On-line urea kinetics in haemodiafiltration

BACKGROUND.: Calculation of Kt/V and assessment of nutrition have so farbeen dependent upon off-line urea measurements of blood or dialysatesamples. Here we describe a biosensor for on-line urea measurementduring haemodiafiltration. METHODS.: The biosensor consisted of a cartridge containing covalentlylinked urease placed between two conductivity cells. The biosensorwas placed on the outlet line of a haemofilter in series witha dialyser in order to obtain an aliquot of plasma ultrafiltratefor on-line measurement of urea. RESULTS.: Urea nitrogen concentrations were highly correlated to the difference() in conductivity measured by the two conductivity cells bothin aqueous solutions (in-vitro studies, y=–6.676+32.12x,R²=0.998, P<0.0001) and in ultrafiltrates (ex-vivo studies,y=–6.7+32.01x, R²=0.98, P<0.00001). conductivity washighly reproducible (% variation: 0.8–5.3%) and stable(maximal % variation at 150 mg/dl after 180 min: 0.9±0.3vs initial values). The intradialytic plasma water urea profilewas obtained in 10 haemodialysis patients. To study recirculation,the plasma water urea profile was analysed before and 3 minafter stopping the dialysate flow. The pre- and post-stoppedflow ratio (1.21±0.1, mean±1 SD) was superimposableto conventional blood sampling data (opposite arm venous/arterial:1.22±0.11) and allowed correction for recirculation.A novel approach to urea kinetic modelling was described andused to reliably project end-dialysis and post-dialysis reboundurea concentration as early as 90 min. Projected (29.2±10.4g) or measured (29.8±10.5 g) net urea removal was highlycorrelated with the amount of urea collected in the total spentdialysate (29.7±10.6 g) (R²=0.99, R²=0.97 respectively). CONCLUSIONS.: These results indicate that on-line, real-time analysis of ureakinetics may provide information on delivery of adequate dialysisin high-efficiency techniques.