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THE FUNCTIONAL PROPERTIES 
OF MILK PROTEIN CONCENTRATES 
.� 
,.; 
MASSEV 
UNIVERSITY 
A thesis presented for the degree of 
Doctor of Philosophy in Food Technology at Massey University 
Palmerston North New Zealand 
Alistair James Carr 
1999 
Abstract 11 
Abstract 
The aim of this thesis was to explore aspects of the functional properties of MPC85 (milk 
protein concentrate, 85% protein). A rheological study of milk protein concentrate 
(52°C) prior to spray drying showed a slight age-thinning behaviour which lasted about 
one hour, after which the apparent viscosity of the concentrate remained constant. This 
result is the opposite of skim milk concentrate which age-thickens at evaporator 
temperatures. The flow behaviour of the concentrate was adequately described by a 
Power Law rheological model. 
The rheological properties of reconstituted commercial MPC85 were studied at various 
temperatures and concentrations. At low concentrations «10% w/w total solids) 
MPC85 solutions were Bingham Plastics. The yield stress was found to increase with 
temperature and concentration. At high concentrations (> 15% w/w total solids) the 
logarithm of apparent viscosity was found to increase linearly with protein 
concentration. These solutions were also found to be Bingham Plastics. At lower 
temperatures « 35°C), however, these MPC85 solutions (>15% w/w total solids) were 
pseudoplastic and did not possess a yield stress. 
The solubility of commercial MPC85 was found to be dependent on the temperature at 
which the solution was prepared, increasing from ::::::59% at 20°C to 100% at 50°C. 
Homogenisation was shown to improve the solubility of MPC85 at 20°e. The 
rheological properties of MPC85 were profoundly influenced by the presence of any 
insoluble solids. 
The effect of preheat treatments during the pilot-scale manufacture of MPC85 on 
functionality was investigated. Heat treatment had no effect on heat stability of 
reconstituted MPC85 solutions for whey protein denaturation (WDN) values up to 86%. 
Heat treatments resulting in �90% WDN produced a dramatic loss in heat stability. The 
variations in rheology and rennet coagulation properties among the pilot plant powders 
were found to be correlated with the apparent diameter of the casein micelles. In 
Abstract III 
reconstituted solutions the apparent diameter of the casein micelles increased gradually 
with heat treatments up to 86% WDN and dramatically at higher WDN levels. 
The main effect of preheat treatments during manufacture on the rheology of MPC85 
solutions was the linear increase in apparent viscosity with apparent diameter of casein 
micelles. The variation in apparent viscosity with apparent diameter of casein micelles 
was found to be greater at low shear rates. A schematic model was proposed to account 
for these observations. 
A factorial design experiment was used to identify the components and interactions of 
components which play a significant part in determining the functionality of MPC85. 
This work demonstrated techniques for modelling heat stability - pH profiles and 
thereby allowing the quantitative comparison of the entire profiles of different solutions 
rather than comparisons at just single pH values or qualitative comparisons regarding 
the shape of the profile. The addition of divalent cations in the absence of added 
phosphate resulted in solutions that were completely unstable at 120°C. 
Overall this work has provided a detailed characterisation of commercial MPC85, both 
of the rheology of the concentrate prior to spray drying and of the functional properties 
of the powder. The research presented here has implications for both processing and 
product formulation. 
Acknowledgements iv 
Acknowledgements 
Sincere thanks to my chief supervisor Peter Munro for the many hours of stimulating 
discussion, helpful advice, encouragement and friendship throughout the length of this 
project. I am also thankful for the support and guidance of my co-supervisor Hrujinder 
Singh. 
The funding of this project by the New Zealand Dairy Board is gratefully acknowledged. 
Special thanks to Gheeda and June for their friendship, advice and keeping the post-grad 
lab ticking over; Alistair Young for his humour, assistance in running the pilot plant 
equipment and for furthering my education in the finer points of sarcasm; and Byron 
McKillop for keeping bits of equipment running. 
Thank you also to John Lucey, Michelle Tamehana, Steve Glasgow, Anne Marie Zanker 
and to all the postgrad students especially Magesh, David, King Tasa, Steve, Anil, VV, 
Khalid, Hong, Lise, Rani, Algane and Jackie. 
I am indebted to Warren Sutton from Anchor Products, Hautapu, for assistance and 
advice with the factory based experiments and for providing the 20kg 'sample' of 
commercial MPC85 on which most of this work is based. 
My thanks also goes to: the Iep Facility at Grasslands Research, Palmerston North, for 
conducting the elemental analyses and Duncan Hedderly from the Massey Statistics 
Consultancy group for helpful advice in handling data. 
Many thanks to the staff in the Consumer and Application Science section (nee Food 
Ingredients section) ofNZDRI especially: Warren for the croissants, hot cross buns, and 
shortbread; Chris and Ranjan for allowing me to clutter their laboratory; Michelle, Lisa, 
Acknowledgements v 
Charlie, Ivan, Di, Mary and Steve for the many useful discussions ranging from how to 
clear blockages in the homogeniser to suitable names for chooks. 
I would also like to thank all the other staff at the NZDRI who have provided help 
during this work including: Skelte Aenema for help conducting and interpreting the 
particle size analysis; Brent Vautier for supplying the ALANATE 1 80; Jac Roeper, 
Donald Love, Satyendra Ram, Tim Coolbear, and Christine Coker for useful discussions 
and encouragement. 
To all my flatmates over the years who have enjoyed many robust discussions on the 
more intricate details of dairy products. 
A special thanks to Turlough 0' Carolan and Jacques Berthier for composing music 
without which I might be a little less than campus mentus. 
The "Lads" deserve a special thank you for hearing the excuse "West alpine style ascent 
of K2 following the Abruzzi line? yeah well . . . . , any other weekend, I mean you know 
me . . .  but well yeah ahhh I was ern going to work on the thesis and umm . . .  " many, 
many times over the last few years. 
Thanks also to my parents for giving me encouragement throughout my studies (to 
finish!) and Mary for being an atypical "motber-tn-latn!". 
Finally, thank you to Hannah: "Ah lass . . .  do you know how fine you are to me?" 
Table of Contents VI 
Table of Contents 
ABSTRACT II 
ACKNOWLEDGEMENTS IV 
TABLE OF CONTENTS VI 
1. REVIEW OF LITERATURE 1 
1 . 1  Introduction 1 
1 .2 Chemistry and thermophysical properties of milk 1 
1 .3 Milk proteins 2 
1 .3 . 1  Casein proteins 2 
1.3.1.1 Arrangement of casein in milk protein products 4 
1 .3 .2 Whey proteins 7 
1.4 Milk salts 8 
1 .5 Lactose 9 
1 .6 Review of processing operations involved in the production of powdered milk 
protein products 1 1  
1 .6. 1 Preheat treatments 1 2  
Table of Contents vu 
1 .6.2 The effects of concentration, concentrate preheating and concentrate holding 
on the rheology of milk protein concentrates 1 2  
1 .6.3 Spray drying 1 6  
1 .6.4 Homogenisation 1 7  
1 .6.5 Summary of processing operations involved m powdered milk protein 
products 20 
1 .7 Milk protein concentrate 20 
1 .7. 1 MPC manufacturing process 20 
1 .7. 1 . 1  Membrane processing 22 
1 .7.2 Composition and structure of milk protein concentrates 24 
1 .7.3 Effect of heat treatments on MPC85 manufacture 27 
1 .7.4 Functional properties of MPC 28 
1 .7.5 Effect of milk salts on the rheology of milk protein concentrate solutions 29 
1 .8 Planning research direction from literature review 30 
2 .  RHEOLOGY OF COMMERCIAL MPC85 CONCENTRATES DURING 
PROCESSING 33  
2 . 1  Materials and methods 33  
Table of Contents Vlll 
2. 1 . 1  Methodology of rheological experiments 33  
2. 1 .2 Total protein analysis 3 5  
2.2 Results and discussion 36 
2.2. 1 Investigation of the time dependency in MPC85 concentrate 36 
2.2.2 Effect of holding time on the flow properties of MPC85 concentrate 44 
2.3 Conclusions 48 
3 .  RHEOLOGY OF RECONSTITUTED COMMERCIAL MPC85 POWDER 50 
3 . 1  Materials and methods 50 
3 . 1 . 1  Composition of commercial powder 50 
3 . 1 .2 Composition of low heat skim milk 5 1  
3 . 1 .3 Preparation of solutions of reconstituted MPC85 5 1  
3 . 1 .4 Detennination of MPC85 solubility 
I 
52 
3 . 1 .5 Rheological measurements 53 
3 . 1 .5 . 1  Rheological measurements using the Haake VT500 54 
3 . 1 .5 .2 Rheological measurements using the Bohlin VOR Rheometer 55  
3 .2 Effect of method of reconstitution on solubility 55  
Table of Contents lX 
3.3 Effect of solubility on apparent viscosity 58  
3 .4 Effect of cold storage on rheology 62 
3 .5 Effect of holding at 52°C on rheology 67 
3.6 Comparison of the effects of concentration on apparent viscosity for reconstituted 
commercial MPC85 and low heat skim milk powder 69 
3.7 Effect of temperature and MPC85 concentration on viscosity 80 
3 .8 Conclusions 92 
3 .9 Impact of conclusions on the focus of the thesis 93 
4. EFFECT OF HEATING DURING PILOT-SCALE MANUFACTURE ON THE 
FUNCTIONAL PROPER TIES OF MILK PROTEIN CON CENTRA TE 95 
4. 1 Manufacture of pilot plant powders 95 
4.2 Composition of pilot plant powders 96 
4.2. 1 Protein analysis 96 
4.2. 1 . 1  Total protein 96 
4.2. 1 .2 Whey protein denaturation 97 
4.2.2 Elemental analysis 98 
4.3 Functional properties 1 1 0 
4.3 . 1  Solubility 1 1 0 
Table of Contents x 
4.3 .2 Particle size analysis of reconstituted MPC85 powders 1 1 1  
4.3.3 Rennet coagulation properties of reconstituted pilot plant powders 1 14 
4.3 .4 Apparent viscosity 126 
4.3.5 Apparent viscosity of reconstituted MPC85 held at 52°C 139  
4.3.6 Heat stability of reconstituted pilot plant powders 1 43 
4.4 Overall discussion and conclusions 1 46 
5 .  EFFECT OF COMPOSITIONAL DIFFERENCES BETWEEN RECONSTITUTED 
MILK PROTEIN CONCENTRATE AND SKIM MILK POWDER ON THEIR 
FUNCTIONAL PROPERTIES 
5 . 1  Introduction 
5 .2 Materials and methods 
5 .2. 1 Materials 
5.2.2 Experimental design 
5 .2.3 MPC85 solution preparation 
5 .2.4 Apparent viscosity 
5 .2.5 Heat stability 
5 .2.6 Rennet coagulation properties 
149 
149 
1 50 
1 50 
1 50 
1 52 
1 53 
1 53 
1 53 
Table of Contents Xl 
5.3 Results and discussion 1 54 
5.3. 1 Apparent viscosity 1 54 
5 .3 .2 Heat stability 1 6 1  
5.3.3 Rennet coagulation properties 1 75 
5 .4 Functional properties of MPC85 and low heat skim 1 84 
5 .5  Conclusions 1 87 
6. EFFECT OF COMPOSITIONAL DIFFERENCES BETWEEN RECONSTITUTED 
MILK PROTEIN CON CENTRA TE AND SOLUTIONS CONSISTING OF 
SODIUM CASEINATE AND WHEY PROTEIN CONCENTRATE ON THEIR 
FUNCTIONAL PROPERTIES 1 89 
6. 1 Introduction 
6.2 Methods 
6.2. 1 Solution preparation 
6.3 Results 
6.4 Conclusions 
7. SUMMARY AND CONCLUSIONS 
7.1 Introduction 
7.2 Functional Properties 
1 89 
1 90 
1 90 
1 93 
1 95 
1 96 
196 
1 97 
Table of Contents Xll 
7.2. 1 Rheology 1 97 
7.2.2 Heat Stability 200 
7.2.3 Rennet coagulation properties 200 
7.3 Main conclusions 201 
7.4 Recommendations for future work 202 
APPENDIX A - STATISTICAL EQUATIONS 204 
APPENDIX B - MINERAL COMPOSITION OF MPC85 POWDERS 206 
BIBLIOGRAPHY 208