Use of response surface methodology to optimise the hydrolysis of whey protein isolate in a tangential flow filter membrane reactor

Abstract

Response surface methodology (RSM) was used to investigate the effects of substrate concentration ( S), enzyme concentration ( E) and initial permeate flow rate, ( J i), on permeate flux behaviour in a 10 kDa nominal molecular weight cut-off (NMWCO) tangential flow filter (TFF) enzyme membrane reactor (EMR) during 3 h hydrolysis of whey protein isolate (WPI) using Protease N Amano (IUB 3.4.24.28, Bacillus subtilis) at pH 7.0 and 45 °C. The average residual permeate flow rate ( J residual), residual enzyme activity ( A residual) and product recovered in permeate designated as apparent sieving ( S apparent) were monitored. The quadratic model regression equations obtained revealed that all the three factors had significant but dissimilar influences on permeate flux behaviour. J residual, S apparent and A residual increased with increasing E, A residual decreased with increasing J i and there was substrate inhibition at low E. The optimised factors were S = 4.72% (w/v), E = 0.055% (w/v; hence E/ S ≈ 1% w/w) and J i = 6.91 mL/min (approximately 0.7% reactor volume per minute). The optimised values were 87.24%, 52.37% and 35.08% for J residual, A residual and S apparent, respectively. The actual values for the responses agreed well with the predicted values implying that RSM is suitable for EMR optimisation. Covariance values showed that J residual and S apparent increased concomitantly while A residual decreased with increasing S apparent and J residual.