0
selected
-
1.
Is oxidative stress an issue in peritoneal dialysis?
Roumeliotis, S, Eleftheriadis, T, Liakopoulos, V
Seminars in dialysis. 2019;(5):463-466
Abstract
During the last two decades, oxidative stress (OS) has emerged as a novel risk factor for a variety of adverse events, including atherosclerosis and mortality in chronic kidney disease (CKD) patients. Increased OS occurs even in early stages of the disease, progresses with deterioration of renal function and is further aggravated by hemodialysis (HD), due to the bioincompatibility of the method. Compared to HD, peritoneal dialysis (PD) is a more biocompatible dialysis modality, characterized by a significantly reduced, but still high, OS status. The culprit for OS in PD is mainly the composition of PD solutions (low pH, lactate buffer, increased osmolarity and high glucose concentration). After heat sterilization of PD solutions, formation of glucose degradation products (GDPs) and advanced glycation end-products (AGEs) trigger inflammation and enhance OS. Chronic exposure of the peritoneum to this toxic, hyperglycemic environment leads to OS-derived morphologic damage of peritoneal cells, loss of ultrafiltration capacity and decreased technique survival. Moreover, OS is linked with peritonitis, loss of residual renal function, inflammation, atherosclerosis, cardiovascular (CV) disease, and increased mortality. To ameliorate OS status in PD, a multitargeted approach is necessary that includes use of neutral pH, low GDP, low lactate and iso-ismolar PD solutions, strict glycemic control, optimal volume management and, probably supplementation with antioxidants, N-acetylcysteine being the most promising among them.
-
2.
Dialysate Calcium Levels: Do They Matter?
van der Sande, FM, Ter Meulen, KJA, Kotanko, P, Kooman, JP
Blood purification. 2019;(1-3):230-235
Abstract
BACKGROUND Calcium (Ca) is an essential element that plays a critical role in many biological processes. In dialysis patients, the regulation of Ca balance is highly complex, given the absence of kidney function, endocrine disturbances and the use of drugs such as phosphate binders, vitamin D analogues, and calcimimetics. Also, the use of different dialysate Ca (DCa) baths has profound effect on Ca balance, which depends both on the difference between the Ca concentration in the bath and the serum of the patients, as on the ultrafiltration volume. SUMMARY The choice of DCa may have important short- and long-term consequences. While lower DCa (especially < 2.5 mEq/L) concentrations have been associated with an increased risk of sudden cardiac death in observational studies, DCa in the higher ranges (3.0 mEq/L and above) may contribute to vascular pathology. Intra-dialytic hemodynamics may also be affected by the choice of DCa. In general, lower DCa concentrations are associated with an increase, and higher DCa concentrations with a decrease in parathyroid hormone (PTH) levels. Preliminary data has suggested that a DCa of 2.75 mEq/L may help in obtaining a net zero intradialytic Ca balance in individual patients, but clinical experience is still limited. Key Message: The optimal Ca balance depends on multiple parameters including blood Ca levels, PTH and the use of phosphate binders and vitamin D analogues, as well as on the risk of hemodynamic stability and cardiac arrhythmias. Therefore, DCa prescription should be individualised. A DCa of 2.75 mEq/L may be useful adjunct for dialysis providers.
-
3.
Vitamin and trace element deficiencies in the pediatric dialysis patient.
Harshman, LA, Lee-Son, K, Jetton, JG
Pediatric nephrology (Berlin, Germany). 2018;(7):1133-1143
-
-
Free full text
-
Abstract
Pediatric dialysis patients are at risk of nutritional illness secondary to deficiencies in water-soluble vitamins and trace elements. Unlike 25-OH vitamin D, most other vitamins and trace elements are not routinely monitored in the blood and, consequently, the detection of any deficiency may not occur until significant complications develop. Causes of vitamin and trace element deficiency in patients on maintenance dialysis patient are multifactorial, ranging from diminished nutritional intake to altered metabolism as well as dialysate-driven losses of water-soluble vitamins and select trace elements. In this review we summarize the nutritional sources of key water-soluble vitamins and trace elements with a focus on the biological roles and clinical manifestations of their respective deficiency to augment awareness of potential nutritional illness in pediatric patients receiving maintenance dialysis. The limited pediatric data on the topic of clearance of water-soluble vitamins and trace elements by individual dialysis modality are reviewed, including a brief discussion on clearance of water-soluble vitamins and trace elements with continuous renal replacement therapy.
-
4.
Prevention of hypophosphatemia during continuous renal replacement therapy-An overlooked problem.
Heung, M, Mueller, BA
Seminars in dialysis. 2018;(3):213-218
-
-
Free full text
-
Abstract
Hypophosphatemia is a common and potentially serious complication occurring during continuous renal replacement therapy (CRRT). Phosphate supplementation is required in the vast majority of patients undergoing CRRT, particularly beyond the first 48 hours. Supplementation can be provided either as a standalone oral or parenteral treatment or as an additive to CRRT solutions. Each approach has advantages and disadvantages, and clinicians must weigh the individual factors most relevant in their practice setting. Currently there are no consensus protocols for phosphate replacement in CRRT, and many centers replete phosphate in response to hypophosphatemia as opposed to pre-emptively. Repletion protocols have also been challenged in recent years by shortages in injectable phosphate solutions. More recently a commercially available phosphate-containing CRRT solution was approved in the United States, but there has been limited clinical experience with this product. In this review, we present recommendations for phosphate repletion in CRRT to prevent hypophosphatemia, and describe our experience using phosphate-containing CRRT solutions.
-
5.
Feeding during dialysis-risks and uncertainties.
Agarwal, R, Georgianos, P
Nephrology, dialysis, transplantation : official publication of the European Dialysis and Transplant Association - European Renal Association. 2018;(6):917-922
-
-
Free full text
-
Abstract
Allowing dialysis patients to eat during the treatment is controversial. It is, therefore, no surprise that practices and policies with respect to intradialytic food consumption vary considerably from unit to unit and from country to country. Those who defend the position of feeding during dialysis reason that intradialytic meals offer a supervised and effective therapy for protein-energy wasting. Those who take the opposite view argue that intradialytic food intake should be avoided for the following three reasons. First, interventional studies show that eating during dialysis causes a clinically significant reduction in systemic blood pressure during the postprandial period and elevates the risk of symptomatic intradialytic hypotension; the latter is associated with increased mortality risk. Second, clinical studies have shown that eating during dialysis interferes with the adequacy of the delivered dialysis, whereas eating 2-3 h before the dialysis session has no impact on the efficiency of the subsequent dialysis treatment. And third, randomized studies show that eating during dialysis focus on the positive outcomes but do not adequately balance this potential benefit against the risk of intradialytic hemodynamic instability and poor quality of delivered dialysis. Even after half a century of providing long-term dialysis, definitive randomized trials that balance risks and benefits of eating during dialysis are missing. These knowledge gaps require randomized trials. Since there is a real possibility of harm with eating during dialysis, we caution that instead of encouraging the widespread use of intradialytic meals, practices and policies should focus on adequate nutrient intake during the interdialytic interval.
-
6.
Low GDP Solution and Glucose-Sparing Strategies for Peritoneal Dialysis.
Szeto, CC, Johnson, DW
Seminars in nephrology. 2017;(1):30-42
Abstract
Long-term exposure to a high glucose concentration in conventional peritoneal dialysis (PD) solution has a number of direct and indirect (via glucose degradation products [GDP]) detrimental effects on the peritoneal membrane, as well as systemic metabolism. Glucose- or GDP-sparing strategies often are hypothesized to confer clinical benefits to PD patients. Icodextrin (glucose polymer) solution improves peritoneal ultrafiltration and reduces the risk of fluid overload, but these beneficial effects are probably the result of better fluid removal rather than being glucose sparing. Although frequently used for glucose sparing, the role of amino acid-based solution in this regard has not been tested thoroughly. When glucose-free solutions are used in a combination regimen, published studies showed that glycemic control was improved significantly in diabetic PD patients, and there probably are beneficial effects on peritoneal function. However, the long-term effects of glucose-free solutions, used either alone or as a combination regimen, require further studies. On the other hand, neutral pH-low GDP fluids have been shown convincingly to preserve residual renal function and urine volume. The cost effectiveness of these solutions supports the regular use of neutral pH-low GDP solutions. Nevertheless, further studies are required to determine whether neutral pH-low GDP solutions exert beneficial effects on patient-level outcomes, such as peritonitis, technique survival, and patient survival.
-
7.
High versus low dialysate sodium concentration in chronic haemodialysis patients: a systematic review of 23 studies.
Basile, C, Pisano, A, Lisi, P, Rossi, L, Lomonte, C, Bolignano, D
Nephrology, dialysis, transplantation : official publication of the European Dialysis and Transplant Association - European Renal Association. 2016;(4):548-63
Abstract
BACKGROUND It is the object of debate whether a low or high dialysate sodium concentration (DNa(+)) should be advocated in chronic haemodialysis patients. In this paper, we aimed at evaluating benefits and harms of different DNa(+) prescriptions through a systematic review of the available literature. METHODS MEDLINE and CENTRAL databases were searched for studies comparing low or high DNa(+) prescriptions. Outcomes of interest were mortality, blood pressure (BP), interdialytic weight gain (IDWG), plasma sodium, hospitalizations, use of anti-hypertensive agents and intradialytic complications. RESULTS Twenty-three studies (76 635 subjects) were reviewed. There was high heterogeneity in the number of patients analysed, overall study quality, duration of follow-up, DNa(+) and even in the definition of 'high' or 'low' DNa(+). The only three studies looking at mortality were observational. The risk of death was related to the plasma-DNa(+) gradient, but was also shown to be confounded by indication from the dialysate sodium prescription itself. BP was not markedly affected by high or low DNa(+). Patients treated with higher DNa(+) had overall higher IDWG when compared with those with lower DNa(+). Three studies reported a significant increase in intra-dialytic hypotensive episodes in patients receiving low DNa(+). Data on hospitalizations and use of anti-hypertensive agents were sparse and inconclusive. CONCLUSIONS There is currently no definite evidence proving the superiority of a low or high uniform DNa(+) on hard or surrogate endpoints in maintenance haemodialysis patients. Future trials adequately powered to evaluate the impact of different DNa(+) on mortality or other patient-centred outcomes are needed.
-
8.
New Options for Iron Supplementation in Maintenance Hemodialysis Patients.
Vaziri, ND, Kalantar-Zadeh, K, Wish, JB
American journal of kidney diseases : the official journal of the National Kidney Foundation. 2016;(3):367-75
Abstract
End-stage renal disease results in anemia caused by shortened erythrocyte survival, erythropoietin deficiency, hepcidin-mediated impairment of intestinal absorption and iron release, recurrent blood loss, and impaired responsiveness to erythropoiesis-stimulating agents (ESAs). Iron malabsorption renders oral iron products generally ineffective, and intravenous (IV) iron supplementation is required in most patients receiving maintenance hemodialysis (HD). IV iron is administered at doses far exceeding normal intestinal iron absorption. Moreover, by bypassing physiologic safeguards, indiscriminate use of IV iron overwhelms transferrin, imposing stress on the reticuloendothelial system that can have long-term adverse consequences. Unlike conventional oral iron preparations, ferric citrate has recently been shown to be effective in increasing serum ferritin, hemoglobin, and transferrin saturation values while significantly reducing IV iron and ESA requirements in patients treated with HD. Ferric pyrophosphate citrate is a novel iron salt delivered by dialysate; by directly reaching transferrin, its obviates the need for storing administered iron and increases transferrin saturation without increasing serum ferritin levels. Ferric pyrophosphate citrate trials have demonstrated effective iron delivery and stable hemoglobin levels with significant reductions in ESA and IV iron requirements. To date, the long-term safety of using these routes of iron administration in patients receiving HD has not been compared to IV iron and therefore awaits future investigations.
-
9.
Dialysate-induced hypocalcemia presenting as acute intradialytic hypotension: A case report, safety review, and recommendations.
Thurlow, JS, Yuan, CM
Hemodialysis international. International Symposium on Home Hemodialysis. 2016;(2):E8-E11
Abstract
Intradialytic hypotension is the most common complication associated with hemodialysis. We describe a case of severe intradialytic hypotension during routine chronic dialysis, the presenting symptom of hypocalcemia due to a procedural error involving a zero calcium liquid acid dialysate concentrate. Although human factors were the root cause of this event, we discuss physical and procedural controls that may help to minimize the risk of human error. Citrate anticoagulation for renal replacement therapy is increasingly used, particularly in acute kidney injury. Thus, zero calcium liquid acid dialysate is more likely to be stocked by dialysis units that serve both inpatients and outpatients. Providers in such units must maintain the utmost vigilance for human error involving these concentrates, as it is likely that the reported literature does not accurately reflect the frequency of such adverse events occurring during dialysis. Structured and universal reporting of errors to allow systematic analysis of hemodialysis device related hazards would allow identification of engineering controls that could prevent such potentially catastrophic clinical errors.
-
10.
Icodextrin-induced acute pancreatitis in a peritoneal dialysis patient: a case report and literature review
.
Rubinstein, S, Franjul, R, Surana, S, Fogel, J
Clinical nephrology. 2016;(11):283-286
Abstract
The 7.5% icodextrin solution is widely used for long-dwell in peritoneal dialysis (PD) regimens as an alternative osmotic agent to glucose. It has been defined as a biocompatible agent because of its iso-osmolarity and is generally safe and well tolerated. Icodextrin and its hydrolyzed metabolites are found in systemic circulation. In serum, icodextrin interferes with amylase determination causing a significantly decreased plasma amylase level making it unreliable for the diagnosis of acute pancreatitis. Lipase measurement provides an alternative and accurate method for diagnosing acute pancreatitis (AP) in patients using icodextrin. Icodextrin-induced acute pancreatitis is not well described. The literature appears limited to two case reports. We describe a case of a man with end-stage renal disease (ESRD) on PD who developed acute pancreatitis following icodextrin use. We also provide a novel possible mechanism for understanding how icodextrin causes AP.
.