4-cresol-sulfate and phenylacetic-acid

Hydrophobic uremic toxins accumulate in patients with chronic kidney disease, contributing to a highly increased cardiovascular risk. The clearance of these uremic toxins using current hemodialysis techniques is limited due to their hydrophobicity and their high binding affinity to plasma proteins. Adsorber techniques may be an appropriate alternative to increase hydrophobic uremic toxin removal. We developed an extracorporeal, whole-blood bifunctional adsorber particle consisting of a porous, activated charcoal core with a hydrophilic polyvinylpyrrolidone surface coating. The adsorption capacity was quantified using analytical chromatography after perfusion of the particles with an albumin solution or blood, each containing mixtures of hydrophobic uremic toxins. A time-dependent increase in hydrophobic uremic toxin adsorption was depicted and all toxins showed a high binding affinity to the adsorber particles. Further, the particle showed a sufficient hemocompatibility without significant effects on complement component 5a, thrombin-antithrombin III complex, or thrombocyte concentration in blood in vitro, although leukocyte counts were slightly reduced. In conclusion, the bifunctional adsorber particle with cross-linked polyvinylpyrrolidone coating showed a high adsorption capacity without adverse effects on hemocompatibility in vitro. Thus, it may be an interesting candidate for further in vivo studies with the aim to increase the efficiency of conventional dialysis techniques.

Topics: Adsorption; Blood Cell Count; Charcoal; Cresols; Humans; Indican; Phenylacetates; Povidone; Renal Dialysis; Renal Insufficiency; Sulfuric Acid Esters; Uremia

Protein-bound uremic toxins, such as phenylacetic acid, indoxyl sulfate, and p-cresyl sulfate, contribute substantially to the progression of chronic kidney disease (CKD) and cardiovascular disease (CVD). However, based on their protein binding, these hydrophobic uremic toxins are poorly cleared during conventional dialysis and thus accumulate in CKD-5D patients. Therefore, we investigated whether hydrophobic and cationic adsorbers are more effective for removal of protein-bound, hydrophobic uremic toxins than conventional high-flux hemodialyzer. Five CKD-5D patients were treated using the fractionated plasma separation, adsorption, and dialysis (FPAD) system for 5 h. A control group of five CKD patients was treated with conventional high-flux hemodialysis. Plasma concentrations of phenylacetic acid, indoxyl sulfate, and p-cresyl sulfate were measured. Removal rates of FPAD treatment in comparison to conventional high-flux hemodialysis were increased by 130% for phenylacetic acid, 187% for indoxyl sulfate, and 127% for p-cresol. FPAD treatment was tolerated well in terms of clinically relevant biochemical parameters. However, patients suffered from mild nausea 2 h after the start of the treatment, which persisted until the end of treatment. Due to the high impact of protein-bound, hydrophobic uremic toxins on progression of CKD and CVD in CKD-5D patients, the use of an adsorber in combination with dialysis membranes may be a new therapeutic option to increase the removal rate of these uremic toxins. However, larger, long-term prospective clinical trials are needed to demonstrate the impact on clinical outcome.

Topics: Adsorption; Blood Proteins; Cresols; Humans; Indican; Phenylacetates; Pilot Projects; Plasmapheresis; Protein Binding; Renal Dialysis; Sulfuric Acid Esters; Uremia