Biomedical Engineering Reference
In-Depth Information
[51] S.R. Lustig and N.A. Peppas, Solute and penetrant diffusion in swellable polymers: VII. A Free
volume-based model with mechanical relaxation,
Journal of Applied Polymer Science
33 (1987)
533-549
[52] L. Simon, Analysis of heat-aided membrane-controlled drug release from a process control per-
spective,
International Journal of Heat and Mass Transfer
50 (2007) 2425-2433
[53] P.P. Madeira, X. Xu, J.A. Teixeria, and E.A. Macedo, Prediction of protein partition in polymer/
salt aqueous two-phase systems using the modified Wilson model,
Biochemical Engineering
Journal
24 (2005) 147-155
[54] G.M. Wilson, Vapor-liquid equilibrium: XI. A new expression for the excess free energy of mix-
ing,
Journal of American Chemistry Society
86 (1964) 127-130
[55] H. Renon and J.M. Prausnitz, Local compositions in thermodynamic excess functions for liquid
mixtures,
AIChE Journal
14 (1968) 135-144
[56] D.S. Abrams and M. Prausnitz, Statistical thermodynamics of liquid mixtures: A new expres-
sion for the excess Gibbs energy of partly or completely miscible systems,
AIChE Journal
21
(1975) 116-128
[57] J.M. Prausnitz, R.N. Lichtenthaler, and E. Gomes de Azevedo,
Molecular Thermodynamics of
Fluid-Phase Equilibrium
, 3rd edition, Prentice Hall, New Jersey, 1999 (chapter 6)
[58] S. Denis and J.M. Prausnitz, Statistical thermodynamics of liquid mixtures: A new expression
for the excess Gibbs energy of partly or completely miscible systems,
AIChE Journal
21 (1975)
116-128
[59] A. Fredenslound, R.L. Jones, and J.M. Prausnitz, Group-contribution estimation of activity
coefficients in nonideal liquid mixtures,
AIChE Journal
21 (1975) 1086-1099
[60] A. Haghtalab and B. Mokhtarani, On extension of UNIQUAC-NRF model to study the phase
behavior of aqueous two phase polymer-salt systems,
Fluid Phase Equilibria
180 (2001) 139-149
[61] J.A.P. Coutinho and F.L.P. Pessoa, A modified extended UNIQUAC model for proteins,
Fluid
Phase Equilibria
222-223 (2004) 127-133
[62] Y.-T. Wu, D.-Q. Lin, and Z.-Q. Zhu, Thermodynamics of aqueous two-phase systems—the
effect of polymer molecular weight on liquid-liquid equilibrium phase diagrams by the modi-
fied NTRL model,
Fluid Phase Equilibria
147 (1998) 25-43
[63] A. Haghtalab and B. Mokhtarani, The UNIFAC-NRF activity coefficient model based on group
contribution for partitioning of proteins in aqueous two phase (polymer + salt) systems,
Journal
of Chemical Thermodynamics
37 (2005) 289-295
[64] T. Oishi and J.M. Prausnitz, Estimation of solvent activities in polymer solutions using a group-
contribution method,
Industrial and Engineering Chemistry Process Design and Development
17
(1978) 333-339
[65] H.O. Paksoy, S. Ornektekin, B. Balcl, and Y. Demirel, The performance of UNIFAC and
related group contribution models: Part I. Prediction of infinite dilution activity coefficients.
Thermochimica Acta
287 (1996) 235-249
[66] K.K.S. Buck, N.I. Gerhardt, S.R. Dungan, and R.J. Philips, The effect of solute concentration
on equilibrium partitioning in polymeric gels,
Journal of Colloid and Interface Science
234 (2001)
400-409
[67] A.P. Sassi, H.W. Blanch, and J.M. Prausnitz, Phase equilibria for aqueous protein/polyelectro-
lyte Gel systems,
AIChE Journal
42 (1996) 2335-2353
[68] J. Wu, A.P. Sassi, H.W. Blanch, and J.M. Prausnitz, Partitioning of proteins between an aqueous
solution and a weakly-ionizable polyelectrolyte hydrogel,
Polymer
37 (1996) 4803-4808
[69] L. Jin, Y.-X. Yu, and G.-H. Gao, A molecular-thermodynamic model for the interactions between
globular proteins in aqueous solutions: Applications to bovine serum albumin (BSA), lysozyme,
α
-chymotrypsin, and uno-gamma-globulins (IgG) solutions,
Journal of Colloid and Interface
Science
304 (2006) 77-83
[70] L. Shang, S. Zhang, H. Du, and S.S. Venkatraman, A novel approach for the control of drug
release rate through hydrogel membrane: II. Thermodynamic modelling of the partition con-
trol scheme,
Journal of Membrane Science
321 (2008) 331-336
