diuretics is limited by counter-regulation, specifically increased proximal tubular reabsorption in response to hypovolemia and increased distal tubular sodium reabsorption in response to increased sodium load. At higher serum creatinine values, thiazides are no longer sufficiently effective in monotherapy. The diuretics of first choice are then loop diuretics, potentially in combination with thiazide diuretics. Potassium-sparing diuretics are contraindicated. The most important side effects of diuretics are hypovolemia with orthostatic hypotension, hypokalemia, metabolic alkalosis, increase of creatinine concentration and (rarely) hyponatremia. Diuretic treatment should be accompanied by reduction of dietary sodium intake. Important points are selection of an adequate dose (in problematic cases dose-finding via urine sodium measurements) and selection of proper dosing intervals. If cases do not respond to loop diuretic monotherapy, combination with thiazide diuretics or intravenous administration of loop diuretics should be considered.

Counteracting progression of renal disease: A look into the future.

It is the very nature of research, including medical research, that truly novel results are not predictable. Nevertheless, some predictions concerning the understanding and management of progression of renal disease are plausible. It is very likely that in the future, exploding health budgets will force authorities and nephrologists to more effectively apply existing knowledge in this field to patients with early renal disease, particularly diabetics. We hope that this optimistic note is justified, although experience admittedly indicates that it is very much against human nature to behave rationally. With the powerful methodological tools available today, it is safe to predict that insight into the mechanisms underlying progression will also increase. Although pharmacological blockade of the renin-angiotensin system has been one of the great success stories of the past two decades, in many patients, progression is seen despite administration of angiotensin-converting enzyme (ACE) inhibitors and angiotensin receptor blockers. Fortunately, additional targets for intervention, such as endothelin-1, inflammatory cascades, chemokines, etc., are on the horizon. A particularly fertile target for prevention of progression will be kidney grafts, since it has become increasingly clear that factors unrelated to allo-immunity play an important role in chronic allograft nephropathy.

Non-insulin-dependent diabetes mellitus and hypertriglyceridemia impair lipoprotein metabolism in chronic hemodialysis patients.

Patients with diabetes mellitus undergoing chronic hemodialysis treatment have the worst outcome on dialysis due to an increased rate of cardiovascular complications. Nearly all patients present with dyslipidemia, a prominent vascular risk factor, probably responsible for the high rate of vascular injury. Since both uremia and diabetes predispose to hypertriglyceridemia, the present study was conducted to investigate the influence of diabetes mellitus and/or hypertriglyceridemia on lipoprotein metabolism in hemodialysis patients. LDL was isolated and characterized from hyper- and normotriglyceridemic diabetic and nondiabetic hemodialysis patients (n = 40; 10 in each group); also, LDL-receptor-dependent uptake and intracellular cholesterol metabolism were studied in HepG2 cells. In addition, scavenger-receptor-mediated uptake was examined in mouse peritoneal macrophages. LDL isolated from nondiabetic normotriglyceridemic hemodialysis patients exhibited impaired cellular uptake via the LDL receptor. Additionally, intracellular sterol synthesis was less inhibited and cholesterol esterification was reduced compared with LDL from healthy control subjects. Reduction of catabolic capacities was more marked in hemodialysis patients who were either diabetic or hypertriglyceridemic and even more pronounced in patients presenting with a combination of both diabetes and hypertriglyceridemia. Hypertriglyceridemic and diabetic patients showed reduced lipase activity and increased LDL oxidation. Furthermore, they accumulated a fraction of small, dense LDL, and LDL was predominantly taken up via the scavenger-receptor pathway in peritoneal macrophages. This study elucidates the distinct influence of diabetes and/or hypertriglyceridemia in hemodialysis patients on cellular LDL metabolism via specific and nonspecific metabolic pathways. Furthermore, it underscores the cumulative impact of these pathologic entities on impairment of lipoprotein metabolism and increase of cardiovascular risk.

Osteodystrophy in the millennium.

Despite three decades of intensive research on the derangements of calcium phosphate metabolism of renal failure, several unresolved issues are still with us at the turn of the millennium: poor control of hyperphosphatemia, relative inefficacy of active vitamin D to prevent progressive parathyroid hyperplasia, and persistence of bone disease despite lowering of parathyroid hormone (PTH) and administration of active vitamin D. Although predictions are problematic, it is not unreasonable to hope that, barring unforeseen side effects, calcimimetics will prove to be valuable for suppressing or even preventing hyperparathyroidism, thus potentially replacing, at least in part, active vitamin D. There is also reason to hope that more effective phosphate binders with fewer side effects will become available and that controlled studies will provide a rationale for the administration of estrogens to dialyzed women. As regards understanding the pathological mechanisms, one can anticipate that the disturbances leading to autonomous growth of parathyroid cells will be elucidated and the signals involved in osteoclast/osteoblast differentiation pathways and osteoclast/osteoblast coupling will be clarified, with obvious impact on patient management.