Sage Journals: Discover world-class research

Abstract

Introduction

Hollow fiber models describe the exchange of solutes between blood and dialysate across the membrane of a single fiber of the hemodialysis filter (hemodialyzer). This work aims to develop a new approach to simulate the solute exchange in a hollow fiber in a dynamic and realistic way. Sodium was chosen as our solute of interest due to its importance in hemodialysis as an osmotic regulator.

Methods

A 2-dimensional (2D) hollow fiber model based on the finite element method (FEM) is coupled to a simple blood pool model to dynamically update the concentration of the solute entering the dialyzer. The resulting coupled model maintains the geometrical detail of the 2D fiber representation and gains a dynamic, blood-side inlet solute concentration. In vitro dialysis sessions were carried out for model validation, by implementing a combination of blood volume loss and/or sodium concentration steps. Plasmatic sodium concentration was recorded by blood gas sampling. Dialysate inlet and outlet conductivities were continuously recorded.

Results

Simulated plasmatic sodium concentration was compared with data from the blood gas samples. A mean error of 1.76 ± 1.03 mM was found for the complete dataset, along with a 3.87 mM maximum error. The simulated outlet dialysate sodium concentration was compared with the recorded outlet dialysate conductivity: a very high correlation was found on the whole dataset (R² = 0.992).

Conclusions

Coupling our FEM hollow fiber model to a simple blood pool model proved to be an effective approach for dynamical analysis of the properties of the hemodialyzer.

Keywords

Hemodialysis Hollow fiber Membrane Numerical model Sodium exchange

Get full access to this article

View all access options for this article.

References

Sargent

J.A.

, Gotch

F.A.

Principles and biophysics of dialysis. In: Drukker

, Parsons

F.M.

, Maher

J.F.

eds. Replacement of Renal Function by Dialysis, 2nd ed. Dordrecht: Martinus Nijhoff Publishers; 1983.

Galach

, Ciechanowska

, Sabalińska

, Waniewski

, Wójcicki

, Weryńskis

Impact of convective transport on dialyzer clearance.

J Artif Organs. 2003; 6(1): 42–48.

Waniewski

Mathematical modeling of fluid and solute transport in hemodialysis and peritoneal dialysis.

J Membr Sci. 2006; 274(1-2): 24–37.

Liao

, Poh

C.K.

, Huang

, Hardy

P.A.

, Clark

W.R.

, Gao

A numerical and experimental study of mass transfer in the artificial kidney.

J Biomech Eng. 2003; 125(4): 472–480.

Ding

, He

, Zhao

, Zhang

, Shu

, Gao

Double porous media model for mass transfer of hemodialyzers.

Int J Heat Mass Transfer. 2004; 47(22): 4849–4855.

, Lu

W-Q

. A numerical simulation for mass transfer through the porous membrane of parallel straight channels. Int J Heat Mass Transfer. 2010; 53(11-12): 2404–2413.

Annan

Mathematical modeling of the dynamic exchange of solutes during bicarbonate dialysis.

Math Comput Model. 2012; 55(5-6): 1691–1704.

Islam

M.S.

, Szpunar

Study of Dialyzer Membrane (Polyflux 210H) and Effects of Different Parameters on Dialysis Performance.

Open Journal of Nephrology. 2013; 3: 161–167.

Yamamoto

, Matsuda

, Hirano

. Computational evaluation of dialysis fluid flow in dialyzers with variously designed jackets. Artif Organs. 2009; 33(6): 481–486.

10.

Eloot

, De Wachter

, Van Tricht

, Verdonck

Computational flow modeling in hollow-fiber dialyzers.

Artif Organs. 2002; 26(7): 590–599.

11.

Ding

, Li

, Sun

. Three-dimensional simulation of mass transfer in artificial kidneys. Artif Organs. 2015; 39(6): E79–E89.

12.

Mann

, Stiller

Sodium modeling.

Kidney Int Suppl. 2000; 76: S79–S88.

13.

Gotch

F.A.

Evolution of the single-pool urea kinetic model.

Semin Dial. 2001; 14(4): 252–256.

14.

Ursino

, Colí

, Magosso

. A mathematical model for the prediction of solute kinetics, osmolarity and fluid volume changes during hemodiafiltration with on-line regeneration of ultrafiltrate (HFR). Int J Artif Organs. 2006; 29(11): 1031–1041.

15.

Sternby

, Daugirdas

J.T.

Theoretical basis for and improvement of Daugirdas' second generation formula for single-pool Kt/V.

Int J Artif Organs. 2015; 38(12): 632–637.

16.

Casagrande

, Bianchi

, Vito

. Patient-specific modeling of multicompartmental fluid and mass exchange during dialysis. Int J Artif Organs. 2016; 39(5): 220–227.

17.

Heineken

F.G.

, Evans

M.C.

, Keen

M.L.

, Gotch

F.A.

Intercompartmental Fluid Shifts in Hemodialysis Patients.

Biotechnol Prog. 1987; 3(2): 69–73.

18.

Flanigan

M.J.

Role of sodium in hemodialysis.

Kidney Int Suppl. 2000; 76: S72–S78.

19.

Baxter website. http://www.gambro.de/en/global/Products/Hemodialysis/Dialyzers/index.html. Accessed October 18, 2016.

20.

Cussler

E.L.

Diffusion: Mass transfer in Fluid Systems. 3rd ed. Cambridge University Press, 2009.

21.

Bouré

, Vanholder

Which dialyser membrane to choose?

Nephrol Dial Transplant. 2004; 19(2): 293–296.

22.

Dullien

F.A.L.

Porous Media: Fluid Transport and Pore Structure. 2nd ed. Academic Press, 1991.

23.

Broek

A.P.

, Teums

H.A.

, Bargeman

, Sprengers

E.D.

, Smolders

C.A.

Characterization of hollow fiber hemodialysis membranes: pore size distribution and performance.

J Membr Sci. 1992; 73(2-3): 143–152.

24.

Yan

, Dejardin

, Schmitt

, Pusineri

Electrochemical characterization of a hemodialysis membrane.

J Phys Chem. 1993; 97(15): 3824–3828.

25.

Hayama

, Kohori

, Sakai

AFM observation of small surface pores of hollow-fiber dialysis membrane using highly sharpened probe.

J Membr Sci. 2002; 197(1-2): 243–249.

26.

Barzin

, Feng

, Khulbe

K.C.

, Matsuura

, Madaeni

S.S.

, Mirzadeh

Characterization of polyethersulfone hemodialysis membrane by ultrafiltration and atomic force microscopy.

J Membr Sci. 2004; 237(1-2): 77–85.

27.

Hedayat

, Szpunar

, Kumar

NAPK

, Peace

, Elmoselhi

, Shoker

Morphological Characterization of the Polyflux 210H Hemodialysis Filter Pores.

Int J Nephrol. 2012; 2012: 304135.

28.

Millington

R.J.

, Quirk

J.P.

Permeability of porous solids.

Trans Faraday Soc. 1961; 57(0): 1200–1207.

29.

Robinson

R.A.

, Stokes

R.H.

- Electrolyte Solutions. 2nd revised ed. Dover Publications, 2002.

30.

Polaschegg

H.D.

Automatic, noninvasive intradialytic clearance measurement.

Int J Artif Organs. 1993; 16(4): 185–191.

31.

Ficheux

, Argilés

, Mion

C.M.

Influence of convection on small molecule clearances in online hemodiafiltration.

Kidney Int. 2000; 57(4): 1755–1763.

32.

Petitclerc

Festschrift for Professor Claude Jacobs. Recent developments in conductivity monitoring of haemodialysis session.

Nephrol Dial Transplant. 1999; 14(11): 2607–2613.

33.

Moret

, Grootendorst

D.C.

, Beerenhout

, Kooman

J.P.

Conductivity pulses needed for Diascan® measurements: does it cause sodium burden?

NDT Plus. 2009; 2(4): 334–335.

34.

Zhang

J.B.

, Lin

, Zhao

X.D.

Analysis of bias in measurements of potassium, sodium and hemoglobin by an emergency department-based blood gas analyzer relative to hospital laboratory autoanalyzer results.

PLoS One. 2015; 10(4): e0122383.

35.

Tura

, Sbrignadello

, Mambelli

, Ravazzani

, Santoro

, Pacini

Sodium concentration measurement during hemodialysis through ion-exchange resin and conductivity measure approach: in vitro experiments.

PLoS One. 2013; 8(7): e69227.

Finite-Element Modeling of Time-Dependent Sodium Exchange across the Hollow Fiber of a Hemodialyzer by Coupling with a Blood Pool Model

Abstract

Introduction

Methods

Results

Conclusions

Keywords

Get full access to this article

References