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Quality and utilization of raw milk retentate
produced at the dairy farm
PhD thesis by
Ida Sørensen
May 2017
Aarhus University – Foulum
Department of Food Science
Denmark
ii
Preface
This PhD thesis concludes on the results obtained by Ida Sørensen from October 2014 to May 2017.
Experimental work was conducted at the Department of Food Science, Aarhus University, Foulum,
at Danish Cattle Research Center, Aarhus University, Foulum and at Danmark Protein, Arla Foods.
The project was a collaboration between Aarhus University, Arla Foods and GEA; and funded by
GUPD.
Main Supervisor
Lars Wiking
Associate professor, Department of Food Science, Aarhus University
Co-supervisor
Lotte B. Larsen
Professor, Department of Food Science, Aarhus University
Assessment Committee
Niels Oksbjerg (chairman)
Senior researcher, Department of Food Science, Aarhus University
Monika Johansson
Associate professor, Department of Molecular Sciences, Swedish University of Agricultural
sciences
Alexander Tolkach
R&D Director, Bayerische Milchindustrie
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Acknowledgements
I would like to give very sincere thanks my main supervisor Lars Wiking for guidance and patience;
and most of all, for giving me the opportunity to be at this point in my career. I truly respect the
work it has required on your behalf. I also owe much gratitude to my co-supervisor Professor Lotte
B. Larsen, for all the knowledge and support you have given me.
A special thanks is given to Gitte Hald Kristensen and Rita Albrechtsen for help and assistance on
some of the more complicated analysis. Without your help, I would not have been able to reach this
level. Moreover, I would also like to thank the rest of the technicians: Caroline, Hanne and Jens for
advice and inspiration; and, naturally, bringing a good atmosphere to the labs.
I would also like to thank all the people from DKC, AFI and GEA whom I had the chance to work
with, and who taught all I wanted to know about cows and membrane filtration; and saved my day
on several occasions. In addition, deep thanks to my family for being supportive and understanding
when the times have been tough. Furthermore, thanks to Helle for helping me with much needed
graphical assistance.
Finally, a truly heartfelt thanks to all my wonderful friends and colleagues in Foulum, whom I have
had extraordinary fun with, and who have always been there if I needed help or company.
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Abstract
Because of the increased demand on the dairy industry to be competitive on a global market and to
have focus on environmental issues, it has long been a wish to explore the option to concentrate
milk at the farm before transport to the dairy. When considering that the size of the average dairy
cowherd is increasing and the number of dairies is decreasing due to merging, it is an obvious
solution to reduce the transportation costs. By implementing membrane filtration plants for
concentrating the milk directly at the farm, the volume of milk for bulk tank storage and transport
could be reduced to half, and the remaining permeate could be utilized as drinking water for the
cows or for cleaning. Part of the purpose of this project is to process the retentate into e.g. cheese or
milk powder, where pre-concentrating the milk is already part of the standard procedure during
production.
Before implementation of this type of process, it is important to ensure that the milk quality is not
affected. Mechanical treatments are known to cause damage to the milk, especially concerning the
milk fat globules (MFG); moreover, enzymes and bacteria native to the milk are concentrated as
well. Consequently, it is easy to imagine that the filtration process could potentially be harmful to
the milk quality. The purpose of this study is thus to identify the issues related to concentrating milk
at the farm, how it will affect the milk as a raw material and in relation to further processing, and
evaluate whether implementation of the technology is advisable from a quality perspective.
As part of this study, it was examined whether membrane type (ultra-filtration (UF) and reverse
osmosis (RO)) and several membrane filtration process parameters had an influence on the MFG
size distribution, free fatty acid (FFA) concentration and extend of proteolysis. The results showed
that the temperature during the filtration process and feed pressure had a significant influence on the
FFA concentration in the retentate. However, this effect was only observed on milk from automatic
milking system (AMS); not in milk from conventional parlour milking system. It was there for
concluded that the concentrating process only had an impact on the milk, when the mechanical
aggregation during AMS had predisposed the milk for further damage. In spite of the much higher
pressure required to perform RO compared to UF, no difference in e.g. FFA concentration was
observed. In order to avoid waste of lactose, it was decided to focus on RO during the following
studies.
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The rennet coagulation properties of RO retentate, as is essential during cheese production, was
compared to that of raw milk during the entire coagulation process. The study showed that the
coagulation onset time is later in retentate, but the gel firming rate was higher. Moreover, the
kinetics of chymosin was included as the hydrolysis rate of κ-casein (κ-CN) to caseinomakropeptide
(CMP), was evaluated based on varying concentrations of rennet and retentate dry matter. The study
showed that the ratio between chymosin and substrate was the determining factor for the reaction
rate of the hydrolysis, and thus, the time for coagulation onset. The distribution of calcium between
colloidal and serum phase was compared between retentate and raw milk was studied, and the
results showed that the retentate contained a higher portion of colloidal calcium and less serum
calcium. The change in ion equilibrium may have contributed to the changed coagulation
properties.
As part of the thesis, it was examined whether whole milk powder pre-concentrated by RO at the
farm had different properties and storage stability, compared to whole milk powder made from
regular raw milk. The study was affected by unintended changes to the milk composition (fat and
protein content) during the further processing prior to spray drying. This made it impossible to
conclude on differences directly caused by the RO process. Thus, several commercial whole milk
powders were included in the study as references in order to draw conclusions based on production
scale and composition on powder quality and storage stability. The results showed that the protein
content in particular had in influence on development of Maillard products during storage, reflected
on furosine concentration but not colour. The commercial powders had an initial higher
concentration of products from proteolysis than the experimentally produced powders from both
retentate and raw milk.
The contribution from this thesis has been a demonstration of how RO affects the milk and what
consequences that may have during further processing. From a quality point of view, there is no
hindering to implement membrane filtration at the farms. The overall status is however that there
are no economic and environmental benefits from this technology in Denmark, as the herd sizes and
distance to dairies is not enough to compensate for the extra cost of running many small filtration
plants. The implementation of the technology will however be an advantage in countries with
different conditions regarding transport distances.
vi
Sammendrag
Grundet det øgede præs på mejeriindustrien til at kunne være konkurrencedygtig på verdensplan, og
det samtidige fokus på miljø, har det længe været et ønske for mejerierne at undersøge muligheden
for at opkoncentrere mælken på gården, inden det bliver transporteret til mejerierne. Når man tager i
betragtning at den gennemsnitlige malkebesætning bliver større, og antallet af mejerier nedbringes
via sammenlægning, er det oplagt at forsøge at skære ned på omkostninger der er forbundet med
transport. Ved at implementere opkoncentrering direkte hos mælkeproducenterne vil volumen af
mælk til opbevaring og afhentning kunne halveres, og det resterende vand kunne bruges til
drikkevand til køerne eller til rengøring. En del af formålet med denne proces er at retentatet kan
videreforarbejdes til produkter såsom ost eller mælkepulver, hvor opkoncentrering af mælken
allerede er en del af standardprocessen under produktionen.
Før et system som dette kan implementeres er det nødvendigt at sikre sig at mælkens kvalitet ikke
belastes. Da mekanisk forarbejdning er kendt for at forvolde skade på mælken, især i form af
mælkefedtkugle (MFG) -beskadigelse, og mælken desuden bliver opkoncentreret med et intakt
indhold af enzymer og mikroorganismer, er det let at forestille sig at behandlingen måske kan have
en forringende virkning på kvaliteten. Således er formålet med dette studie at afgøre hvilken
betydning og konsekvenser opkoncentreringen vil have på mælken som råvare og under den
efterfølgende forarbejdning af retentatet, og ud fra et kvalitetsmæssigt synspunkt vurdere om denne
proces er tilrådelig.
Under studiets forløb har det været undersøgt hvorvidt membrantype (ultra-filtrering (UF) og
omvendt osmose (RO)) og proces-parametre tilknyttet membranfiltreringen, har haft betydning for
størrelsesfordelingen af MFG, indholdet af frie fedtsyre (FFA) og niveauet af proteolyse.
Resultaterne viste at procestemperaturen, og fødetryk havde indvirkning på dannelse af FFA, men
at denne effekt kun gjorde sig gældende i mælk fra automatisk malkningssystem (AMS), og ikke i
mælk fra en konventionel malkestald. Det blev derfor konkluderet at opkoncentreringen kun havde
en effekt når mælken i forvejen havde været udsat for hårdhændet behandling under malkningen og
derfor var prædisponeret for kvalitetsfejl. På trods af det væsentligt højere tryk som anvendes under
RO membran filtreringen, var denne proces ikke mere skadelig for mælken end UF. Så med henblik
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på at udgå spild af laktose gennem UF permeatet, blev det besluttet udelukkende at anvende RO i de
fremadrettede studier.
Retentatets løbe-koaguleringsegenskaber, der er essentiel ved fremstilling af ost, blev sammenlignet
med rå mælk i forhold til selve koaguleringsforløbet. Forsøgene viste at koaguleringen af retentate
starter senere, men med en hurtigere udvikling af koagelets fasthed. Yderligere, blev løbens
reaktionshastighed, baseret på hydrolyse af κ-casein til casein makropeptid (CMP), undersøgt under
varierende forhold mellem løbens koncentration og mælkens opkoncentreringsgrad. Det viste sig, at
forholdet mellem enzym og substrat var direkte bestemmende for reaktionenshastigheden af
hydrolysen, og dermed hvornår koaguleringen påbegynder. Desuden blev det undersøgt hvorledes
opkoncentreringen påvirkede fordelingen af calcium mellem micelle, serum og ionisk fase.
Resultatet viste at retentatet havde en højere andel af calcium bundet til caseinmicellerne og en
mindre andel som frie ioner sammenlignet med fordelingen i den rå mælk inden opkoncentrering.
Den ændrede mineral- og ionbalance kan meget ved være en medvirkende årsag til, at retentatet
opnåede hurtigere fasthed af koagelet.
Som en del af studiet blev det også undersøgt, om pulver lavet ud fra mælk der havde være
opkoncentreret på gården havde samme egenskaber og holdbarhed som pulver lavet ud fra
almindeligt rå mælk. Studiet bar præg af utilsigtede ændringer i råvarernes sammensætning (i form
af forholdet mellem fedt og protein), opstået under den videre forarbejdning, og det var derfor ikke
muligt at se en direkte konsekvens af opkoncentreringen på kvaliteten af det færdige pulver. Derfor
blev der i studiet inddraget adskillige kommercielle sødmælkspulvere til sammenligning, for på den
måde at konkludere sammenhængen mellem pulverets produktionsskala og sammensætning på de
endelige kvalitetsegenskaber. Resultatet viste, at især proteinindholdet havde betydning for
udvikling af Maillard produkter under lagring, hvilket afspejlede sig i indholdet af furosine men
ikke som farveændringer. De kommercielle pulvere havde som udgangspunkt en højre
koncentration af proteolyseprodukter end forsøgspulverene. Ligeledes blev der også udviklet
mindre eller tilsvarende mængder oxidationsprodukter i forsøgspulverene – både fra retentat og rå
mælk, sammenlignet med en kommerciel reference.
Denne afhandling har bidraget med en anskueliggørelse af hvorledes RO processen påvirker
mælken, samt hvilke konsekvenser det har for den videre forarbejdning. Der er ud fra et
viii
kvalitetsmæssigt synspunkt ikke noget til hindre for at implementere opkoncentrering af mælken på
gårdene. I det samlede billede af projektet, har det dog vist sig at den miljømæssige og økonimiske
gevinst kræver at gården har en vis minimum størrelse i forhold til afstanden til mejeriet som bliver
svær at imødekomme i Danmark. Implementeringen vil derfor være fordelagtig i lande med større
geografiske afstande mellem mælkeproducenter og mejerier.
ix
List of publications included in the thesis
Paper I
Chemical Quality of Raw Milk Retentate processed by Ultra-filtration or Reverse Osmosis
at the Dairy Farm
Ida Sørensen, Søren Jensen, Niels Ottosen, Tommas Neve & Lars Wiking
International Journal of Dairy technology, February 2016, Volume 69, Issue 1, Page 31-37
Paper II
Caseinomarcropeptide release in relation to rheological properties during rennet coagulation
of raw milk reverse osmosis retentate
Ida Sørensen, Thao T. Le, Gitte Hald Kristensen, Lotte Bach Larsen & Lars Wiking
Manuscript in preparation, intended for publication in International Dairy Journal
Paper III
Storage stability of whole milk powder produced from raw milk reverse osmosis retentate
Ida Sørensen, Tommas Neve, Niels Ottosen, Lotte Bach Larsen, Trine Kastrup Dalsgaard
& Lars Wiking
Dairy Science & Technology, 2017, Volume 96, Page 873–886
x
List of abbreviations
AMF Automatic milking system
CMP Caseinomacropeptides
FFA Free fatty acids
MF Micro filtration
MFG Milk fat globule
MFGM Milk fat globule membrane
NF Nano filtration
RO Reverse osmosis
TAG Triacylglycerol
UF Ultra filtration
VCF Volume concentration factor
ii
Contents
Preface ii
Main Supervisor ii
Co-supervisor ii
Assesment Committee ii
Acknowledgements iii
Abstract iv
Sammendrag vi
List of publications ix
List of abbreviations x
1. Project overview 1
1.1 Introduction 1
1.2 Aim and objectives 3
1.3 Experimental outline 3
1.3.1 Concentrating milk at the farm 3
1.3.2 Analytical methods 6
2 Raw milk quality 7
2.1 Milk composition 7
2.1.1 Fat 7
2.1.2 Protein 8
2.1.3 Lactose 10
2.1.4 Enzymes 11
2.1.4.1 Lipolysis 11
2.1.4.2 Proteolysis 12
2.1.5 Minerals 12
2.1.6 Somatic cells in milk 14
2.2 Primary production 15
2.2.1 Milking systems and pumping 15
2.2.2 Bulk tank storage 16
3 Filtration process 17
4 Cheese making process 20
4.1 Cheese production overview 20
4.2 Milk coagulation process 22
4.2.1 First stage 22
4.2.2 Second stage
4.2.3 The role of calcium
5 Milk powder 24
5.1 Milk powder manufacture 24
5.2 Milk powder quality 25
5.2.1 Powder composition and physical properties 25
5.2.2 Storage stability 26
6 Summary of included papers 28
6.1 Paper I: Chemical Quality of Raw Milk Retentate processed by Ultra-filtration or Reverse Osmosis at the Dairy Farm 28
6.1.1 Study objectives 28
6.1.2 Experimental setup 28
6.1.3 Summary of results 28
iii
6.2 Paper II: Caseinomacropeptide release and rheological properties during rennet coagulation of raw milk reverse osmosis retentate 29
6.2.1 Study objectives 29
6.2.2 Experimental setup 30
6.2.3 Summary of results 30
6.3 Paper III: Storage stability of whole milk powder produced from raw milk reverse osmosis retentate 32
6.3.1 Study objectives 32
6.3.2 Experimental setup 32
6.2.3 Summary of results 32
7 General discussion 34
8 Conclusion 41
9 Perspectives 43
10 References 45
Paper I
Paper II
Paper III
Appendix 1
Appendix 2
Appendix 3
Appendix 4
1
1. Project overview
1.1 Introduction
During the production of several dairy products such as milk powder, cheese and yoghurts, membrane
filtration is used to remove water, decrease volume in the cheese vats and standardize the protein
content of the milk. By transferring this process to the dairy farm, it would be possible to save costs for
transport and cooling, and reduce CO2 emission. As the heard sizes are currently increasing, and
certain countries have long distances between farms and dairies, this technology becomes even more
relevant. In cases with implementation of reverse osmosis membrane filtration it would even be
possible exploit the permeate as drinking water for the cows or for cleaning the equipment. Similar
practices have been implemented in the United States, Australia and New Zealand with little
documentation of the effect on milk quality. Generally, even though this technology is very well
known, the impact on the raw milk quality has not been fully studied.
Most literature on the subject of concentrating milk at the farm dates back to the 1980’s. Garcia III and
Medina (1988) described that reverse osmosis might have more advantages compared to ultrafiltration,
since ultrafiltration changes the composition of the milk by losing e.g. lactose in the permeate. This
makes the retentate less versatile for application in the dairy industry, and either value is lost in the
permeate or it needs subsequent treatment. Even so, a number of studies describe how ultra-filtration
could be implemented (Slack et al. 1982; Zall 1987a; Zall 1987b), with focus on the hygienic aspect of
microbial growth and handling and cleaning of the filtration equipment. An early study by de De Boer
and Nooy (1980) on RO showed that processing temperatures below 7.5°C lead to non-significant
increase of FFA concentration compared to higher processing temperatures. They concluded that the
main challenge would be to keep a high retentate quality, while applying enough pressure to prevent
fouling of the membranes. Kelly (1987) shared this concern, stating that the fouling effect would be
greater in raw milk compared to skim milk due to the presence of fat globules, which in turn would
cause a decreased flow and thus need of higher pressure. Pumping and general mechanical treatment
has been linked to milk fat globule damage, and thereby increased FFA formation (Wiking et al. 2003;
Fonseca et al. 2013).
2
This would result in quality defects such as off flavor (Nielsen 2005), and perhaps impair proper milk
fat separation (Evers 2004). Yet another major concern is that microorganisms and enzymes from the
raw milk would be concentrated as well, and perhaps affect the storage stability of the retentate.
This PhD study is structured in two parts according to the dairy processing route – from raw material to
final product. The first part is centered on the quality or raw milk retentate as directly affected by the
filtration process. Different membrane types (UF and RO) and processing parameters such as
temperature, pressure and concentration factor were studied in relation to the chemical quality of the
retentate (paper I). The second part used the knowledge gained from the first part to focus on the
functional properties of RO retentate, especially concerning cheese making properties (paper II) and
powder production (paper III). These products were chosen as obvious processing pathway of RO
retentate. Figure 1 shows a schematic overview of the study structure.
Quality of raw milk retentate in relation to processing parameters (Paper I)
Cheese making properties of raw milk RO retentate (Paper II)
Quality of whole milk powder made from raw
milk RO retentate (paper III)
Part 1
Part 2
Figure 1: Main structure of study elements included in this PhD thesis.
3
1.1 Aim and objectives
The general objective of this study was to examine and characterize changes to the milk after
membrane filtration of raw milk at the farm, both as a direct effect of the mechanical process, and due
to derived compositional and enzymatical changes. Thus, the aim of this study has been to correlate the
observed retentate attributes and quality defects to specific variables during the filtration process, such
as temperature, pressure and membrane type, and investigate how pre-concentrating raw milk will
reflect properties of further retentate processing into cheese curd and milk powder.
1.2 Experimental outline
1.2.1 Concentrating milk at the farm
The membrane filtration pilot plant was provided by GEA, assembled from existing parts. A model
drawing of the unit can be seen in figure 2. Danish Cattle Research Centre (DKC) provided the in situ
farm facilities and milk for the experiments. The filtration plant was built to be as versatile as possible,
with pumping capacity for both UF and RO, a plate heat exchanger for temperature control, and the
option of either continuous process or batch process. The specific setup differed with each experiment
(paper I -III). The plant was built with milk volume capacity fitting a medium size farm of
approximately 200 cows to accommodate the animal number at DKC. The milk used for the
experiments was mainly from Danish Holstein cows, and in some situations from a mixture of Danish
Holstein and Jersey. Both milk from automatic milking system and from herringbone parlour milking
was tested depending on the specific experiment. The cows were from herds of mixed lactation state
and feeding – especially the heard milked by automatic milking system had individual feeding
programmes depending on other parallel studies conducted at the farm. The raw milk was generally of
very high quality standard, with very SSC and CFU.
4
Figure 2: Drawing of the complete membrane filtration plant used for the experiments in this thesis,
including a small balance tank, plate heat exchanger and pumps.
Ideally, the RO permeate would have been utilized for either cleaning or drinking water. A drinking
water analysis was conducted (the approval failed on a phosphorus level of 1.8 mg/l and pH of 5.7),
and due to lack of resources, utilization of the RO permeate was not implemented.
Figure 3 shows how the filtration unit can be implemented in the process line between farm and dairy,
as it was done in this study.
5
Figure 3: Overview of the process line – from cow to final dairy product, where the membrane
filtration plant has been included as a continues process at the dairy farm.
6
1.2.2 Analytical methods
Table 1: overview of experimental techniques used and a reference to the paper where a detailed description is found.
Aim Method Paper
General milk composition FT-IR, MilkoScan I, II, III,
Appendix 3
FFA concentration BDI I
MFG size distribution Dynamic laser light scattering I
Proteolysis Flourescamine assay I, III
Total calcium Titration II
Ionic calcium Horiba electrode II
Rennet coagulation properties Convnetionel rheometer and ReoRox II
CMP concentration LC II
Fat content Rose-Gottlieb III, Appendix 4
Protein content Kjeldahl III, Appendix 4
Moisture content of powder Drying chamber III
Insoluble particles Dissolving, washing and centrifuged III
Surface free fat Petrolium ether washing III
Powder particle size distribution Sieving III
Oxidation HPLC III
Colour Minolta colourmeter III
Furosine concentration HPLC III
SSC Flow cytometry, Fossomatic Appendix 1
CFU Flow cytometry, BactoScan Appendix 2
Viscosity Rheometer Appendix 3
7
2 Raw milk quality
2.1 Milk composition
2.1.1 Fat
Fat is the milk components that differ most in content and composition through cow breed, feeding and
state of lactation, with an average content of 4 % (Walstra et al. 2006a). Milk is generally regarded an
oil in water emulsion, where the lipids primarily exist as triglycerides (TAG). Furthermore milk is
considered the fat source of most diverse TAG composition (Fox and McSweeney 1998c; MacGibbon
and Taylor 2006). Only very small parts of the milk fat exist as free fatty acids or as mono- and di-
glycerol (Jensen, 2002). The main fatty acids are palmitic, oleic, stearic and myristic acid. During
summer season a decrease of palmitic, myristic and caproic acid concentration can be observed
together with a higher concentration of oleic and stearic acid, thus giving a less saturated lipid
(MacGibbon and Taylor 2006; Huppertz et al. 2009). Organic milk has been found to have a higher
content of poly unsaturated and n-3 fatty acids, which is linked to changes in fodder composition in the
same way as differences between summer and winter season (Ellis et al. 2006). Milk fat synthesis is
divided into different pathways – each dominant during certain circumstances and will affect the fatty
acid composition (Palmquist 2006): Blood plasma lipids and de novo synthesized fatty acids. Blood
plasma lipids are the lipids directly absorbed from the blood stream into the mammary glands. This
account for nearly all the long chain fatty acids in the milk - the C18 and longer fatty acids, and some
of the C16. The blood plasma lipids are mostly in a TGA form, and only a small portion arises from
non-esterified fatty acids (Grummer 1991). The proportion of plasma lipids, and the form in which they
are taken up, is highly dependent on the cow’s energy balance and stage of lactation. During the
negative energy balance that is associated to the first state of lactation, a higher net uptake of non-
esterified fatty acids occurs, together with a higher level of body fat mobilization (Palmquist 2006).
Microorganisms in the rumen will, as part of the feed digestion, ferment the main part of the dietary
fats. Especially due to the microbial bio hydrogenation, lipase and esterase activity. Rumen
microorganisms will furthermore novo synthesize fatty acids, yielding mainly C18 and C16 or C18:1
and C16:1 if the pathway is anaerobic (Jenkins 1993).
8
When the fat is secreted from the mammary glands into the milk, parts of the apical plasma membrane
and parts from the cytoplasm of the secretory cell conceals the fat droplets and herby form a membrane
layer (Evers 2004). The milk fat globule membrane (MFGM) has a loose structure, and consists mainly
of bipolar material such as proteins, enzymes, phospholipids and cholesterols (Jensen 2002).
Depending on breed and state of lactation, the MFG size can range between 0.1 to 20µm (Fox and
McSweeney 1998c).The MFGM suppresses fat droplet merging due to decrease of surface tension
between fat droplets and water phase (Fox and McSweeney 1998c). Additionally, the MFGM acts a
protective barrier against milk lipase enzymes (Deeth 2006), thus preventing off flavor caused by free
fatty acids and lipid oxidation products.
2.1.2 Protein
Milk consists of 3.5% protein on average. However, like the case of fat, milk proteins is a highly
diverse group, where the amount and composition is influenced by state of lactation and genetics (Fox
and McSweeney 1998b; Ginger and Grigor 1999). The proteins are normally considered as two groups:
caseins and whey proteins, with an average ratio of 80:20 %. This fractionation was discovered as early
as 1830 based on acid precipitation, where caseins would precipitate at pH 4.6 (iso-electrical point) and
whey proteins would remain dissolved (Fox 2008). This division remains, but many sub-groups of both
whey proteins and caseins have later been discovered, together with several genetic variants and other
serum proteins (MFGM proteins, blood serum proteins, enzymes etc.).
Whey proteins consists mainly of β-lactoglobuline (10% of total milk protein) and α-lactalbumin (4%
of total milk protein). Early on, whey as regarded a waste product from cheese production, but
development of advanced dairy technology made it possible to utilize the whey proteins as functional
ingredients and infant formulas (Smithers 2008).
Caseins consist of αS1-CN, αS2-CN, β-CN and κ-CN connected by calcium-phosphate linkages to a
colloidal spherical micellar structure (Rasmussen et al. 1999; Farrell Jr et al. 2006). The actual structure
has been the topic of much debate, and considerable research has been conducted in order to shed light
on that matter, especially on the matter of sub-micelles compared to a random structure (Phadungath
9
2005; Horne 2006; Fox and Brodkorb 2008). Schematic models and electron microscopy pictures of
casein micelles is seen in figure 4. αS1-CN is the most abundant milk protein, and together with αS2-CN
construct the “framework” of the casein micelles due to the high content of sulphuric bridges formed.
The second most abundant protein is β-CN, which has the highest hydrophobicity. It has dynamic
abilities and can drift from the casein micelle into the serum phase at low temperatures, this tendency
can be reversed over time if the temperature is increased (Walstra et al. 2006b).
Figure 4: Casein micelle structure models and pictures. A: model based on the sub-micelle theory
(Walstra 1999). B: Tangled open structure (Holt 1992). C: Field Emission Scanning Electron
Microscopy image of casein micelle (Dalgleish et al. 2004). D: Transmission electron microscopy
picture of casein micelle (Karlsson et al. 2007b).
Pressure treatment of milk at >100MPa has shown to irreversibly change the micelle structure by
increasing the solubility of α-CN and β-CN (Huppertz et al. 2004). κ-CN has hydrophilic properties
10
and is primarily situated on the outer surface of the micelles. The hydrophilicity, together with a
negative electrostatic repulsion, keeps the micelles suspended in the milk (Fox and McSweeney 1998b;
McSweeney and Fox 2013). These properties are the basis in cheese production, where cleavage of the
hydrophilic outer part of κ-CN and reduction of negative charge (by lowering pH and adding Ca2+)
allows the casein micelles to merge.
2.1.3 Lactose
Lactose is the main carbohydrate in milk, with an average concentration of about 4.8%. Lactose is a
disaccharide of galactose and glucose, and regarded the main osmole in milk giving a total osmotic
pressure of 700kPa (Fox and McSweeney 1998d). During secession of lactose, water is drawn to the
Golgi vesicles according to osmolarity. Thus, lactose remains a constant concentration in the milk, but
the net-amount decreases during lactation stages due to overall decrease in milk yield (Fox 2008). An
exception occurs when cows suffer from mastitis; a decrease in lactose concentration is observed as a
regulatory system to compensate for the increased NaCl concentration giving a high osmotic pressure
(Auldist et al. 1995). Feeding regulations influencing blood glucose levels and farm managements can
however lead to an indirect increase in lactose output through overall milk yield (Broderick et al. 2002;
Auldist et al. 2007; Grainger et al. 2009). A high milk yield is associated with a lower protein and fat
content and thus lactose constitute more of the milk solids (Jenness and Holt 1987).
Previously, lactose was mainly considered as a waste product from cheese production as part of the
whey. Advances in technology has however made it possible to utilize lactose (Atra et al. 2005).
Human milk contains 6.9% lactose. The increasing demand for infant formula has thus made lactose a
highly valuable ingredient rather than a waste product. Lactose is the main substrate for starter culture
microorganisms during production of cheese, yoghurt and other fermented dairy products, and hereby
indirectly responsible for pH of the final product (Fox and McSweeney 1998a). The starter culture will
however not be able to utilize all the available lactose before the fermentation process stops at around
pH 4.4. Depending on the buffering capacity of the cheese curd, it might be necessary to restrict the
amount of available lactose in order to remain at the desired pH. This can be done by washing the
cheese grains for excess lactose (Nielsen 2004).
11
The properties and quality of milk powder are highly determined by the crystal state of lactose. The
crystals are formed when the temperature and relative humidity conditions fall between glass transition
state and melting point. Depending on the exact conditions different crystal polymorphs occur. This
will influence e.g. solubility and flowability; but also storage stability, as water can be released from
the crystalline structure. Moreover, lactose plays a major role in formation of maillard products – both
during the drying process but also during subsequently storage (Thomas et al. 2004).
2.1.4 Enzymes
The enzymes found in raw milk have two possible sources: Microbial contamination or indigenous
milk enzymes. The indigenous enzymes enter the milk either through somatic cells (Larsen et al. 2004),
from blood stream through leaky junctions, or secreted by the mammary epithelial cells. Especially the
complex MFGM contains a large number of different enzymes (Fox 2008). Today, a minimum of 70
different enzymes has been identified in raw milk, but only few has a known role during biosynthesis
of milk components or post-secretion. Many of the enzymes do not have access to proper substrates,
needs activation or the conditions in milk are not optimal. However, especially lipases such as LPL and
proteases e.g. plasmin are known to have an impact on the milk quality during processing and storage
(Fox and Kelly 2006).
2.1.4.1 Lipolysis
The main lipase enzyme in milk is LPL (EC 3.1.1.34). LPL is otherwise associated with very low
density lipoproteins in the blood stream where it hydrolyses triglycerides into free fatty acids. It will
hydrolyse fatty acids from sn-1 and sn-3 position in triglycerides, but the specificity is generally very
low. In bovine milk LPL is mostly connected to casein micelles. LPL is generally dependant on being
activated by Apolipoprotein C II in order to hydrolyse triglycerides, and hereby limiting the activity.
Still, LPL is the milk lipase responsible for spontaneous lipolysis of milk during storage. The activation
of LPL seems to be facilitated by rapid temperature changes and aggregation (Stepaniak 2004).
Moreover, the MFGM acts as an efficient barrier, shielding the milk triglycerides from LPL (Deeth
2006). Sundheim (1988) observed that LPL activity varied among individual cows, state of lactation
and even according to time of day, the milking was conducted. This emphasizes the complexity of the
system of activators and inhibitors (Bengtsson and Olivecrona 1980). The major concern regarding
12
lipolysis in milk is the formation of off-flavours from the concentration of FFA (Pillay et al. 1980;
Wiking et al. 2002; Santos et al. 2003). Wiking et al. (2002) showed that the concentration of FFA
during cold storage of milk increased within the first 24 h, with a constant concentration during
subsequent storage. They found this result reflected in the sensory analysis. Later on, Gargouri et al.
(2013) reached a similar conclusion as Wiking et al. (2002); that LPL is indeed the lipase responsible
for FFA emission compared to lipases from somatic cells and microorganisms, and that the major part
of spontaneous lipolysis occurs within the first day of storage. In his review, Deeth (2006) expressed
concern about microbial lipases being more heat stable, and might thus cause quality defect during
further processing rather than during bulk tank storage.
2.1.4.2 Proteolysis
Plasmin is the main protease system in good quality milk. Other protease systems such as cathepsin and
elastase are associated with an increased level of SSC (Kelly et al. 2006). Plasmin is not secreted
through the mammary glands, but only from the blood stream, leading to an increased content during
time periods with leaking tight junctions e.g. during udder infections and late state of lactation
(Nicholas et al. 2002). In milk from healthy cows, the inactive form – plasminogen is most prevalent.
Thus, the proteolytic activity is heavily regulated by the presence of activators, inhibitors and
plasminogen activator inhibitors (Ismail and Nielsen 2010). Plasmin is rather heat stable, and is
therefore known to affect the milk quality after heat treatment. β-CN is the primary substrate of
plasmin, however, αS1-CN, αS2-CN may also be hydrolysed at lower rates. Due to the hydrolysation of
casein, high plasmin activity has been linked to lower cheese yield and longer coagulation time (Lucey
and Fox 1992).
2.1.5 Minerals
Milk contains on average 0.7-0.8 % minerals, measured as total ash content (Fox and McSweeney
1998e), mainly phosphate, citrate, potassium, calcium, chloride, sodium and magnesium, together with
a large number of trace elements such as copper, iron and zinc. The minerals exist in several different
phases in the milk: colloidal – as organic or inorganic, and in serum phase as ions or bound in as
undissolved salts, where an equilibrium with pH between the phases is affected by temperature
(Shennan and Peaker 2000; Gaucheron 2005). Especially calcium and phosphate are part of a very
13
complex system related to the casein micelles as colloidal calcium phosphate nanoclusters, and as
calcium bound to phosphorylation of serine in the caseins (Mekmene and Gaucheron 2011; Bijl et al.
2013). This makes them highly responsible for the casein stability and structure. Table 2 shows the
average content and phase distribution of some of the major milk minerals.
Table 2: Mineral content(mM) and distribution in bovine milk. The table is adapted from (Mekmene et al. 2009).
Pinorganic Citrate Potassium Calcium Chloride Sodium Magnesium
Total 21 9 38 30 29 22 5
Colloidal 11 0.9 0.35 20.9 0 0.22 1.29
Serum 10 8.1 37.7 9.10 29 21.8 3.71
Ionic 7.3 0.2 36.26 2.12 27.8 20.9 1.14
Minerals enter the milk through five main routes: The membrane route, through the apical or
basolateral membranes (e.g. Na+, K+, Pi and Cl-); the Golgi secretory route, where proteins and lactose
are secreted (e.g. citrate and calcium); the milk fat route, where some minerals can be associated to the
MFGM and be part of certain hormones and enzymes; the transcytosis route, through expression of
immunoglobulins, transferrin and prolactin – especially during production of colostrum. The fifth
route, the paracellular route, is highly associated to mastitis where direct transport of components from
the interstitial fluid is seen (Shennan and Peaker 2000).
The total mineral content rarely changes, but the specific content of each mineral can exhibit a large
variation (Fox and McSweeney 1998e). Minerals are essential constitutes to calf nutrition, and thus the
mineral content is highly regulated by the lactation state. Each mineral is differently affected by the
state of lactation, and especially calcium secession increases during early and late lactation. Other
minerals, e.g. citrate and potassium concentration will however decrease during the course of lactation
(Gaucheron 2005). Sodium and chloride concentration are known to increase at early and late lactation,
and during an udder infection, due to weakening of tight junctions and thereby entry of interstitial fluid
into the milk. The cow nutrition has very little effect on the minerals in the milk (Schwendel et al.
14
2015), but other factors, such as breed can indirectly affect the mineral content, as Ca and p
concentration are showed to correlate to high protein and casein (Gaucheron 2005).
2.1.6 Somatic cells in milk
The milk secreting cells in the cow udder are connected via tight junctions, regulating the barrier
between milk and blood. This system can, however, be disturbed. This can be related to either lactation
state – such as during secretion of colostrum or due to infection of the glands. A leakage in the tight
junctions between the mammary epithelial cells leads to an increased amount of somatic cells into the
milk, due to concentration normally being higher in blood than milk, together with other substances
such as plasma enzymes and antibodies. Somatic cells are therefore an indicator of leaky tight
junctions, and since somatic cells are easily detected by flow cytometry, they are often used as a
measure of milk quality on the farm level and udder health. Somatic cells themselves may furthermore
be a source of enzymes, so it is required to keep the level of somatic cells to a minimum, as these
enzymes may contribute to milk quality deterioration due to both proteolysis and lipolysis. The amount
of somatic cells is measured in cells/ml milk and is referred to as the somatic cell count, SCC (Blowey
and P. 1995; Nielsen et al. 2002).
Often environmental infections from e.g. E. coli or Streptococcus species are responsible for the
infection, and in some instances are treated with antibiotics (Blowey & Edmondson 1995). Thus, good
hygiene and milking routine and high welfare for the cows prevents most cases of elevated SCC
(Blowey and P. 1995; Ruegg et al. 2000). During AMS milking, a vacuum can be build up if the teats
are empty. This enables bacteria from dirty tits to enter into the teat canal, and hereby infect the gland
(Rasmussen 2000). The amount of somatic cells is divided into categories according to the severity of
the number. In EU, the allowed limit is currently 400.000 cells/ml, very good quality of the milk may
be down to 200.000 cells/ml, while an acute mastitis infection may reach up to 1.000.000 cells/ml
(Kelly and Larsen 2010).
A consequence of an increased SCC number is that enzymes follows into the milk – either from within
the cells themselves or they come from the blood stream of the cow. Together with an increased SCC
an increase of proteolytic, lipolytic and oxidative enzymes can be found. Through their action on milk
15
substrates these enzymes will contribute to reduce the milk quality, even after mixing with high quality
milk, by e.g. causing casein to degrade. Unfortunately, these enzymes are quite heat stable, and will
probably tolerate low pasteurization (Larsen and Nielsen 2006). In addition, the consequences may be
even more pronounced in certain products, like cheese, compared with fresh milk products, due to
storage time. The milk composition at elevated SCC in general also changes, both due to influx of
blood components, leading to increase in whey protein, as well as degradation of the main milk
components, like triglyceride fat, caseins and lactose. Furthermore, milk mineral composition changes
due to exchange between milk and blood stream (Kelly and Larsen 2010).
2.2 Primary production
2.2.1 Milking systems and pumping
Since the introduction of automatic milking system, it has been known to cause certain quality defects
to the milk (Rasmussen et al. 2002). Klungel et al. (2000) and Abeni et al. (2005) observed a higher
concentration of FFA in milk from automatic milking systems compared to parlour milking, as well as
an increase in bacteria count (Klungel et al. 2000). Both studies correlated FFA increase to milking
frequency, when comparing data to farm with parlour milking. It was suggested that the increased
milking frequency stimulated an enzymatic response to the cow, which could result in higher lipase
activity. Moreover, protein content decrease when cows are milked three times a day compared to
twice a day (Klei et al. 1997). Mechanical stress and agitation has been linked to MFGM disruption
during pumping (Wiking et al. 2005). Especially milk with a high fat content was found to be less
stable towards a high shear rate, and this effect was enhances at temperatures above 20⁰C, which
resulted in MFG coalescence and subsequently an increase in FFA concentration (Wiking et al. 2003).
However, the stabilizing effect of crystalline lipids in the MGF in cold milk will largely prevent
MFGM disruption, and thereby limit the access of lipase. Presence of air in the pipe systems caused by
vacuum during milking, is another issue linked to AMS compared to parlour milking is the (Rasmussen
et al. 2006).
16
2.2.2 Bulk tank storage
At Danish dairy farms it is common to store the milk for 24 to 48 hours at 4⁰C before being collected
by the dairy. Furthermore, the milk can be further stored in dairy silos after arrival for an additional
period of time prior to pasteurization and further processing. The milk does, however, undergo changes
during bulk storage. Within the first 48 hours, β-casein is known to be released from the casein
micelles and diffuse into the serum phase. Furthermore, cooling increases calcium phosphate solubility,
leading to more calcium in the serum phase, rather than integrated into the casein micelles (Gaucheron
2005). This may lead to prolonged coagulation time during cheese production (Maciel et al. 2015). The
effect is, however, reversed, when the milk is heated during further processing (Ali et al. 1980; Connell
et al. 2017).
Microbial growth is one of the major concerns regarding bulk storage. The microorganisms mainly
originates from dirt on the udder and teats, from growth and biofilm in the milking equipment (Latorre
et al. 2010) and from unmanaged mastitis outbreak. This gives a very large range of psychotropic and
coliform bacteria, which can contaminate the milk and give undesirable off-flavour and enzymatic
activities. It is, however, possible to significantly minimize microbial growth with a strict hygiene
management at the farm (Elmoslemany et al. 2010; Velthuis and Asseldonk 2011; Connell et al. 2016).
An issue specific to storage raw milk retentate is the high buffering capacity of concentrated milk
(Salaün et al. 2005). pH is a limiting factor of bacterial growth, and the buffering effect combined with
high concentration of substrates for bacterial growths, has the potential to cause severe storage
problems if the hygienic procedures and maximum storage time is not properly controlled.
17
3 Filtration process
Today, a number of different concentration techniques exist. Cross-flow filtration through a semi
permeable polymer membrane is most common in the dairy industry, and depending on the
circumstances, the membrane can be designed as either a plate and frame or spiral wound system. The
plate and frame design is capable of handling highly viscous substrates, but is quite space consuming
and difficult to handle. The spiral wound membranes have gone through a lot of development in the
past years, and is considered very efficient relatively to size (Lewis 1996; Walstra et al. 2006b).
Membranes can be divided in four groups depending on pore sizes: microfiltration (> 500 nm), UF
(500 nm – 5 nm), NF (5 nm – 0.5 nm) and RO (< 1 nm). Microfiltration will hold back and thus
concentrate microorganisms, fat globules and some larger proteins in the retentate, and let smaller
proteins, lactose, minerals and water through the membrane as permeate. UF will retain caseins and
whey proteins together with fat and microorganisms in the retentate. NF will let through only water and
some minerals to the permeate and in RO, permeate will be almost pure water and perhaps small
molecules such as urea (Walstra et al. 2006b). Figure 5 shows a schematic overview of the membrane
types and the permeability.
Figure 5: Overview of membrane types according to pore size, pressure requirements and
permeability.
18
In order to overcome the hydraulic resistance of the membrane and possible fouling cake layer, a
certain feed pressure is needed. The retentate flux is a result of a combination of membrane spacer size,
product viscosity (due to e.g. VCF and temperature) and feed pressure. The retentate flux will often
decrease over time as fouling layer builds up (Kessler 2002; Walstra et al. 2006b).
Figure 6 General setup of a continuous membrane filtration process.
Generally, the filtration can be conducted as either a continuous or batch process. The continuous
process (figure 6) gives retentate with the desired concentration factor directly from the outlet valve
once the system has stabilized. This is done, more or less automatically, by controlling the ratio
between feed flow and retentate outlet flow through a retentate valve. In practice, the membrane unit
exists as a loop, mixing the feed product with part of the retentate that is held back by the valve
(Mulder 1996). A balance tank is required to ensure that air is not introduced into the system.
During batch processing, the retentate circulates back into the bulk tank until the desired concentration
factor has been reached (figure 7). The batch process allows a lower permeate flux and the ratio
between feed product and retentate is not crucial, as the dry matter of the feed material will slowly
increase. The total volume of the bulk tank will drop as more and more permeate it expelled (Mulder
19
1996). The choice of either continuous or batch process is a matter of the exact conditions. The
continuous process will generally be faster but consume more energy compared to the batch process,
where the concentration factor at the retentate outlet is less important and thus the pump efficiency can
be maximized.
Figure 7: General setup of a batch membrane filtration process.
20
4 Cheese making process
As previously mentioned, cheese dairies are a very likely receiver of farm-produced retentate.
Especially considering that part of the pre-treatment of the cheese-milk is standardization of cheese-
milk according to protein content in order to save space in the cheese vats. The process of cheese
making is however quite complex, and thus a thorough understanding of the chemistry related to the
processing steps is needed in order to accommodate changes that might occur due to the membrane
filtration. Milk can coagulate and form aggregates through different pathways: enzymatically, by
hydrolysing of κ-CN; acidification to the iso-electrical point of the CNs and by temperature (heat)
denaturation of the proteins (Walstra et al. 2006b). During modern cheese production, the
enzymatically pathway is most prevalent, but some cheese are also made purely by acidification. This
thesis will focus on the processes involved in the enzymatically induced coagulation.
4.1 Cheese production overview
When looking at factors that influences quality of cheese – that be texture, flavour and composition, the
pre-processing of the cheese milk will contribute to reflect on the final product. Depending on the exact
type of cheese, many of the processing steps differ slightly. However, the overall principal in cheese
making – and especially during large-scale production, will follow the procedure as described in this
chapter.
Heat treatment: The main purpose of heat treatment is to eliminate pathogenic bacteria. It will
however also eliminate non-pathogenic microorganisms and denature indigenous enzymes, which will
help control the characteristics of the final product. Another effect seen from heat treatment is the
restoration of the changes that happened during cold storage, even by high temperature, short time
pasteurization at 72ºC for 15 seconds (Walstra et al. 2006b). Spores are generally more resilient to
regular pasteurization. However, if the heat treatment is too intense, the ability to form a proper
coagulum will be reduced due to denaturation and absorption of β-CN and whey proteins to the surface
of κ-CN and thus shield from the enzymatic cleavage by rennet (McSweeney 2007). Traditionally,
21
chemicals such as NaNO3 and H2O2 have been added to prevent problems from spore forming bacteria.
Due to higher awareness, mechanical processes such as bacteofugation and microfiltration have
replaced this procedure (Champagne 1994; Saboya 2000).
Standardization: Cheese milk is often standardized according to fat content by separating the cream
from skim milk and recombine to the desired fat content. In modern cheese production, the protein
content will also be standardized by UF in order to utilize the capacity of the cheese vats. To ensure
sufficient amounts of calcium in the milk, a solution of CaCl2 is usually added (Sandra et al. 2012).
Acidification: The acidification of the cheese milk serves several purposes. It will inhibit bacteria that
might have survived the pasteurization, by changing the environment, but will also result in appropriate
conditions for the rennet enzyme. A low pH also advances the syneresis and helps to control the texture
of the cheese by influencing the Ca2+ balance. Acidification can be either direct by adding a food grade
acid to the cheese milk or indirect through starter culture. Direct acidification is more time efficient and
easy to control (Kosikowski and Mistry 1997), but will not contribution further to flavour formation.
Indirect acidification is more difficult to control compared to direct, but the indirect is often preferred
due to the role in flavour development during cheese ripening. When adding starter culture, the final
pH of the cheese curd is highly dependent on factors such as the specific species and strains in the
culture, cheese milk composition - especially concerning lactose content together with temperature and
time, all of which contribute to the acidification rate.
Addition of coagulant: When the appropriate pH is reached, the coagulant is added. The coagulation
mechanism of the first and second stage of the coagulation is further described in section 4.2. When the
milk has coagulated into a continuous gel structure, the syneresis of whey and further structural
rearrangement will start, and this step can be regarded the third coagulation stage(Lucey and Fox 1993;
Kosikowski and Mistry 1997). The rennet also plays a role during ripening, especially when the curd is
made from direct acidification where no starter culture is present to induce proteolysis and form other
flavour components (Harboe et al. 2010).
22
Cutting, stirring and pressing: Further processing of the cheese curd involves mechanical agitation to
accelerate the syneresis, and hereby regulate the water content of the cheese. Factors such as cheese
grain size, temperature and stirring time can all affect the syneresis: smaller cheese grains providing
larger surface area, higher temperature and stirring intensity will enhances syneresis. Pressing is the
final step of mechanically increased syneresis and promotes a structural rearrangement and
strengthening of the gel into a firm and durable mass (Walstra et al. 2006b).
Salting: Salt plays a large role in the final perception of the cheese, as it affects both flavour, texture
and starter culture profile during ripening and to some extend the water content. The desired salt
content depends on the characteristics of each cheese type, but recent studies have researched the
possibility to produce known cheese types with a reduced salt content due to health benefits
(Rulikowska et al. 2013; Murtaza et al. 2014).
4.2 Milk coagulation process
4.2.1 First stage
The first stage of the coagulation, also called the enzymatic stage, where κ-CN is hydrolysed into para
κ-CN, with the casein macro peptide (CMP) residue dispersed in the serum phase. This process
destabilizes the casein suspension by reduction of the electrostatic repulsion, enabling the casein
micelles to collide, aggregate and form a network structure. The hydrolysis can be described as a first
order reaction (Osintsev and Qvist 2004; Harboe et al. 2010). The enzyme commonly added to induce
milk coagulation is chymosin (EC 3.4.23.4). Chymosin, (referred to by the common name rennet) is an
aspartic protease endopeptidase, that has a very well defined and specific κ-CN cleavage site, making it
a very efficient coagulant, with limited protein loss (Whitaker 2002). Previously, the length of the first
coagulation stage was measured as the time from addition of rennet and until small aggregates were
visually observed (Lomholt et al. 1998). With modern analysis equipment such as LC, the first stage is
now evaluated by the concentration of CMP in the serum.
23
4.2.2 Second stage
Second stage is the actual aggregation of the remaining part of the casein micelles, when CMP has been
cleaved off. The second phase can be enabled when the electrostatic repulsion is sufficiently low, when
approximately 70% of the κ-casein has been hydrolysed (Sandra et al. 2012). A model based on
overcoming an energy barrier required for aggregation has been described by (Darling and van
Hooydonk 1981) and later confirmed by (Lomholt et al. 1998). The model suggests that hydrolysis of
CMP reduces the energy barrier, that otherwise would have been too high to form stable aggregates.
The driving force of the casein aggregation is mainly due to hydrophobic interactions and van der
Waals attraction, enabled by the loss of electrostatic repulsion. During the early phase of aggregation,
small casein clusters are formed. This will result in an initial viscosity decrease (Karlsson et al. 2007c).
These clusters will, subsequently, link together, until a continuous gel network is obtained, which is
then reflected as an storage modulus increase (Klandar et al. 2007).
4.2.3 The role of calcium
The casein micelle structure is held together by colloidal calcium phosphate (CCP) which consists of
3Ca3(PO4)2CaH citrate; Ca9(PO4)6; or CaHPO4٠2H2O. Thus, calcium plays an essential role during
cheese production, as it would not be possible to form a gel without (Lucey and Fox 1993). The
primary coagulation stage is considered independent of Ca, but due to ionic equilibria, addition of Ca2+
will decrease pH, and hereby indirectly cause an increase of the enzymatic reaction rate. This effect is
however mostly theoretical, as pH of the cheese milk is adjusted by other means during cheese
production (Sandra et al. 2012). During the second stage, calcium has a dual purpose; both by further
decreasing the electrostatic repulsion by neutralizing negative charges of the casein micelles and by
formation of calcium bridges, increasing the curd firmness (Mellema et al. 1999; Sandra et al. 2012).
The bovine milk calcium exist as an equilibrium between casein, bound as complexes in the serum
phase and as free Ca2+ ions. The distribution is temperature and pH dependent. Calcium will dissociate
from the casein micelles at low temperatures, and reverse when re-heating after cold storage. The
solubility of calcium increases at lower pH, leading to a higher concentration of calcium in the serum
phase (Mekmene et al. 2010; Malacarne et al. 2013; Koutina et al. 2014).
24
5 Milk powder
Worldwide the production of milk powder is very important, in order to provide the possibility of milk
to people without access to daily fresh milk. It also makes it possible to store milk for long time in a
convenient way, and hereby export it easily. Finally, milk powder is in many cases preferable in several
food productions, since it is easy to recombine according to special recipes. Milk powder is an obvious
usage of farm produced reverse osmosis retentate; but naturally, the quality must not be compromised.
Milk for powder production has to be of good quality, in order avoid off flavor and loss of functional
properties. Harsh heat treatment of the milk will cause whey proteins to denature, resulting in lower
solubility (Bylund 1995).
5.1 Milk powder manufacture
The most common way to produce milk powder is through spray drying and roller drying. The
principle in drying is to evaporating away the water so only the dry matters are left, by giving the milk
a very large surface area and apply to hot, dry air or surface. Roller drying is traditionally only used in
the chocolate industry, as it is associated to development of Maillard reaction, which is only desirable
in milk chocolate (Bylund 1995).
Spray drying can be performed in many steps and stages, in order to improve functional qualities and
save energy (Kessler, 2002). Many parameters will affect the final product quality: the construction of
the drying tower and atomizer nozzle, inlet air temperature, outlet temperature, air circulation, droplet
size, and air humidity. The state of the milk for drying is also very important. The quality depends on
temperature of feeding product, dry matter content, age thickening and flow into the dryer (Pisecky
1997).
Prior to drying, the milk is often pre-concentrated to about 50% dry matter. This saves energy (Kessler
2002) and may improve the powder quality (Kim et al. 2009; Lin and Chen 2009). The most common
method is by evaporation in a vacuum chamber (Kessler, 2002); however, this process can be partially
substituted by reverse osmosis. The milk concentrate is preheated and homogenized before spray dried.
25
The preheating provide optimal conditions for both homogenization and drying. Homogenizing the
milk ensures a better distribution of fat in the milk and herby better functional properties of the powder
(Kim et al. 2009). The milk concentrate is pumped through an atomizer nozzle, dried with hot air of e.
g. 200°C until the milk powder contains approximately 6% moist. Then the powder is cooled and
packed in appropriate containers (Bylund 1995).
In order to dry powder in an optimal way, it is necessary to choose the right inlet temperature, outlet
temperature, nozzle pressure and product flow. The aim is to get as high product yield as possible and
to dry the powder to an exact moisture content, without burning/browning the product and without the
product sticking to the surface of the drying chamber. The speed/pressure of the atomizer wheel as a
function of droplet size can also be estimated and fitted with the height of the drying chamber, in order
to calculate whether the droplets of a given size have time enough to dry on the way down the chamber
(Kessler 2002). Pisecky (1997)described that the smallest droplets may lose 90% of their water content
within the first 10 cm from leaving the atomizer, and the big droplets will need 1 m to lose the same
amount of water. If the droplets are too big, or the flow of the feed product to high, there may not be
time for all the water inside the particles to evaporate and they will stick to the surface and create
lumps. An increase in temperature can prevent this, but might then burn the particles. The adjustment
of these variables, is also influenced by air moisture and dry matter in the milk (Kessler 2002).
5.2 Milk powder quality
5.2.1 Powder composition and physical properties
Lactose has a major impact on the milk powder properties. It is desirable to keep the lactose in a glassy
state after drying. If the storage conditions give rise to entering a rubbery state of lactose and create
crystals, the quality of the milk powder will change dramatically depending on the specific situation,
and result in many contrary effects (Thomas et al. 2004). During crystallization, lactose alters the
structures of the powder particles, and creates capillary forms, that allow water to defuse into the
particle. At the same time, fat is expelled from inside the particles, and instead, create a water repelling
surface layer (Thomas et al. 2004; Kim et al. 2009).
26
Particle shape, size and agglomeration has a great influence on the final quality. Nijdam and Langrish
(2005) showed via electron micrographs scanning that particles dried at high temperatures are bigger
and have a smoother and round shape, compared to smaller, more wrinkled and shriveled particles
dried at lower temperatures. Due to the shape of the particles, they were able to pack closer together
and hereby give a higher bulk density.
Wettability is a measurement testing the powders ability to suck up water. Wettability is affected by
particle size and density, and can be improved with a lecithin treatment. It is the small capillary holes in
the powder particles that gives the ability to suck up water, or rather letting water cover all the surface
of the particles, so it can quickly be dissolved (Ji 2016). Whole milk powder normally has a lower
wettability than skim milk because of the higher fat content respells water (Pisecky 1997).
The solubility index gives a value of the amount of un-dissolvable particles in the milk, measured by
the volume of sediment after centrifuging. The most crucial factor controlling the solubility index
during drying is the particle temperature through the first drying state, until the moist content of the
particles is below 10%. In reality, the factors controlling the particle temperature is viscosity of the
milk, droplet size, outlet temperature and dry matter content of the milk (Pisecky 1997).
Bulk density is defined as the mass of a given volume of powder, after it has settled. It is directly
affected by the amount of air is trapped inside the powder particles, and the particles ability to pack
close together (Nijdam and Langrish 2005). Bulk density values are very important when it comes to
transport and storage of the powder. Bulk density is measured in g/ml, and a high bulk density means
that the powder does not take up much space according to the mass, which is often desirable. Nearly all
the production factors affect the bulk density (Pisecky 1997). A large difference in density between
before and after stamping is undesirable, since it will cause a larger amount of air on top of the product
after packaging. This takes up space and uses extra packing material for no use.
5.2.2 Storage stability
Enzymatic activity: As one of the advantages of milk powder is the excessive shelf life, the processes
that might occur during storage has to be controlled. Heat treatment of the milk as part of the pre-
27
processing during powder manufacture might not be enough to denature all indigenous enzymes. Since
microorganisms and enzymes require a certain water activity to function, the moisture content of the
milk powder can accelerate reaction and growths; Chen et al. (2003) described observations of
sensorial detectable FFA concentrations in whole milk powder with a water content of 3%. Likewise,
Celestino et al. (1997) showed that a certain level enzymatic activity occurred during storage of the
powder, that may impair the quality. They did however conclude that many of the products from
enzymatic activity originated from heat resilient microbial sources, and even from storage of the raw
milk. This emphasizes the role of raw milk quality in relation to the processes that leads to the final
product (Fonseca et al. 2013).
Oxidation: Another quality defect associated to milk powder storage is oxidation. Both proteins and
lipids may be subjected to oxidation, and in order to prevent this, much of the commercial powder is
sold in sealed packages with alternated atmosphere, as it will delay formation oxidation products
(Lloyd et al. 2009). The extend of oxidation in milk powder is largely influenced by the storage
conditions, powder moisture content and raw milk quality rather than e.g. fat and protein content of the
powder (Celestino et al. 1997; Stapelfeldt et al. 1997; Scheidegger et al. 2013). Oxidation has an
impact on consumer perception, as it will cause formation of off flavours (Romeu-Nadal et al. 2007)
rather than impair nutritional value (Zunin et al. 2015).
Maillard reaction: Formation of Maillard products is often a direct consequence of excessive heating.
During milk powder storage, the maillard reaction can however proceed at room temperature, and is
regarded a major quality flaw as it affects the powder visually, sensorial and nutritional, and the
reaction is further catalysed by storage temperature, pH and moisture content (Van Renterghem and De
Block 1996). The consequence of extensive Maillard is both sensorial through flavour and colour
changes, and nutritional as the lactosylated amino acids are less digestible (Thomas et al. 2004;
Dalsgaard et al. 2007). The maillard reaction is often referred to as non-enzymatic browning, but in
order to cause browning, the Maillard reaction has to be on a highly progressed level in the reaction
chain. Earlier stages of the Maillard reaction involves condensation of amine-carbonyl (reducing
sugars) groups and formation of Amadori compounds. During the intermediate stages, the sugars are
28
dehydrated and fragmented, and amino acids degraded (Strecker degredation). The browning occurs
during the final stages, where Aldol and aldehyde-amine condensates (Nursten 2005).
6. Summary of included papers
6.1 Paper I: Chemical Quality of Raw Milk Retentate processed by Ultra-filtration or
Reverse Osmosis at the Dairy Farm
6.1.1. Study objectives
The objective of this first study was to describe the extent of mechanical damage that RO and UF
would cause to raw milk, depending on variable processing factors: feed pressure, temperature,
concentration factor, pressure drop across the membrane and membrane spacer thickness. The
parameters for evaluating quality was MFG size distribution, concentration of FFA and extend of
proteolysis, as this is common factors for classifying raw milk quality. We anticipated that especially
the milk fat would be vulnerable to the mechanical process.
6.1.2 Experimental setup
The membrane filtration was organized as an in-line process, with milk poured straight from the AMS
milking line into the balance tank of the filtration plant. The milk was provided by Danish Cattle
Research Centre (Aarhus University – Foulum, Tjele, Denmark), where the filtration plant was
installed. Retentate samples were acquired after 30 minutes of processing, so the system had time to
stabilize and adapt when processing settings were changed. As the FFA values of the raw AMS milk
seemed quite high, it was decided to repeat the experiments using bulk tank milk from a herringbone
parlour milking system. The processing parameters that had no significant influence on retentate from
AMS were kept constant in order to reduce the number of experiments required to evaluate the impact
membrane filtration on parlour milk.
6.1.3 Summary of results
29
Raw AMS milk had an average FFA concentration of 1.38 mmol/100g fat. The FFA concentration of
UF retentate was not significantly different from raw milk. Changing the temperature from 5°C to 10°C
did not have any significant impact on the UF retentate, but a single experiment at 15°C did yield a
significant higher FFA concentration. A feed pressure increase from 0.15 Pa to 0.35 Pa resulted in a
FFA increase of 1.25 mmol/100g fat to 1.48 mmol/100g fat. No difference in MFG size distribution
was found between retentate and raw milk, and neither of the process settings had an impact.
FFA significantly decreased by 0.22 mmol/100 g fat, when the RO feed pressure was increased from
2.0 Pa to 3.0 Pa. By increasing the temperature from 4°C to 10°C the FFA concentration vas
significantly increased by 0.24 mmol/100 g fat. No increase in size distribution of the MFG was
observed during RO processing. Feed pressure had a significant influence on the concentration of
proteolytic products. When the feed pressure was increased from 20bar to 30bar, proteolysis increased
by 13.4%. Proteolysis increased by 23.4% when increasing the membrane spacer thickness from 30mil
to 48mil. Concentration factor did not have significant influence, however, a tendency was observed
toward higher level of proteolysis at 2 times concentration factor compared to 1.5 times concentration
factor. The raw milk from herringbone parlour milking system had an average FFA concentration of
0.580 mmol/100 g fat and a concentration of proteolytic products of 1.069 Leu-Equivalents [mM].
Neither FFA, MFG size distribution nor proteolysis increased significantly by RO filtration.
6.2 Paper II: Caseinomacropeptide release and rheological properties during rennet
coagulation of raw milk reverse osmosis retentate
6.2.1 Study objectives
The aim of this study was characterize the coagulation properties of RO retentate compared to raw
milk. The observed differences explained by including calcium distribution and the effect of varying
rennet concentration. Likewise, CMP release was included in order to determine whether the observed
changes were reflected in the first phase of the rennet coagulation process.
30
6.2.2 Experimental setup
For this study, in-line RO membrane filtration on fresh bulk tank milk from herringbone parlour
milking system was used. According to previous results presented in paper I, the processing
temperature was kept at 4ºC and the feed pressure was 3.0 Pa. Retentate of both 1.5 VCF and 2 VCF
was collected. All combinations of sample types and rennet concentrations (0.03, 0.04 and 0.05 IMCU)
were included included in the study. The rheological properties were recorded on both conventional
rheometer and ReoRox. Calcium distribution was characterized by measuring total calcium content of
both full samples and serum phase together with ionic calcium concentration.
The rennet kinetics was analysed by collecting samples at certain time points during the coagulation
process. Subsequently, LC was used to quantify the CMP concentration.
6.2.3 Summary of results
Retentate had a delayed RCT compared to raw milk, but the extent of this delay was dependent on
rennet concentration. Figure 8 shows rheological data during coagulation of raw milk, 1.5 VCF
retentate and 2 VCF retentate with a rennet concentration of 0.05 IMCU. At 0.05 IMCU, the retentate
samples exceeds the gel strength of raw milk, in spite of the longer RCT. The rennet kinetics were not
different when comparing retentate and raw milk, and the CMP concentration was purely dependent on
the ratio between rennet concentration and VCF, thus the enzyme: substrate ratio.
The calcium distribution changed by concentrating the milk (figure 9), so that a larger relative fraction
was located in the colloidal phase.
31
Figure 9: Distribution of calcium as % between colloidal, bound in the serum phase and ionic in raw milk and 1.5 VCF and 2 VCF RO retentate.
0.001
0.01
0.1
1
10
100
1000
0 5 10 15 20 25 30 35 40 45 50
log G' , Pa (elasticity)
Time, minutes
Raw
1.5 VCF
2 VCF
Figure 8: Elasticity during the formation of rennet induced coagulum of raw milk, 1.5 VCF and 2 VCF retentate with a rennet concentration of 0.05 IMCU.
32
6.3 Paper III: Storage stability of whole milk powder produced from raw milk reverse
osmosis retentate
6.3.1 Study objectives
The objective of this study was to evaluate whole milk powder made from 2 VCF RO retentate
compared to whole milk powder made from raw milk of the same heard. The powders would be
evaluated based on both functional and chemical properties during storage. Finally, the powder
properties were compared to a number of commercial reference powders.
6.3.2 Experimental setup
During this study, the raw milk was concentrated by a factor of two through a RO batch process, on
bulk tank milk from AMS, and sent to a spray drying pilot plant. Out of the same bulk tank, raw milk
was collected and sent for spray drying together with the retentate. The RO filtration process was
conducted at 4ºC with a feed pressure of 3.0 Pa. The entire process of making powder from retentate
and raw milk was duplicated on two subsequent days.
The milk powder samples were analysed based on composition, surface free-fat, insoluble particles and
particle size distribution, together with the storage stability attributes: proteolysis, oxidation, colour and
furosine, and compared to values found in commercial powders. The storage experiment was carried
out over the course to 12 months, with samples retrieved after 3, 6 and 12 months. The powder was
stored at room temperature in light sealed bags.
6.3.3 Summary of results
The powder composition had a lot of variation, that affected the results of the study (table 3), and thus
making it difficult to correlate the RO pre-concentration directly to the results. An increase in
concentration of oxidation products hexanal, heptanal and nonanal was found during storage (figure
10), but to a lower extend than the commercial reference sample. Proteolysis did not change during
storage, but different levels were generally found among the different powder samples, and the same
situation was reflected on the colour measurements. Furosine concentration was higher in powder
prepared from raw milk than in powder from pre-concentrated milk.
33
Table 3: Composition and physical characterization of small-scale powders produced from non-concentrated (Non-conc) raw milk and raw milk pre-concentrated (Conc) at the farm from reverse osmosis, on two subsequent days (1 and 2) of production; and several commercial reference samples (Ref.) – both instant and regular stored in bulk bags for up to 12 months and two reference powders stored in sealed bags with altered air composition
Figure 10: Oxidation products found in powders produced from non-concentrated (Non-conc) raw milk and pre-concentrated (Conc) raw milk manufactured on a pilot-scale spray drier, compared to a commercial reference (Ref) sample. A: hexanal concentration during storage. B: heptanal concentration during storage. C: nonanal concentration during storage. The error bars show the standard deviation found between the samples of same type.
00
50
100
150
200
0 3 6 12
Hex
anal
ng/
100m
g sa
mpl
e
Storage time / months
A
00
05
10
15
20
25
30
0 3 6 12
Hep
tana
l ng
/100
mg
sam
ple
Storage time / months
B
Non‐conc Conc Ref
00
02
04
06
08
10
12
0 3 6 12
Non
anal
ng/
100m
g sa
mpl
e
Storage time / months
C
Composition Particle size distribution Fat
% Protein % Water % Surface fat g/100 g fat
Insoluble particles ≥ 630 µm
630-400 µm ≤ 400 µm
Raw 1 17.81 30.78 3.55 0.17 0.2 0.20 1.20 98.60
Conc 1 29.89 26.47 2.17 1.57 0.2 0.90 2.20 96.90
Raw 2 21.89 29.29 2.81 0.85 0.1 0.58 1.00 98.42
Conc 2 31.00 26.26 1.87 2.59 0.2 0.26 1.82 97.92
Ref. regular fresh 28.24 23.63 3.17 0.99 0.1 0.30 53.19 46.52
Ref. regular 12mth 27.97 23.45 3.38 0.83 0.1 0.16 37.36 62.48
Ref. instant 6mth 26.47 26.89 3.31 1.14 0.1 4.49 64.22 31.29
Ref. instant fresh 27.91 23.97 2.71 1.49 0.1 2.30 83.21 14.49
Ref. regular 3mth 25.76 24.17 3.04 0.88 0.1 0.20 44.10 55.70
Ref instant sealed 12mth 28.36 23.54 2.85 1.70 0.1 0.98 68.98 30.04
Ref regular sealed 12mth 26.34 23.99 3.22 1.64 0.1 0.52 6.13 93.35
34
7. General discussion
This thesis has sought to uncover the extend of witch concentrating milk at the farm might affect the
milk quality (Paper I). Moreover, as the retentate is intended for further processing into e.g. cheese or
milk powder, the consequences of pre concentrating needs to be understood in relation to product
quality as well (Paper II and III). The following chapter seeks to discuss to what extend concentrating
milk at the farm will, in itself, affect the quality of milk and milk product when considering the whole
production chain, and thereby put the topic of this thesis into perspective.
The overall results found in Paper I reinforces the importance of raw milk quality, especially
concerning the processing steps of the primary production. The focus was on the mechanical treatment
from membrane filtration; however, the results showed very clearly that factors such as choice of
milking equipment had a bigger influence on the final level of FFA than the membrane filtration.
Lipolysis and the resulting FFA emission is highly unwanted due to off flavour formation, with a
sensorial detection threshold of 0.250 meq of FFA/kg milk (Santos et al. 2003). Several studies have
reported an increased in FFA concentration when converting to AMS from a conventional system.
Klungel et al. (2000) reported an average increase in FFA concentration from 0.38 to 0.53 mmol FFA /
100 g fat, together with an increased level of CFU / ml. Abeni et al. (2005) found a difference of FFA
between parlour milking system and AMS from 0.51 to 0.72 mmol FFA / 100 g fat. These results are in
line with the observations we made on the raw milk in Paper I, before subjection to membrane
filtration. The difference between AMS and conventional milking systems can be assigned to milking
frequency, pumping (mechanical agitation) and air intake due to vacuum in the suction cups
(Rasmussen et al. 2006). Bulk tank storage is another factor that can indeed influence the raw milk
quality. Wiking and Bjerring (2010) described how the cooling efficiency has an impact on the FFA
concentration. In order to prevent increased lipase activity, the milk has to be immediately cooled to
4ºC, and mixing in of warm milk should be avoided. If the milk is cooled too severely, with local areas
of freezing, the MFGM will be damaged, resulting in promoted lipolysis. Stirring in the bulk tank
should, if possible, be prevented until the milk is sufficiently cooled.
35
Bhavadasan et al. (1982) observed that aggregation of milk at 15 ºC increased lipolysis compared to
aggregation at 10 and 20 ºC. An explanation as to why the MFG are more subjectable to lipolysis is due
to a combination of factors. At lower temperatures, the MFG contains a larger fraction of solid fat,
which has a stabilizing effect on the globule, and thus prevents shearing of the MFGM. At higher
temperatures, e.g. 20 ºC, the TAG inside the MFGM are mostly at a liquid stage, allowing the MFG
and MFGM to be flexible and adapt the shape rather than tear apart during mechanical treatment.
However, at 15 ºC, the ratio between liquid and crystalline TAG compromises both stability and
flexibility, making the MFGM highly subjectable to aggregation (Lopez 2011). Another aspect of the
LPL activity during cooling is the changes in MFGM associated proteins. LPL is synthesis into the
milk in association with the casein micelles. Dickow et al. (2011) showed that cooling of milk led to a
migration of proteins from the skim milk phase to the cream phase, and to instability of the MFGM
proteins. This is thought to cause enhanced attachment of LPL to the MFGM and subsequently lead to
increased LPL substrate availability, and hence, more hydrolysis of TGA to FFA.
As the AMS milk used during the experiments of Paper I was collected directly from the milking line,
and cooled in the plate heat-exchanger on the membrane filtration plant, the raw milk had been
subjected to further pumping while still warm, compared to the milk from the parlour milking system,
that had been collected cold from the bulk tank. This might bias the results towards higher FFA
concentration in the retentate from AMS.
One of the initial concerns related to concentrating milk at the farm was the lack of pasteurization of
the milk prior to the membrane filtration. It was speculated, whether this would give rise to microbial
growth, through e.g. biofilm formation. As reported by Klungel et al. (2000), AMS caused an increase
in CFU levels compared to conventional milking systems, and it is natural to think that more complex
processing equipment, such as a filtration plant, requires more awareness in order to secure a hygienic
process (Cleto et al. 2012). As part of unpublished experiments in this thesis (Appendix 2), samples
were collected during the bulk filtration process, and compared to the levels found in the raw milk for
microbial analysis. Results showed that 2 VCF retentate contained an average of 4500 CFU/ml after 12
hours of batch processing time compared to a raw milk starting value of 3000 CFU/ml. Thus, the
microbial load was lower than the concentration factor. The experiment was later repeated with similar
36
conclusion. Whether the result was due to the filtration process conditions caused the microorganisms
to lyse or cluster together, and hereby obscuring the CFU count is not clear. Almeida et al. (2014)
showed that the bacterial clustering was affected by shear stress during growth, and cultures exposed to
shear during long periods yielded a higher number of clusters containing few individual bacteria. This
contradicts the results from this unpublished study, but may support the theory of rupturing and lysing.
It was decided not to research more on this topic, as the result was sufficient to discard the concern of
microbial growth.
The impact of mechanical treatment caused by the membrane filtration might also be highly dependent
on the milk composition and other factors related to the cow. Wiking et al. (2003) and (2004) reported
a connection between cow diet and increased milk fat content; and how that lead to an increase in MFG
size that made them more unstable during pumping. Diet is however not the only cause of changes to
MFG size and fat yield. Jersey cows have a higher fat yield and subsequently larger MFGs (Schwendel
et al. 2015). They are also reported to have a higher concentration of de novo synthesized fatty acids
(Carroll et al. 2006); witch in total may result in MFGs that are less resistant to pumping.
During studies as part of the present PhD project, SCC was recorded (Appendix 1) with the intention
of making a possible correlation to other quality parameters to raw milk retentate, like lipolysis and
proteolysis. The levels found in raw milk were very low with an average of 148000 cells/ml, compared
to the study by Klungel et al. (2000), who reported levels of 220000 cells/ml. The retentate had a
surprisingly low number, compared to raw milk, with 125000 cells/ml in 1.5 VCF retentate and 47000
cells/ml in 2 VCF retentate. These results indicate that the membrane filtration process might disrupt as
least a sub-population of the cells. This brings a concern as to enzymes being released due to SCC
disruption by the filtration process and thereby potentially causing a higher level of enzymatic
degradation of lipids and proteins after concentrating the milk. Experiments on storage of retentate did
not result in presence of higher concentrations of peptides compared to raw milk. It was concluded that
the initial level of SCC was too low to give a significant effect, and the results were not included in
either of the published papers. Thus, when evaluating the retentate quality based on common factors for
evaluating raw milk quality it seems that the membrane filtration is not of any concern compared to
37
how other factors and processing steps during the primary milk production. Provided, that the raw milk
is of high quality, no negative effect of pre-concentrating is found.
Based on the results from Paper I there was no concern of the retentate quality. Since the retentate was
intended for further processing, it was however still necessary to ensure that e.g. cheese making
properties had not been impaired (Paper II). Attributes linked to farm management, cow breed
(Frederiksen et al. 2011) and state of lactation are known to have an impact on the coagulation
properties. The major reason is milk composition changes, which in different ways affect the
coagulation process through genetic variants of proteins (Jensen et al. 2012; Jensen et al. 2015; Poulsen
et al. 2015), casein:protein ratio and SCC (Sorensen et al. 2008). The major difference between raw
milk and RO retentate is the composition. Even though the results from Paper I showed that it is
possible to make RO retentate without increased proteolysis and damage to fat globules, the cheese
making properties of milk is highly dependent on other factors such as calcium distribution.
Experiments showed that the rennet coagulation was indeed affected by the RO pre-processing. Further
studies reviled that the observed delay in rennet coagulation time was mostly linked to changes to the
ration between rennet concentration and protein content. RO retentate coagulum reached a higher
storage modulus than raw milk coagulum, suggesting that other factors than enzyme to substrate ratio
influences the coagulation process. This difference was not reflected on the CMP release, so the results
could not be ascribed to the first phase of the coagulation process. These observations are completely in
line with observations made by Sharma et al. (1993) on UF retentate, and Karlsson et al. (2007c)
assigned the more rapid curd firming rate to the decreased distance between casein micelles and
thereby more sensitive to the electrostatic charges. So is seems that in spite of significant changes to the
calcium distribution, the RO coagulation properties are very similar to those of UF.
As the RO process concentrates the minerals of the milk, the entire mineral and ionic equilibrium will
be changed. Paper II focused on changes to the Ca distribution, but other salts are likewise
concentrated. Studies have shown that addition NaCl to milk prior to rennet-induced coagulation, lead
to increased RCT and lower gel firmness (Karlsson et al. 2007a; Sameh 2007). It has not been possible
to make a direct correlation to the effect of NaCl concentration, and general ionic strength, during our
38
studies of RO retentate coagulation properties. This is a topic that could be relevant during further
studies.
As an on-farm membrane filtration technology, UF is generally not a recommendable option due to
issues of permeate handling. The effects of mechanical treatment were not different from RO (Paper
I), and will result in other issues such as loss of lactose and subsequently handling of the permeate. The
best solution to the question of handling UF permeate, retain lactose and account for the total energy
and cost balance compared to RO is still not found. UF can in some situations be preferred over RO
with regards to standardization during e.g. cheese production, as it leads to a reduced lactose content in
the retentate. The lactose concentration will affect the acidification rate during indirect acidification, as
lactose is the primary substrate for the starter culture producing lactic acid (Moynihan et al. 2016). The
starter culture will be inhibited at approximately pH 4.4. For semi hard cheeses it is however not
desired to reach a pH below 5.25, as it will have a negative impact on flavour and texture (Nielsen
2004). Part of the lactose will be expelled into the whey, but more lactose will also be retained in the
cheese curd when the initial lactose concentration is high (Moynihan et al. 2016). This will result in
net-loss of lactose into the cheese that could have been utilized, and lead to concerns about the quality
of the final cheese. In a situation where the majority of the milk consists of RO retentate, it could be
imagined a need to dia-filtrate the retentate to reduce the lactose content. This would however be a
disadvantage regarding energy consumption, and thus not a desired situation.
Viscosity of 2 VCF RO retentate was measured during cold storage for 3 days (Appendix 3) to ensure
that no age thickening occurred. The viscosity did not change over time and the results were very much
in line as what would be expected concerning the dry matter content (Carr 1999). It was therefor
decided to end further experiments on this subject. Experiments on skimming RO retentate was
conducted (Appendix 4), both in laboratory scale and on a pilot scale centrifuge. It was hypothesized
that concentrated milk would be difficult to skim properly without a remaining fat fraction in the skin
milk. The results showed that the fat was properly removed from the skim milk, but the cream had
increased protein content. This could potentially cause problems due to loss of protein. In order to
avoid this, the cream can be washed and re-centrifuged; this is however contradictory to the purpose of
saving resources through concentrating milk at the farm. Thus, it should be considered to utilize the
39
raw milk retentate for purposes that does not require skimming, or alternatively mix it with un-
concentrated raw milk in the dairy bulk tank to limit the issue.
Finally, the utilization of RO retentate was evaluated as a raw material for production of whole milk
powder (Paper III). Milk powder is a highly complex subject, as the production involves several
quality defining process steps. It is of utter most importance that the raw milk is of prime quality, since
quality defects at this stage will transfer to the final product. Based on the results seen in Paper I, it
was expected that the powder from RO retentate would be able of equal quality to powder made from
raw milk. The study did however not progress as expected, as other processing factors dominated the
intention of the study. This only emphasized that the concept of pre-concentrating raw milk at the farm
did not affect the raw material enough to be the main factor regarding quality defects.
There are two aspect of milk powder quality: the functional properties that influences how easy the
powder is to handle – both at the dairy and at the consumer, and the chemical quality witch might affect
the nutritional value and flavour. Handling of the raw milk prior to spray drying will naturally
contribute to the final quality. Storage of the raw milk should not exceed 3 days at 4ºC, as problems
with microbial growth may arise causing increased lipolysis and proteolysis (Celestino et al. 1997;
Fonseca et al. 2013). Unpublished data collected during this thesis showed that cold storage of retentate
for 3 days did not cause elevated levels of proteolysis, but microbial growth during storage remains a
severe concern point. Before the milk enters the spray drier, it is common to concentrate the milk to a
dry matter content of approximately 50 % as it reduces overall energy consumption and leads to
powder particles with better technical properties (Westergaard 2004). This process is normally done by
evaporation (Singh 2007), and the idea was to substitute part of this procedure by RO processing at the
farm. A study by Liu et al. (2012) describes that evaporation of milk caused changes to the ionic
equilibrium of e.g. calcium distribution and pH decrease in accordance to our findings on RO
membrane filtration (paper II). And even though evaporation is usually conducted at elevated
temperatures, the whey proteins were not subjected to denaturation (Singh 2007). It is a common issue
that the concentrated milk undergoes age thickening (Zisu et al. 2013), which causes fouling problems
during spray drying (Westergaard 2004). Age thickening is caused by casein aggregation, which are
dependent on the soluble minerals (Bienvenue et al. 2003). We had concerns that pre-concentrating
40
milk at the farm might lead to increased age thickening, due to storage of the retentate, and thereby a
longer period of changed ionic balances as observed in Paper II. This was however not observed
during the experiments.
Storage stability of milk powder is a great concern, as this is affected by temperature and air humidity
(Fitzpatrick et al. 2004) – conditions that seen problematic for locations where consumption of milk
powder rather than raw milk is prevalent. Increased temperature and air moisture will accelerate
oxidation and formation of maillard products, but the powder composition does also contribute to the
storage stability as was described in Paper III. Generally, powder with a high fat content is more
subjectable to oxidation. A study from Páez et al. (2006) described variation due to season, and
Romeu-Nadal et al. (2007) observed that a high content of unsaturated fatty acids lead to a decrease in
oxidative stability. Through proper handling of the raw milk retentate, storage stability should not be
impaired. We found no evidence of changes to the milk components that might result in decreased
storage stability as a result of on-farm RO.
41
8. Conclusion
The aim of this study was to identify whether concentrating milk at the farm would impair the retentate
quality, both concerning the mechanical treatment and possible damage during storage, caused by
enzymes being equally concentrated. Moreover, the process-ability of the retentate into cheese and
powder had to be studied to get a full understanding of the consequences of concentrating milk at the
farm.
The study of paper 1 showed that high feed pressure and low temperature during the filtration process
had a slight, but significant effect on limiting the development of FFA in RO retentate. Proteolysis of
the RO retentate was affected by feed pressure and membrane spacer thickness. However, when
changing the origin of raw milk from AMS to parlour milking system, none of the processing
parameters had any significant influence on the emission of FFA. The FFA concentration in the raw
parlour milk was significantly lower that the raw milk from AMS, and there was no increase in FFA
concentration between raw parlour milk and the RO retentate after 24 hours storage. Thus, it appears
that the milking system had more impact on the milk quality than the subsequent membrane filtration,
and milk from AMS was predisposed for further damage by the filtration process. Studies comparing
retentate quality between RO and UF showed no advantage of using UF. Therefor UF was not included
in further studies.
Studies on rennet coagulation properties showed that RO retentate had a longer RCT compared to raw
milk, but the curd-firming rate was higher. The cause of this observation was studied by including the
chymosin reaction rate and calcium distribution. Based on measurements of CMP concentration during
the coagulation process it was observed that the delay of gelation was due to the enzyme:substrate ratio
in the samples during the first phase of the coagulation. This transferred to the results of rennet
coagulation time. The increase in curd firming rate was speculated to be due to shorter distance
between casein micelles and thus higher electrostatic attraction. The calcium distribution changed by
RO filtration, so that a larger fraction of the total calcium content was incorporated into the casein
micelles and the retentate contained relatively less ionic calcium. This resulted in a pH decrease.
42
Changes to calcium and ionic balances might also bear part of the explanation behind the increased
curd firming rate.
Whole milk powder produced form RO retentate compared to powder from raw milk that had not been
pre-concentrated prior to evaporation, showed no direct difference in storage stability. Unfortunately,
during afterwards handling of the milk and retentate, the composition of the two samples were very
different – possibly due to insufficient stirring during storage. To compensate for this, all the powder
analysis were compared to commercial whole milk powder samples. The conclusion was that pre-
concentrating milk at the farm did not lead to and quality or storage defects, as the overall whole milk
powder composition had a much larger impact.
All the studies, that have been part of this thesis, shows no clear disadvantage of performing RO
membrane filtration as a method of concentrating milk at the farm. During all situations, other factors
such as milking system and exact sample composition seem to have a larger influence on the final
product, than the filtration process itself. Changes to the ionic balances was the biggest effect derived
from RO processing, and this aspect has to be considered during further processing, and certain
production steps during e.g. cheese manufacture might have to be revised.
43
9. Perspectives
The objective of this thesis has been the aspects of retentate quality, but the studies are however only
part of a much larger project about implementing membrane filtration in the dairy farms. Project groups
within Arla have focused on the business case and legislation.
In Denmark, the Veterinary and Food Administration require the farm to obtain status as a dairy in
order to process the milk in any other way than milking and cooling. In order for the farm to gain
permission to concentrate the milk through membrane filtration, the legislation has to be reworded and
new rules added. This process is very time and resource consuming, as the food safety has to be
thoroughly documented and the exact circumstances regarding the filtration technology has to be
formulated.
From the farmers’ perspective, an agreement has to be made regarding costs of filtration equipment,
maintenance and value of the milk. Several suggestions have been made:
The dairy owns and maintains the equipment, the farmer is payed the regular raw milk value
and a compensation from the dairy.
The farmer buys the filtration equipment and becomes certified to conduct maintenance, and
in return is given higher value of the concentrated milk.
The farmer leases the filtration equipment, is not responsible for service and maintenance,
and given a higher value for the concentrated milk.
The implementation model has to be agreed upon between the dairies and farmer, based on
recommendations from the authorities.
The business case on the feasibility of farm membrane filtration was based on whole milk powder
production, comparing 2 VCF RO retentate to values known from standard production, using regular
raw milk. Expenses from all the process steps, including cleaning, were included in the calculations.
The end result showed that in order for the membrane filtration at the farm to give a positive
economical outcome, the dairy farm must be of a certain size depending on the distance to the dairy.
However, the combination of farm size and dairy distance exceeds the conditions found in Denmark. It
44
was thus concluded that, in Denmark, the business case would be negative, and there for the technology
was not recommended for implementation. The main factor leading to this conclusion was the principle
of smaller plant not utilizing the energy and capacity well enough compared to large scale production
plants. The data for energy consumption were based on values recorded during experiments conducted
during studies of this thesis. Based on the overall conclusion of the business case it was decided not to
spend further resources on this matter. Nevertheless, the technology is still applicable in other
countries, which are known to have far greater distances between farm and dairy. Thus, the positive
results from the studies of this thesis are still useful knowledge in regards to membrane filtration – both
on farm and dairy.
45
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Paper I
Chemical Quality of Raw Milk Retentate processed by Ultra-filtration or Reverse Osmosis
at the Dairy Farm
Ida Sørensen, Søren Jensen, Niels Ottosen, Tommas Neve & Lars Wiking
International Journal of Dairy technology, February 2016, Volume 69, Issue 1, Page 31-37
Errata
The second paragraph beginning on page 34, first column, should have said:
The concentration of FFA in nonfiltrated milk was 1.19 mmol/100 g fat, and the ultra-filtrated milk
ranged from 0.98 mmol/100 g fat to 2.12 mmol/100 g FFA (Table 2), which was an overall
nonsignificant difference.
ORIGINALRESEARCH Chemical Quality of Raw Milk Retentate processed by
Ultra-filtration or Reverse Osmosis at the Dairy Farm
IDA SØRENSEN,1 SØREN JENSEN,2 NIELS OTTOSEN,2 TOMMASNEVE3 and LARS WIKING1*1Department of Food Science, Aarhus University, Blichers All�e 20, DK-8830 Tjele, 2Arla Foods Ingredients GroupP/S, Sønderupvej 26, DK-6920 Videbæk, and 3Arla Foods, Arla Strategic Innovation Centre, Roerdrumvej 10,DK-8820 Brabrand, Denmark
Concentrating raw milk at the dairy farms – rather than at the dairy – reduces energy consumptionand CO2 emission, due to less road transportation of the milk. This study demonstrates whether itis possible to use either reverse osmosis or ultra-filtration for milk concentration at the farm with-out harming the milk quality, regarding lipolysis and proteolysis. Filtration at low temperature(4 °C) secures a good milk quality. Despite reverse osmosis operating at much higher feed pres-sures, the effect on lipolysis is small, which makes this technology the most applicable, as lactose iswithhold in retentate.
Keywords Lipolysis, Free fatty acids, Proteolysis, Milk fat globule, milking system, mechanicalstress.
INTRODUCTION
During the production of several dairy productssuch as milk powder, cheese and yoghurts, aconcentration test for the milk is conducted atthe dairy, to increase the protein content of themilk. It would be beneficial if part of this con-centration can occur at the farm, so transportand cooling as well as CO2 emission can bereduced. Additionally, the water withdrawn fromthe milk may be reused at the farm. However,the impact on the milk quality is needed to bestudied, as it is yet unknown how the processinfluences the milk quality.To overcome the hydraulic resistance of the
membrane and possible fouling cake layer, acertain feed pressure is needed. The retentateflux is a result of a combination of membranespacer size, product viscosity – due to, forexample, concentration factor and temperature –and feed pressure. The retentate flux may, how-ever, decrease over time as fouling layer buildsup (Kessler 2002; Walstra et al. 2006). Mem-brane filtration at farms is known to be used inthe United States, Australia and New Zealand,and several early studies conclude that analysisof concentration of raw milk is possible, but thismight impact the milk quality. The exact mecha-
nisms are, however, not well documented (Zall1984; Kelly 1987; Garcia and Medina 1988).More effort has generally been to study and pre-vent membrane fouling (Slack et al. 1982;Brans et al. 2004), and fractionation of the vari-ous milk compounds (Tolkach and Kulozik2005; Piry et al. 2008; Toro-Sierra et al. 2011).de Boer and Nooy (1980) arrived at some ideasregarding the methods of concentration of milkat the farm. They mention that reverse osmosis(RO) might be a better option compared toultra-filtration (UF), as UF changes the composi-tion of the milk and hereby makes use of theretentate less versatile in the dairy industry –even though RO processing requires moreenergy. They tested whether temperature andstorage would influence the level of free fattyacids in the retentate and found that processingtemperatures below 7.5 °C are most preserving.The challenges related to concentrating raw milkis to maintain a high quality, while running themembrane filtration plant at a pressure, highenough to prevent fouling. Kelly (1987)expressed his concern in this issue stating thatthe fouling effect would be greater in raw milkthan in skim milk, causing a higher pressuredrop through the membrane and a decreasedflow. High-pressure pumping and general
*Author forcorrespondence. E-mail:[email protected]
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doi: 10.1111/1471-0307.12296
mechanical treatment of the milk may very well cause dam-age to the milk fat globules (MFGs) (Wiking et al. 2003;Fuc�a et al. 2013).The disruption of the milk fat globule membrane
(MFGM) is known to increase the level of lipolysis, as thetriglycerides inside of the MFG are more reachable to thenative lipase present in milk. High levels of free fatty acidwill cause off flavour, and this fact is regarded as a qualitydefect. The enzymes and bacteria present in the milk will beconcentrated as well, so the risk of compromising the milkquality is likely. Plasmin and other proteolytic enzymesmay react differently in the concentrated milk, resulting in amore unpredictable cleaving pattern and kinetics. Thehydrolysis of b-casein and as2-casein by plasmin will causechanges in texture and flavour, together with loss in cheeseyield (Bastian and Brown 1996). However, the extent andmechanisms of the mechanical stress and enzymatic damageof the raw milk related to concentration, as well as theimpact on further processing of the retentate into, for exam-ple, milk powder, are not known.The aim of this study was to examine whether concentrat-
ing raw milk at the farm could be performed without qualitydeteriorations. It was tested whether membrane type (UF orRO), membrane spacer thickness, feed pressure, pressuredrop, volume concentration factor and temperature affectedthe concentration of free fatty acids, MFG size distributionand extent of proteolysis. The hypothesis is that the changein viscosity and distance between particles and enzymes inthe concentrated raw milk will change the kinetics andcleavage patterns of the native lipases and proteases. Thismay influence the shelf life of the milk as well at the pro-cessing ability.
MATERIALS AND METHODS
Raw material and equipmentThe raw milk was produced at the Danish Cattle ResearchCentre (Aarhus University – Foulum, Tjele, Denmark).Mainly milk from Danish Holstein cows was used, but for
the UF experiments, some Jersey milk had been mixed in.The membrane filtration plant was developed by GEA Pro-cess Engineering (Skanderborg, Denmark) and designed, soit would be appropriate for daily production on a farm of250 cows. The cows were milked by automatic milking sys-tem (AMS). The membrane filtration plant was designed asan inline process, where milk was added to the filtrationplant between the milking robot and the bulk tank. Milkfrom one robotic milking line was collected in a mobilecontainer and poured into the balance tank. There was nocooling of the milk prior to the plate heat exchanger of thefiltration plant; however, the milk was transferred directly tothe filtration plant. The process flowchart is shown in Fig-ure 1. Additionally, RO experiments were conducted onmilk from a farm with herringbone parlour milking (HPM)system, where the milk was collected from a bulk tank.The membranes of both UF and RO were 3.8″ pHt spiral
wound with either 30 mil or 48 mil spacer and were pro-duced by Alfa Laval (Lund, Sweden). The total membranesurface area per module for the 30 mil membrane was 6.3and 4.7 m2 for the 48 mil membrane.
Experimental set-upThe experiments were conducted, so many of the combina-tions of settings on the filtration plant have been includedand repeated. The settings were feed pressure, pressure dropacross the membrane, temperature, volume concentration fac-tor and membrane spacer size. Combinations of settings isshown in Table 1. The order of the various experiments waschosen mainly from a practical aspect and was therefore notcompletely random. For each day, with new experiments, 2–3 different setting combinations were conducted. For eachexperiment, samples of both retentate and raw milk were col-lected. During UF, samples of permeate were likewise col-lected to monitor the process. For the HPM bulk milk,pressure drop was at about 0.08 MPa, volume concentrationfactor (VCF) was two times the concentration, and the mem-brane spacer was 48 mil, so only feed pressure and tempera-ture varied. The temperature was either 4 °C or 7 °C.
Figure 1 Flowchart of the filtration plant setup connected to the automatic milking system. The balance tank, plate heat exchanger and membranemodule are assembled into the filtration plant unit. All the changes of settings related to this study were done through pumps and valves, on the filtra-tion plant unit.
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Milk compositionThe overall composition of the retentate and unfiltrated milkwas measured by FT-IR (MilkoScan FT2, Foss, Hillerød,Denmark). Both samples of retentate and raw milk weremeasured, together with UF permeate. The componentsmeasured by FT-IR were dry matter, fat, protein, lactose,casein and solids’ nonfat.
Analysis of free fatty acids (FFA)To determine the concentration of FFA, samples of bothretentate and raw milk were sent to Eurofins Laboratories(Vejen, Denmark), which used the Bureau of Dairy Industries(BDI) method (IDF 1991). The samples were left at 4 °C for24 h after production, in order for the lipolysis activity to behigh (Wiking et al. 2002). Afterwards, the samples were pas-teurised within the 500-ml plastic bottles where the sampleswere collected in. The pasteurisation process was conductedby applying the bottled samples to a 71 °C water bath for40 min. Immediately after pasteurisation, the samples werestored at �18 °C, until analysed at Eurofins.
MFG size distributionMilk fat globule size distributions were determined by laserlight scattering (Mastersizer2000, Malvern Instruments) asdescribed by Wiking et al. (2003), immediately after thesamples were collected.
Analysis for proteolysisSamples of both RO retentate and unconcentrated milk werestores at 5 °C for 3 days before the start of the analysis.This was performed to ensure that the plasmin activitywould be at its highest. The assay is based on a reactionbetween free N-terminals of amino acids or peptides andfluorescamine, which will become fluorescent and detectableon a fluorometer. The exact experimental procedure isdescribed in the study by Wiking et al. (2002). Measure-ments were conducted in triplicate on a multiplate reader(BioTek Synergy 2, Holm & Halby, Brøndby, Denmark),and the results were obtained by Gen5 1.07.5 software (Bio-Tek Instruments, Winooski, VT, USA).
StatisticsAll the statistical calculations have been made with the free-ware program R 3.0.1 (R Foundation for Statistical Comput-ing, Vienna, Austria). The applied analyses were t-test,paired t-test and analysis of variance.
RESULTS
Ultra-filtration experimentsUsing ultra-filtration membranes, larger particles such asmicro-organisms, fat and proteins are retained in the retentatephase, whereas lactose, minerals and water distribute evenlybetween retentate and permeate. The milk was added into the
Table 1 Combinations of membrane filtration process settings usedfor the UF and RO experiments
UF of milk from AMS
Membranespacer, mil
Feedpressure, MPa
Temperature,°C VCF
Pressuredrop, MPa n
30 0.15 4 1.5 0.12 20.08 2
10 2 0.12 21.5 0.08 1
0.35 4 1.5 0.12 12 0.12 2
10 2 0.12 215 0.12 2
48 0.15 4 1.5 0.12 10.08 1
2 0.12 110 1.5 0.12 1
0.08 10.35 4 1.5 0.12 1
RO of milk from herringbone parlour milking system
48 2 4 2 0.08 17 1
3 4 37 3
RO of milk from AMS
30 2 4 1.5 0.12 20.08 2
2 0.12 20.08 2
10 1.5 0.12 10.08 1
2 0.12 20.08 1
3 4 1.5 0.12 10.08 1
2 0.12 20.08 1
48 2 4 1.5 0.12 30.08 3
2 0.12 210 1.5 0.12 2
0.08 22 0.12 2
0.08 23 4 1.5 0.12 2
0.08 22 0.12 2
0.08 210 1.5 0.12 1
0.08 22 0.12 1
0.08 2
n, number of replicates; R, reverse osmosis; UF, ultra-filtration.
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filtration plant directly from the automatic milking, as aninline system. The process settings – feed pressure, processtemperature, concentration factor, pressure drop across themembrane and membrane spacer thickness – were tested forinfluence on the retentate condition. The concentration ofFFA in nonfiltrated milk was 1.38 mmol/100 g fat, and theultra-filtrated milk ranged from 0.98 mmol/100 g fat to2.12 mmol/100 g FFA (Table 2), which was an overall non-significant difference. Likewise, no effect on the UF processparameters VCF and pressure drop was observed (Table 2).An effect on processing temperature was found, that is noeffect between 5 and 10 °C was observed, but processing at15 °C produced retentate with a large concentration of FFA(only a single experiment was conducted at the high tempera-ture). Retentate produced with a feed pressure of 0.35 MPacontained a significant greater concentration of FFA(1.48 mmol/100 g fat) than the retentate produced at 0.15MPa(1.25 mmol/100 g fat). MFG size distribution showed no sig-nificant difference between retentate and nonfiltrated milk, andnone of the process settings had an impact (Table 2).
Reverse osmosis experiments
Reverse osmosis filtration in combination with automaticmilking systemsIn RO membranes, only water and small minerals, such asurea can be pressured through the membrane as permeate.Similar to the UF experiment, the filtration system was aninline process from AMS. By increasing the feed pressurefrom 2 to 3 MPa, FFA significantly decreased by0.22 mmol/100 g fat (Table 3). Also, processing tempera-ture significant influenced the concentration of FFA. Anincrease in temperature from 4 to 10 °C increased the FFAconcentration by 0.24 mmol/100 g fat. None of the otherfiltration plant settings influenced the concentration of FFAin the retentate. The size distribution of the MFG was notchanged significantly (P > 0.05) during RO processing(Table 3). About 72 h after milking, the level of proteolysis
in the retentate showed a significant influence on feed pres-sure. By increasing the feed pressure from 2 to 3 MPa,proteolysis increased by 13.4%. Membrane spacer thicknesshad a significant (P = 0.003) influence on proteolysis, andby increasing the membrane spacer thickness from 30 to 48mm, the proteolysis increased by 23.4%. Concentration fac-tor did not have a significant influence; however, a tendencywas observed towards higher level of proteolysis at twotimes the concentration factor compared to 1.5 times theconcentration factor. Taking the protein concentration inretentate into consideration gives slightly changed results, asthis still showed interaction between feed pressure and tem-perature, although feed pressure was not significant in itself.Spacer thickness still had a significant impact (Table 3).
Reverse osmosis filtration in combination with conventionalmilking systemsRO experiments were also conducted with bulk milk from aHPM system, as this is known to produce milk with lowerFFA content. Feed pressure and temperature were the onlyfiltration process settings that we varied during the experi-ments. Table 4 is showing the results from these experiments.Effects of neither process parameter nor overall levelbetween retentate and nonfiltrated milk were found on FFA,MFG size distribution and proteolysis.
DISCUSSION
Filtrations techniques influence on milk fat globulestabilityRO did not lead to more formation of FFA compared toUF, although the pressure needed for RO is 10 times larger.It was expected that the lower pressure during UF would bemore gentile to the milk, thereby retaining MFG and pro-teins at a more native state. But it appears that the ROmembrane technology is compensating, so the mechanicalstress across the membrane is limited at these low tempera-tures.
Table 2 Statistical effect of processing parameters on ultra-filtration retentate based on milk from automatic milking system. The measured fac-tors are as follows: volume weighted diameter [D (4.3)], lower 10% fractil [d (0.1)] and upper 10% fractie [d (0.9)] of the milk fat globules(MFG) and free fatty acids (FFA). The results are compared to the average level found in the retentate and raw nonfiltrated milk. Different lettersindicate significant different values between retentate and nonfiltrated milk
Processing parameter
MFG size distribution
FFA [mmol/100 g fat]D (4.3) d (0.1) d (0.9)
Feed pressure NS NS NS P = 0.0295Temperature NS NS NS P = 0.02241
Concentration factor NS NS NS NSPressure drop NS NS NS NSRetentate level 3.740 � 0.287a 0.976 � 0.200a 6.795 � 0.400a 1.377 � 0.308a
Nonfiltrated milk level 3.864 � 0.336a 1.025 � 0.200a 7.002 � 0.520a 1.19 � 0.209a
1Significant effect seen for temperatures above 10 °C.
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For both UF and RO membrane filtration, no change inthe size distribution of MFG was observed compared to non-filtrated milk. This indicates that the MFG are not severelydisrupted, which has been the initial concern of implement-ing this technology at farms. Wiking et al. (2003) found anincrease in the MFG size after subjecting raw milk to shearstress, which also led to an increase in FFA concentration.Meanwhile, the results from this experiment show no signifi-cant difference in size distribution between concentrated andraw milk, and it appears that the treatment does not severelydamage the MFG. Therefore, the risk of increased FFA con-centration is thought to be less likely, as the MFGM can stillact as a barrier towards native milk lipase.The results of ultra-filtrating raw milk showed that no
damage was applied to the milk, except at processing tem-peratures above 10 °C (only based on a single measure-ment). It indicates that production temperatures higher than10 °C provide a risk for retentate with elevated levels ofFFA. Changes with regard to the increasing temperature ofmilk can cause a number of conformation mechanismsaround the MFG and MFGM. The MFGM composition and
structure can change and in turn can cause the membrane toeither weaken or strengthen, depending on the exact mem-brane molecules that are affected. This is, however, notassociated with much evidence, as the mechanism is highlycomplex (Evers 2004; Dickow et al. 2011). The temperatureis also observed to shift the ratio between solid and liquidfat inside the MFG. A higher level of solid fat is known tohave a stabilising effect on the MFG, which leads to lessdisruption and hence less formation of FFA. Wiking et al.(2003) showed a clear relation between milk at 20 °C beingmore sensitive towards mechanical stress through pumpingand milk at 5 °C. This supports the tendency found in thisstudy, where the sample at 15 °C yielded a higher level ofFFA. This indicates that the mechanical stress applied to theMFG during filtration might be more pronounced at highertemperatures, thereby giving lipase better access to thetriglycerides likewise. de Boer and Nooy (1980) showedthat cooling the milk below 7 °C before subjecting to ROwould prevent damage of the MFG.The content of FFA in the native nonfiltrated milk
from AMS had a large day-to-day variance as well as large
Table 3 Statistical effect of processing parameters on reverse osmosis retentate based on milk from automatic milking system. The measured fac-tors are as follows: volume weighted diameter [D (4.3)] and upper 10% fractile [d (0.9)] of the milk fat globules (MFG), free fatty acids (FFA)and proteolysis level. The results are compared to the average level found in the retentate and raw nonfiltrated milk. Different letters indicate sig-nificant different values between retentate and nonfiltrated milk
Processing parameter
MFG size distribution
FFA [mmol/100 g fat] 1Leu-Equivalents [mM] Leu-Equivalents [mM/protein %]D (4.3) d (0.9)
Feed pressure NS NS P = 0.0195 2P = 0.04225 3NSTemperature NS NS P = 0.0198 2NS 3NSConcentration factor NS NS NS NS NSPressure drop NS NS NS NS NSMembrane spacer NS NS NS P = 0.00286 P = 0.003Retentate level 4.111 � 0.200a 6.607 � 0.426a 1.139 � 0.302a 1.795 � 0.355b 31.209 � 5.717b
Non-filtrated milk level 4.124 � 0.260a 6.621 � 0.543a 1.07 � 0.302a 0.96 � 0.1635a 27.639 � 4.977a
1Significant influence of retentate protein content.2Interaction between feed pressure and temperature P < 0.001.3Interaction between feed pressure and temperature P < 0.001.
Table 4 Statistical effect of processing parameters on reverse osmosis retentate based on milk from herring bone parlour milking system
Processing parameter
MFG size distribution
FFA [mmol/100 g fat] Leu-Equivalents [mM] Leu-Equivalents [mM/protein %]D (4.3) d (0.9)
Feed pressure NS NS NS NS NSTemperature NS NS NS NS NSRetentate level 4.416 � 0.244a 7.328 � 0.469a 0.620 � 0.039a 2.165 � 0.266a 35.05 � 4.225a
Nonfiltrated milk level 4.415 � 0.548a 7.361 � 0.840a 0.580 � 0.064a 1.069 � 0.236a 31.42 � 7.086a
The measured factors are as follows: milk fat globule (MFG) size distribution, free fatty acids (FFA) and proteolysis level. The results are com-
pared to the average level found in the retentate and raw nonfiltrated milk. Different letters indicate significant different values between retentate
and nonfiltrated milk.
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variance during the continual sampling from the milk line,compared to the effect from the filtration itself. This is indi-cated by the large relative standard deviation found in bothnonfiltrated milk and retentate. The natural variation in FFAcontent from individual cows is due to differences in stateof lactation, udder health, milking frequency and some dif-ferences in feeding, as the samples of raw milk by our set-up origin from single or few cows in a heard of mixed ages,state of lactation and diets. The average FFA concentrationin the AMS experiments was around 1.25 mmol/100 g fat,which is considered to be quite high. It is well known thatthe FFA content in milk from AMS is greater than that fromother milking systems, for example milking carousel or par-lous, due to increased milking frequencies, higher air intakeand more temperature fluctuations in the bulk tank whichcaused damage to the MFG and thereby enhanced lipolysis(Rasmussen et al. 2006; Wiking 2011). Lipolysis is inhib-ited by its own product (Bengtsson 1980), and this couldhave biased the results with the AMS milk. Thus, a fewexperiments with herring bone parlour milking system(HPM) were also conducted as this is milk inherently lessdamaged (see nonfiltrated milk in Tables 3 and 4). Besidesthe potential effect from product inhibition, the oppositeeffect could also be theorised, that is predamage MFG couldbe more sensitive to the filtration treatments.The experiment with the milk from HPM only tested the
effect on feed pressure and processing temperature, as theprevious results were found to have a significant effect onAMS retentate. However, no significant effect of feed pres-sure and processing temperature on milk FFA was found(Table 4). This indicates that the reason behind the differentimpacts on RO between AMS and HPM might be due tothe harsh treatment from AMS, making the milk predis-posed for further disruption during filtration. Also, the rela-tive standard deviation in both retentate and nonfiltratedmilk from HPM is lower than that seen in the milk fromAMS (which is expected, as the AMS milk was collectedcow by cow and HPM was from a bulk tank). This supportsthe suggestion that the membrane filtration in itself does notcause severe changes to the milk quality, as the HPM milk,with less indigenous variation, showed no significant differ-ence in FFA level between retentate and nonfiltrated milk.
Influence of reverse osmosis on proteolysisPlasmin is the enzyme in milk that causes the majority of theproteolytic activity. Its activity is balanced between a systemof activators, inhibitors and autolysis, which is, for example,affects the temperature and citrate concentration (Cruddenet al. 2005; Kelly et al. 2006; Ismail and Nielsen 2010). Theeffect of milk processing on proteolysis is presumed to below. However, the concentration of plasmin and its substratescould have kinetic effects on the plasmin activity.Protein content had a significant influence on proteolysis in
the AMS retentate, and the tendency of increased proteolysis
was observed according to VCF. So to compensate for thiseffect, and better focus on the mechanical influence of theprocess, a relative level of proteolysis was calculated.Increasing the RO membrane spacer thickness was the onlymechanical parameter that significantly increased the freeamino group concentration. This could perhaps be due toless mechanical pressure inside the membrane. The relativelevel of proteolysis in the retentate from AMS showed thatfeed pressure and temperature have a tendency of the sameeffect on increased proteolysis. So the direct effect ofmechanical stress on protease activity has to be furtherinvestigated. In the retentate from HPM, no significanteffect of feed pressure and temperature on proteolysis, evenin total concentration, was found. Therefore, the HPM milkproved to be less prone to both lipolysis and proteolysisthan the AMS milk. This leads to the fact that the type ofmilking system has a larger effect on the milk than themembrane filtration processing. However, the nonfiltratedmilk from HMP has a slightly higher average level of pro-teolysis than the milk from AMS. This could be due to dif-ferences between the herds e. g. by the average number oflactations (Bastian and Brown 1996).The trend of increased proteolysis in milk from both
milking systems upon higher processing temperature,together with the statistical interaction between feed pres-sure and temperature, ascribes higher plasmin activity athigher temperature (Crudden et al. 2005). Overall, theresults are very encouraging with regard to future imple-mentation of the technology at larger dairy farms. It appearsthat within regular production settings on the equipment, nosevere mechanical disruption and enzymatic degradation arefacilitated.As the loss of lactose is of great disadvantage, especially
today, where lactose in itself holds great value, the extraenergy consumption that RO requires [UF consumed in thisstudy 1.96 kWh/100 l permeate (at 0.35 MPa feed pres-sure), whereas RO consumed 2.54 kWh/100 l permeate (at3 MPa feed pressure)] is low compared to the benefit ofretaining the native milk composition.
CONCLUSION
The results of this study show no advantage with regard tothe FFA concentration of using UF compared to RO. Adecrease in RO feed pressure from 3 to 2 MPa, as well asan increase in temperature from 4 to 10 °C, increased theconcentration of FFA. In the milk from AMS, the MFG sizedistribution did not change by RO processing. The 48 mmmembrane spacer caused a higher level of proteolysis thanthe 30 mil spacer. And contrary to FFA concentration, theproteolysis level increased at a higher feed pressure. Over-all, results show that the concentration of milk by use ofRO membrane filtration is possible, without causing severechanges to the milk quality.
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REFERENCES
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Bengtsson G (1980) Lipoprotein lipase - Mechanism of product inhibi-tion. European Journal of Biochemistry 106 557–562.
de Boer R and Nooy P F C (1980) Concentration of Raw whole milk byreverse osmosis and its influence on fat globules. Desalination 35201–211.
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Crudden A, Patrick F F and Kelly A L (2005) Factors affecting thehydrolytic action of plasmin in milk. International Dairy Journal 15305–313.
Dickow J A, Larsen L B, Hammershoj M and Wiking L (2011) Coolingcauses changes in the distribution of lipoprotein lipase and milk fatglobule membrane proteins between the skim milk and cream phase.Journal of Dairy Science 94 646–656.
Evers J M (2004) The milkfat globule membrane—compositional andstructural changes post secretion by the mammary secretory cell. In-ternational Dairy Journal 14 661–674.
Fuc�a N, Pasta C, Impoco G, Caccamo M and Licitra G (2013) Mi-crostructural properties of milk fat globules. International DairyJournal 31 44–50.
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IDF (1991) Determination of Free Fatty Acids in Milk and Milk Products.Bulletin 265. Brussels, Belgium: International Dairy Federation.
Ismail B and Nielsen S S (2010) Invited review: plasmin protease inmilk: current knowledge and relevance to dairy industry. Journal ofDairy Science 93 4999–5009.
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Tolkach A and Kulozik U (2005) Fractionation of whey proteins andcaseinomacropeptide by means of enzymatic crosslinking and mem-brane separation techniques. Journal of Food Engineering 67 13–20.
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Paper II
Caseinomarcropeptide release in relation to rheological properties during rennet coagulation of
raw milk reverse osmosis retentate
Ida Sørensen, Thao T. Le, Gitte Hald Kristensen, Lotte Bach Larsen & Lars Wiking
Manuscript in preparation, intended for publication in International Dairy Journal
1
Caseinomarcropeptide release in relation to rheological properties during rennet coagulation of 1
raw milk reverse osmosis retentate 2
3
Ida Sørensen, Thao T. Le, Gitte Hald Kristensen, Lotte Bach Larsen & Lars Wiking* 4
5
Aarhus University, Department of Food Science, Blichers Allé 20, 6
Tjele, 8830, Denmark 7
8
*Corresponding author. Tel.: + 45 87157805. 9
E-mail address: [email protected] 10
2
Abstract 11
12
Studies on new technology for concentrate milk at the dairy farm by reverse osmosis (RO) have 13
previously been conducted, yielding promising results on retaining the milk quality. Cheese dairies are 14
considered obvious recipients of the concentrated milk, but before implementation, the cheese making 15
properties has to be evaluated. During this study, several combinations of concentration factor and 16
rennet concentration was examined based on caseinomacropeptide (CMP) release and rheological 17
attributes of the coagulum. Furthermore, the calcium distribution of retentate compared to raw milk 18
was included in the study, as a possible explanation of observed differences. The results showed a clear 19
influence of the ratio between sample dry matter and rennet concentration on the CMP release and 20
coagulation onset. The calcium distribution shifted to a larger fraction of colloidal calcium in the 21
retentate samples compared to the raw milk. This could be part of the explanation to the increased curd 22
firming rate. 23
3
1. Introduction 24
25
Reverse osmosis (RO) membrane filtration on the dairy farm is regarded an option for saving transport 26
costs and increase bulk tank capacity (de Boer and Nooy 1980; Garcia III and Medina 1988), and one 27
of the obvious utilizations for the retentate would be in cheese production. In modern cheese 28
production, milk is concentrated and standardized according to its protein content, in order to save 29
rennet and cheese vat capacity. Ultra-filtration (UF) is often used to concentrate milk for standardizing 30
the milk protein content in order to utilize the cheese vats in cheese making. However, the process of 31
UF changes the milk composition, by allowing e.g. lactose and ions filtered through the membrane into 32
the permeate (Brans et al. 2004). Compared to using non-concentrated milk for cheese production, it 33
could be assumed that cheeses produced from UF retentate has different properties, and further on, that 34
cheese from RO retentate differs from UF cheese making properties due to altered milk component 35
concentrations. Benfeldt (2005) reported differences in the cheese ripening pattern, lower plasmin 36
activity and less degradation of β-casein when UF milk was used instead of regular raw milk was used 37
for the cheese production. 38
39
Casein is the group of milk proteins that makes the network of the basic cheese matrix. They exist as a 40
micellar colloidal structure of αs1-, αs2-, β- and κ-caseins. The exact arrangements of the casein species 41
are still being debated. However, the consensus is that α-caseins give the “framework”, β-casein is 42
dynamically drifting through the micellar structure and κ-casein is positioned primarily in the outer 43
layer (Dalgleish and Corredig 2012). The micelles are kept suspended in the water phase through a 44
negative charged electrostatic repulsion and hydrophilic characteristics. This is especially due to the 45
properties of the outer κ-casein (Fox and McSweeney 1998; McSweeney and Fox 2013). 46
4
47
Chymosin (EC 3.4.23.4) is an aspartic protease, commonly added to induce coagulation of the milk 48
during cheese production. The coagulation of milk is normally regarded as a two phase phases process: 49
First phase is the enzymatic hydrolysis of κ-casein into soluble fraction caseinomacropeptide (CMP) 50
and insoluble one. This reduces the electrostatic repulsion, and thus enables the casein micelles to form 51
a network structure. Second phase is the actual aggregation of the remaining insoluble part of the 52
casein micelles (without CMP). The second phase normally starts when approximately 70% of the κ-53
casein has been hydrolyzed (Walstra et al. 2006). The casein aggregation is mainly due to van der 54
Waals attraction and formation of calcium bridges. 55
56
Calcium is of vast importance for the coagulation properties if milk. The core of the casein micelle is 57
held together by colloidal inorganic calcium phosphate (CCP) which consists of 3Ca3(PO4)2CaH 58
citrate; Ca9(PO4)6; or CaHPO4٠2H2O. The Ca++ both found natively in the serum phase and as added 59
during the cheese making process neutralizes the negative charges of the casein and hereby facilitates 60
the aggregation (Lucey and Fox 1993), and therefore calcium in the ionic form is crucial for the 61
aggregation process in the second phase of coagulation. In addition, micellar calcium is important for 62
the integrity of the CN micelle and its coagulation properties (Udabage et al. 2001). Calcium bridges 63
afterwards further stabilize the aggregates. Lowering the pH results both in higher calcium ion activity 64
due to higher solubility of the CCP complexes (Koutina et al. 2014). The bovine milk calcium exist as 65
an equilibrium between CCP, bound as complexes in the serum phase and as free Ca++ ions. The 66
distribution is temperature dependent and reversible when re-heating after cold storage (Malacarne et 67
al. 2013). 68
5
When changes in coagulation properties are observed, it is meaningful to determine whether the change 69
is due to first or second phase. This will allow more targeted actions. The distinction between first and 70
second phase can be made by comparing the rate of released CMP representing the first phase to the 71
rennet coagulation time and curd firming rate on the other hand, representing the second phase. Sandra 72
et al. (2012) concluded that calcium activity only plays a role during the second phase of the 73
coagulation process, and did not have any influence on the first phase. It could be hypothesized that the 74
calcium distribution and the general ion strength might change during RO filtration, and thus affect the 75
second phase of coagulation. 76
77
During cheese production, not only the rennet coagulation time is of importance, but also the final 78
firmness and the rate of which its coagulum is formed matters. Frederiksen et al. (2011a) as well as 79
Logan et al. (2015) described in their studies that the size of casein micelles and fat globules have an 80
influence on the development of curd firmness, and thus giving higher cheese yield (Jensen et al. 81
2012). The combination of large fat globules and small caseins gave the highest curd firming rate, and 82
the combination of small fat globules and large caseins gave the lowest. They ascribed this mechanism 83
to smaller casein micelles being able to pack closer together, whereas the fat might only play a 84
secondary role. These interactions could also be affected in a concentrated system, where the 85
components are closer together and the water activity lower. The aim of this study was to examine the 86
cheese making properties of RO retentate produced from raw milk at a farm. This includes the effects 87
of the calcium distribution on the chymosin reaction and further on the rheological behaviour. 88
89
90
91
6
92
93
2. Materials and methods 94
2.1 Raw materials and retentate production 95
The RO membrane filtration was conducted at Danish Cattle Research Centre (Aarhus University – 96
Foulum, Tjele, Denmark), as an inline process with a 3.8” pHt spiral wound membranes (Alfa Laval, 97
Lund, Sweden), with a total surface area of 4.7 m2. Pressure across the membranes was 30 bar, and the 98
process temperature was kept at 4 ºC. A closer description of the equipment and filtration process has 99
been published by Sørensen et al. (2016). Samples of raw milk were acquired before the start of 100
filtration. First, valves on the filtration equipment were set to 1.5 VCF and subsequently to 2 VCF. 101
Retentate samples were acquired from both 1.5 VCF and 2 VCF after 30 minutes of processing time to 102
ensure a stable process. Danish Cattle Research Centre (Aarhus University – Foulum, Tjele, Denmark) 103
supplied the raw milk (Danish Holstein breed) for the experiments. The milk was collected from the 104
bulk tank just after the morning milking, and poured into the balance tank of the filtration plant. The 105
experimental production was conducted as triplicates on separate days. 106
107
2.2 Sample composition 108
The overall composition of the retentate and raw milk measured by FT-IR (MilkoScan FT2, Foss, 109
Hillerød, Denmark), giving values of dry matter content, fat, protein, lactose, and solids non-fat. 110
After 24h cold storage, samples of raw milk, 1.5 VCF retentate and 2 VCF retentate were skimmed by 111
centrifugation (3500 rpm for 20 min at 4°C), and removal of the fat phase. 112
The milk serum phase was obtained by ultracentrifugation (Beckman-Coulter Optima 113
7
L-80XP, Beckman Coulter Inc., Brea, CA) skim milk at 100000 × g at 30 ºC for 1 hour in a T4-TI-70 114
rotor. 115
116
Total calcium of both skim milk and serum phase was measured by titrating with 117
Ethylenediaminetetraacetic acid (EDTA). The samples were acidified to pH 4.3, centrifuged at 3500 118
rpm for 5 minutes. The supernatant was collected and added 0.1 N borax buffer. The titration was 119
conducted with a Calcium electrode (sclON 6.1241.070, Metrohm, Herisau, Switzerland) and a 120
reference electrode (LL ISE Reference 6.0750.100, Metrohm, Herisau, Switzerland) on an auto-121
titration system (862 Compact Titrosampler, Metrohm, Herisau, Switzerland). Analytical replication 122
was conducted as duplicates. Further description of the method has been made by (Poulsen et al. 2017). 123
124
The method for ionic calcium concentration measurements was based on work by Koutina et al. (2015) 125
using a Ca2+-meter (LAQUA twin compact Ca2+ METER B-751, electrode model S050, Horiba, Kyoto, 126
Japan) directly on the sample serum phase. The obtained ionic strength (Mw) was converted to [Ca2+ ] 127
through a standard curve of CaCl2 solutions. 128
129
The distribution of calcium fractions was calculated as follows: 130
[Ca colloidial] = [Ca total, skim] – [Ca total, serum] 131
[Ca serum bound] = [Ca total, serum] – [Ca2+] 132
133
134
2.3 Rheological measurements 135
2.3.1 Reorox 136
8
The skimmed samples were pH adjusted to 6.5 with 10% (vol/vol) lactic acid and incubated at 33°C for 137
30 min in a water bath. Chymosin (ChyMax, 200 IMCU /ml, Chr. Hansen, Hørsholm, Denmark) was 138
diluted in Milli-Q ultrapure water (Millipore, Billerica, MA) such that adding 20µl to 10ml milk would 139
give 0.03, 0.04 and 0.05 international milk-clotting units (IMCU) as the final chymosin concentration. 140
Diluted chymosin was added to the sample, mixed well for 10 seconds and transferred to the rheometer 141
(AR G2, TA Instruments, New Castle, Delaware) (20 ml) and the ReoRox (ReoRox4, oscillatory 142
rheometer, MediRox AB, Nykobing, SE) (1 ml in each of 3 channels). 143
144
2.3.2 Conventional rheometer 145
The rheometer was set to run for 40 minutes at 33 ºC at an oscillatory strain of 6.89×10-5 rad at 1 Hz, 146
and data was obtained through Rheology Advantage Data Analysis V5.7.0 (TA Instruments, New 147
Castle, DE). The ReoRox method has been fully described by Frederiksen et al. (2011b). Rennet 148
coagulation time was chosen as the parameter from ReoRox to describe the second stage of 149
coagulation. The G’ max value was not reproducible, and therefore not included, as the samples with 150
firm gels would detach from the cup. 151
152
2.4 CMP determination by LC 153
The method for CMP determination was adapted from Frederiksen et al. (2011a) and (Jensen et al. 154
2015). The samples were incubated at 33°C for 30 min in a water bath prior to the start of the 155
experiment, and pH was adjusted to 6.5 with 10% (vol/vol) lactic acid. Chymosin (chymax) was diluted 156
in milli Q water such that adding 20µl to 10ml milk would give 0.03, 0.04 and 0.05 international milk-157
clotting units (IMCU) as the final chymosin concentration in each sample. One ml of milk sample 158
withdrawn at each time point: 0, 30 s, and 1, 2, 5, 10 and 20 min after addition of chymosin dilution, 159
9
and mixed with 20 µL of pepstatin stock solution [1 mg of pepstatin A (Sigma-Aldrich, St. Louis, 160
Missouri) per milliliter of 10% (vol/vol) acetic acid in methanol], placed on ice to stop the reaction. 161
The samples were carefully mixed with 100 µL of acetic acid (CH3COOH; 10% for raw milk samples, 162
15% for 1.5 VCF retentate and 20% for 2 VCF retentate) to reach pH 4.6. After 2 min of incubation on 163
ice, 100 µL of sodium acetate (CH3COONa; 1 N for raw milk samples, 1.5 N for 1.5 VCF retentate and 164
2 N for 2 VCF retentate) was added as a buffer, and the solution was mixed and centrifuged for 10 min 165
at 14000 rpm at 4°C. The supernatants containing the CMP was isolated, and stored at -18 ⁰C until the 166
further analysis of CMP by LC. One hundred µl of supernatant was mixed 300 µl of 6N GdnHCl and 6 167
µl of 1N DTE and incubated in a shaker at 37 ⁰C for 1 hour, then centrifuged at 14000 rpm at 7 ⁰C for 168
10 minutes. The supernatant was filtered through filtervails (Mini-UniPrep syringeless filter device, 0.2 169
µm pore, PTFE filter media, Whatman, Maidstone, GB) and loaded into the LC. 170
A commercial CMP standard was included to compare the results and the elution time. The CMP 171
standard was dissolved to a 5% solution, and prepared with GdnHCl and DTE. The samples were 172
loaded (injection volume of 50µl) into a LC-ESI-MS (Agilent LC 1100 series connected to an ESI-173
single-Q-MS, Agilent Technologies, Palo Alto, CA, USA) using the exact procedure described by Le et 174
al. (2016). Data analysis was conducted through LC/MSD ChemStation (Agilent Technologies, Santa 175
Clara, CA). The CMP content was calculated as the total curve area between 20 and 45 minutes 176
retention time divided by the total curve are between 20 and 75 minutes retentation time 177
(approximately total protein present) in accordance to the elution times of detected compounds 178
described by Le et al. (2016). 179
180
2.5 Statistics 181
10
The statistical analysis in this study was processed through the statistical freeware program R 3.0.1 (R 182
Foundation for Statistical Computing, Vienna, Austria), as an analysis of variance with a significance 183
level of P < 0.05. To distinguish difference between groups (raw milk, 1.5 VCF retentate and 2 VCF 184
retentate) Tukey’s honest significant difference test was applied. 185
11
3. Results 186
3.1 Composition and calcium distribution in milk and retentate 187
The raw milk used for the experiments had an average protein content of 3.71 % and a total dry matter 188
content of 9.6 % (Table 1). The retentate from 1.5 VCF concentration had an average protein content of 189
5.79 % and dry matter content of 13.68 %, and the 2 VCF retentate had 7.42 % protein and 16.9 % dry 190
matter. Thus, the actual concentration factor of 2 VCF was around 1.8-2, and the 1.5 VCF was 1.4-1.5. 191
The permeate had no measurable dry matter content by FT-IR. Concentrating the milk resulted in a 192
significant decrease in pH, from 6.68 to 6.52, measured after 24 hours of storage at 4 ⁰C. 193
194
The total calcium content increased from 1589 mg/l to 3210 mg/l between raw milk and 2 VCF. The 195
total calcium in the serum phases increased from 497 mg/l to 867 mg/l between raw milk and 2 VCF 196
retentate. Ionic calcium content did however not change between the raw milk and retentate samples. 197
The permeate had no measurable calcium content, neither bound nor ionic. 198
199
3.2 Curd formation 200
Results obtained from the conventional rheometer showed that raw milk had a shorter gelation time 201
compared to retentate concentrated by a VCF of 1.5 and 2 (Table 3a), measured as the time needed for 202
the elastic modulus to reach 1 Pa. Gelation time was negatively correlated to chymosin concentration. 203
The ratio between protein content and chymosin (Table 2) had a significantly negative impact on the 204
gelation time (P < 0.001). After 40 minutes of reaction time, both retentate samples (1.5 VCF and 2 205
VCF) reached a higher elastic modulus compared to the raw milk sample where a chymosin 206
concentrations of 0.04 IMCU and 0.05 IMCU were used (Table 3b). At 0.03 IMCU the coagulation of 207
the retentate samples, especially VCF 2 was delayed to such a degree, that here was no real gel 208
12
formation after 40 minutes. Likewise, the elasticity at 40 minutes was significantly influenced by the 209
ratio between protein content and chymosin concentration individually as well as the ratio between the 210
two (P < 0.05). An example of the elasticity during the coagulation process for the three different 211
sample type with a chymosin concentration of 0.05 IMCU can be seen in Figure 3. The rennet 212
coagulation time obtained from the ReoRox measurements were very much in line with the results 213
from the rheometer (Table 4). Figure 4 shows the relation between rennet coagulation time and the 214
protein to chymosin ratio. 215
216
3.3 CMP release 217
The CMP content was calculated as the peak area at 214 nm UV absorbance curve from 20-45 minutes 218
retention time compared to the total peak area of 20 to 75 minutes retention time. Since it was not 219
possible to make an accurate protein quantification on the LC measurements, the CMP content was not 220
converted into a mass unit, but kept as a relative value to the total peak area. Figure 1 shows 221
representative results of LC measurements of whey from a retentate sample, a raw milk sample and a 222
CMP standard. It is noticed that the retention time of CMP, match in all the different samples – 223
including the standard. The standard does however not contain peptides and proteins with a retention 224
time above 42 minutes, as there are no whey proteins. According to the study from Le et al. (2016), the 225
peak at 33 minutes represents CMP variant A and the peak at 42 minutes represent CMP variant B. The 226
areas from 20 to 30 and from 44 to 55 minutes are protein fragments. The peaks between 60 and 75 227
minutes are α-Lactalbumin and β-Lactoglobulin variants. The retentate samples generally had a larger 228
peak area of CMP compared to samples from raw milk, but the peak area from the whey proteins were 229
of relatively higher intensity compared to the CMP peaks. Thus, the relative CMP content was lower in 230
the retentate samples. CMP variant A appeared to be of slightly higher abundance than CMP variant B, 231
13
which is in accordance to the results of Jensen et al. (2015) on milk samples from Danish Holstein 232
cows. 233
234
After 20 minutes, the chymosin reaction was stopped for all samples, since excessive gelation made 235
sample withdrawal inaccurate. As can be seen on Figure 2, the relative amount of released CMP did not 236
show a consistent pattern during the first 2 minutes of reaction time, whereas the time interval between 237
2 to 10 minutes displayed a certain degree of linearity for all the combinations of chymosin 238
concentration and milk samples. The retentate samples released relatively less CMP compared to the 239
raw milk sample at a constant chymosin concentration (Figure 2). Furthermore, the relative amount of 240
CMP found after 10 minutes of reaction time is positively correlated (P<0.001) with VCF : chymosin 241
ratio. The relative CMP after 10 minutes reaction time was negatively correlated to protein content and 242
positively correlated to chymosin concentration, and the slope of the linear area between 2 and 10 243
minutes was negatively correlated to the protein content of the samples (P< 0.05), with no significant 244
influence of chymosin concentration. 245
246
247
4. Discussion 248
Several studies have dealt with coagulation and curd quality from UF retentate (Sharma et al. 1993; 249
Waungana et al. 1998; Sandra et al. 2011). The primary distinction between UF and RO retentate is the 250
ionic balance systems. Changes to the ionic balance plays an important role during milk coagulation 251
(Ferrer et al. 2008; Zhao and Corredig 2016), and especially calcium distribution is known to greatly 252
influence the coagulation properties (Klandar et al. 2007). An uptake of calcium into the casein micelle 253
is associated with a decrease in pH due to exchange between Ca2+ and H+. This will typically improve 254
14
the coagulation properties as the optimum pH for chymosin is approached, as well as a neutralizing 255
effect of the casein micelle electrostatic repulsion. In this study, the sample pH was standardized prior 256
to the rheological tests, so the contribution of calcium to the milk acidity is no longer a factor that can 257
explain the observations. The observed decrease in pH in the present study was likely a result of ionic 258
balances and acids present in the milk - such as free fatty acids and amino acids being concentrated in 259
RO process (Sørensen et al. 2016), rather than caused by microbial growth. Both protein content and 260
pH of the raw milk used in this study is comparable to the levels found by Jensen et al. (2012) in milk 261
with good coagulation properties from Danish Holstein-Friesian cows. As pH decreased due to the 262
membrane filtration, it was not possible to make a complete distinction between concentration level 263
and pH as the single factor influencing the calcium distribution. In order to do so, the pH should have 264
been adjusted prior to determine the calcium content of the various phases. 265
266
The raw milk calcium contents observed in this study were at the higher end of what has previously 267
been reported for milk that exhibit good coagulation properties (Maciel et al. 2015), and generally a 268
high calcium content has been correlated with higher curd firming rate and gel strength. The percentage 269
distributions of calcium fractions reveal that the ionic calcium decreased and the casein bound 270
increased, whereas the serum bound remained constant. Since calcium has great impact on cheese 271
making properties, it has been common to use it as a supplement to the cheese milk. Adding calcium to 272
the system does however not result in the same calcium distribution pattern as was observed in this 273
study as Philippe et al. (2003) observed an increase in serum and ionic calcium after supplementation 274
rather than calcium binding to the casein micelles. This difference in observations might be ascribed in 275
the calcium to protein ratio, which changes when calcium is added to the system rather than being 276
constant as is seen for the retentate. 277
15
278
One way to evaluate coagulating properties is to measure viscosity and elasticity through rheological 279
measurements as the coagulum is formed. This provides comparable data of both the time it takes to 280
form the coagulum (either the time it takes to change from mainly viscous to mainly elastic properties, 281
or the time to reach maximum coagulum strength) and the strength of the coagulum. These properties 282
are important, and need to be considered in a cheese production, in order to control the production 283
process (Frederiksen et al. 2011b). Based on comparison between raw milk curd and retentate curd it 284
can be seen dry matter, and hereby protein concentration, together with the chymosin concentration 285
influence both curd firming rate and coagulation onset. Similar effects on like delayed coagulation 286
onset and increased curd firming rate have been observed with UF retentate and can be explained the 287
change in coagulation properties by a stronger interaction between casein micelles when the initial 288
distance between them is shorter (Karlsson et al. 2007). The results of CMP release indicates that κ-289
casein is hydrolysed at a lower rate in concentrated milk presumably due to the decreased substrate to 290
enzyme ratio. Karlsson et al. (2007) and Caron et al. (1997) found increased gel firmness in rennet 291
coagulated milk when increasing the protein content by addition of milk powder. The results of these 292
studies are very much in line with the observations made in this current study, even by a different 293
setup. The electrostatic interactions between casein micelles are likewise affected by the ionic balance 294
of both Ca2+, Na+ and pH (Karlsson et al. 2005), all of which are influenced by the RO process. 295
296
In order to distinguish between effects on first or second phase of coagulation, the study on the 297
hydrolyzation rate of κ-casein were used to describe first phase. Rennet induced aggregation of casein 298
micelles normally happen when approximately 70 % of the κ-casein has been hydrolysed as a pseudo 299
first order reaction rate (Mellema et al. 1999). Increasing the rennet concentration does however 300
16
change the reaction rate with a higher slope of the linear phase (Lomholt and Qvist 1999; Sandra et al. 301
2007). The same effect was not observed in this present study, as protein content of the samples 302
appeared to be the dominant factor. Sandra et al. (2011) found a significant relation between protein 303
content in UF retentate and gel strength, with no changes to the amount of κ-casein that needed to be 304
hydrolysed. As in accordance to our study, Lomholt and Qvist (1997) found that higher rennet 305
concentration contributed to a higher gel-firming rate, even after all κ-casein had been hydrolysed, and 306
thus speculated rennet to contribute to the final gel strength beside the hydrolytic process. Since the 307
substrate to enzyme ratio was lower in the retentate compared to raw milk, this effect has likely not 308
been a contributing factor during this present study. This confirms the theory that the changes in the 309
rennet coagulation properties of RO retentate was not directly influenced by the first phase; only due to 310
the ratio between substrate and enzyme. 311
312
5. Conclusion 313
Concentrating raw milk by reverse osmosis caused a shift in calcium distribution towards more 314
colloidal calcium and less ionic serum calcium followed by, and a decrease in pH. A difference in 315
coagulation properties between RO retentate and raw milk was observed, leading to longer rennet 316
coagulation time but a higher curd firming rate. By decreasing the concentration of chymosin, the 317
retentate samples showed a decrease in curd firming rate and longer rennet coagulation time. The 318
results are comparable to findings by Caron et al. (1997) and Karlsson et al. (2007), who assigned the 319
observations to chymosin to protein ratio and changes in casein micelle interactions. These properties 320
were highly ascribed to the ratio between rennet and sample protein concentration. This statement 321
supports the results in this present study, where also the rennet reaction rate was highly dependent on 322
the sample protein content and rennet concentration. Thus, it appears that mechanical process of RO 323
17
does not contribute to changes in coagulation properties, as it is primarily an effect of substrate to 324
enzyme ratio, which could explain the delay of rennet coagulation time. However, the increased curd-325
firming rate could be related to the calcium distribution and ionic balances, and this would require 326
further studies to confirm. 327
328
6. References 329
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Sandra S, Cooper C, Alexander M, Corredig M (2011) Coagulation properties of ultrafiltered milk retentates 394 measured using rheology and diffusing wave spectroscopy Food Res Int 44:951‐956 395
Sandra S, Ho M, Alexander M, Corredig M (2012) Effect of soluble calcium on the renneting properties of casein 396 micelles as measured by rheology and diffusing wave spectroscopy J Dairy Sci 95:75‐82 397
Sharma SK, Hill AR, Mittal GS (1993) Effect of milk concentration, pH and temperature on aggregation kinetics 398 and coagulation properties of ultrafiltered (UF) milk Food Res Int 26:81‐87 399
Sørensen I, Jensen S, Ottosen N, Neve T, Wiking L (2016) Chemical Quality of Raw Milk Retentate processed by 400 Ultra‐filtration or Reverse Osmosis at the Dairy Farm. Int J Dairy Sci 69:31‐37 401
Udabage P, McKinnon IR, Augustin MA (2001) Effects of mineral salts and calcium chelating agents on the 402 gelation of renneted skim milk J Dairy Sci 84:1569‐1575 403
Walstra P, Wouters JTM, Geurts TJ (2006) Dairy Science and Technology. 2nd edn. Taylor & Francis Group, Boca 404 Raton, FL, U.S. 405
Waungana A, Singh H, Bennett RJ (1998) Rennet coagulation properties of skim milk concentrated by 406 ultrafiltration: Effects of heat treatment and pH adjustment Food Res Int 31:645‐651 407
19
Zhao Z, Corredig M (2016) Influence of sodium chloride on the colloidal and rennet coagulation properties of 408 concentrated casein micelle suspensions J Dairy Sci 99:6036‐6045 409
410
Table 1: composition of milk samples including calcium content and distribution between stages (bound to casein micelle, bound calcium in the serum phase and ionic calcium). Differences between sample types are indicated with letters and the significance level.
Raw 1.5VCF 2VCF Significance
level
DM 9.60±0.055a 13.68±0.381b 16.90±0.221c p<0.001
Protein 3.71±0.078a 5.79±0.324b 7.42±0.276c p<0.001
pH 6.68±0.026c 6.59±0.017b 6.52±0.026a p=0.01
Total calcium skim (mg/l) 1589±32a 2470±86b 3210±49c p<0.001
Total calcium serum
(mg/l) 496±24a 684±14b 867±24c p<0.001
Ionic calcium (mg/l) 100.61±3.550 107.27±4.613 106.16±1.463 NS
Casein bound calcium % 68.7 72.2 73.0
Serum bound calcium % 24.9 23.4 23.7
Ionic calcium % 6.33 4.35 3.31
Table 2: Ratio between average protein content of the samples and chymosin concentration.
IMCU Raw 1.5 VCF 2 VCF
0.03 0.008 0.005 0.004
0.04 0.011 0.007 0.005
0.05 0.013 0.008 0.007
Table 3a and 3 b: (3a) Gelation time, as the time needed to reach a G’ of 1 Pa, of the different sample types with increasing rennet concentration. (3b) The G’ meassured 40 minutes after addition of rennet to the samples with increasing rennet concentration.
Table 4: Rennet coagulation time of the different sample types with increasing rennet concentration, measured on ReoRox.
RCT / min
IMCU Raw 1.5 VCF 2 VCF
0.03 24.5±2.83 30.6±3.37 36.6±1.05
0.04 18.2±1.77 20.0±0.35 27.1±1.77
0.05 14.5±1.44 17.8±0.73 21.8±1.41
Gelation time (Pa=1) min
IMCU Raw 1.5 VCF 2 VCF
0.03 24.7±4.74 31.9±3.52 38.9±2.60
0.04 17.7±2.12 22.2±3.38 27.6±3.34
0.05 13.9±1.65 16.9±2.15 21.8±2.21
G' at 40 min
IMCU Raw 1.5 VCF 2 VCF
0.03 27.7±0.25 27.7±0.30 4.4±0.09
0.04 50.5±0.22 73.3±0.73 101.1±0.92
0.05 66.9±0.24 177.2±0.66 210.9±0.91
Figure 1: LC absorbnace spectrum of whey from a 2 VCF RO retentate sample and a raw milk sample reacted for 20 minutes with 0.05 IMCU rennet concentration - compared to a commercial G-CMP standard.
Figure 2: CMP content, relativ to total whey proteins, at certain timepoints during the renneting reaction on raw milk, 1.5 VCF retentate and 2 VCF retentate with 0.05 IMCU rennet concentration.
0.000
0.020
0.040
0.060
0.080
0.100
0.120
0.140
0.160
0 200 400 600 800 1000 1200 1400
Relative CMP content
time, s
Raw
1.5 VCF
2 VCF
Figure 3: Elasticity curve formed during the rennet coagulation process of raw milk, 1.5 VCF retentate and 2 VCF retentate with a rennet concentration of 0.05 IMCU.
Figure 4: Rennet coagulation time as a function of sample substrate to enzyme ratio, measured on ReoRox.
0.001
0.01
0.1
1
10
100
1000
0 5 10 15 20 25 30 35 40 45 50
log G' , Pa (elasticity)
Time, minutes
Raw
1.5 VCF
2 VCF
0
5
10
15
20
25
30
35
40
45
0.000 0.002 0.004 0.006 0.008 0.010 0.012 0.014 0.016
RCT / min
Chymosin to protein ratio
Paper III
Storage stability of whole milk powder produced from raw milk reverse osmosis retentate
Ida Sørensen, Tommas Neve, Niels Ottosen, Lotte Bach Larsen, Trine Kastrup Dalsgaard & Lars
Wiking
Dairy Science & Technology, 2017, Volume 96, Page 873–886
ORIGINAL PAPER
Storage stability of whole milk powder producedfrom raw milk reverse osmosis retentate
Ida Sørensen1& Tommas Neve2 & Niels Ottosen3
&
Lotte Bach Larsen1& Trine Kastrup Dalsgaard1
&
Lars Wiking1
Received: 13 June 2016 /Revised: 30 November 2016 /Accepted: 2 December 2016 /Published online: 19 December 2016# INRA and Springer-Verlag France 2016
Abstract Implementation of reverse osmosis filtration at the dairy farm will reduce thevolume of milk, which has to be transported, and thereby potentially reduce energyconsumption and CO2 emission. The aim of this study was to examine the quality ofwhole milk powder produced from reverse osmosis retentate concentrated at the farm.Whole milk powder prepared from reverse osmosis retentate, with a volume concen-tration factor of 2, was compared to powder from non-concentrated milk, as well as to arange of commercial whole milk powders. A storage experiment of the stability ofretentate powder for up to 12 months at room temperature was conducted and evaluatedfor quality parameters, including proteolysis, oxidation, furosine and colour. The resultsshowed that concentration of the oxidation products hexanal, heptanal and nonanalincreased during storage of both retentate powder and powder from non-concentratedmilk, but not to a higher extent than found in commercial powder of similar storageconditions. Detectable furosine was higher in powder prepared from non-concentratedmilk than that in powder from pre-concentrated milk, and further no changes in colourwas found during storage. However, high variation in powder composition betweenproduced powders, especially with regard to moisture content, could have affectedsome quality parameters. In conclusion, pre-concentrating milk by reverse osmosis atthe farm did not have significant effects on the overall quality of the produced milkpowders in this study.
Keywords Membrane filtration . Oxidation . Proteolysis . Maillard reaction . Furosine
Dairy Sci. & Technol. (2017) 96:873–886DOI 10.1007/s13594-016-0309-y
* Lars [email protected]
1 Department of Food Science, Aarhus University, Blichers Allé 20, 8830 Tjele, DK, Denmark2 Arla Strategic Innovation Centre, Arla Foods, Roerdrumvej 10, 8820 Brabrand, DK, Denmark3 Arla Foods Ingredients Group P/S, Sønderupvej 26, 6920 Videbæk, DK, Denmark
1 Introduction
Milk powder quality is commonly evaluated in two categories: physical and chemical.The physical quality is related to handling the powder during production (flowability)during shipment (bulk density) and by the consumer (wettability). These attributes areoften associated with production-related factors such as atomization and dry matter ofthe evaporated milk and thereby size distribution and surface composition of thepowder particles (Kim et al. 2009; Murrieta-Pazos et al. 2012). However, much ofthe powder quality depends on the raw material. A high level of proteolytic andlipolytic activities in the milk, due to either bacterial growth or somatic cells, willtransfer these qualities to the milk powder and perhaps advance the reactions found inthe powder during storage (Celestino et al. 1997). Sert et al. (2016) has in a recent studyfound a correlation between elevated somatic cell count and loss of functional proper-ties such as solubility, wettability and dispersability of whole milk powder. Thisresulted in poor texture when the powder was reconstituted into yoghurt.
In relation to chemical quality, nutritional value and flavour may be compromisedthrough alteration of fat and proteins and by oxidation. Therefore, it is of absoluteimportance to ensure the product quality when implementing new technologies. Heattreatments of the milk prior to drying might denature whey proteins which can theninteract with the casein micelles, and thereby alter the functionality (Singh 2007). TheMaillard reaction is also catalysed by high temperature, moisture content and pH andwill influence the appearance, colour, flavour, odour and digestibility due to essentialamino acids being less accessible after lactosylation (Thomas et al. 2004; Dalsgaardet al. 2007). Furosine is formed as a further stage of lactosylation, when fructoselysine,generated from lactulosyl-lysine, is hydrolysed in acidic conditions during analysis.This rather early stage of Maillard reaction is a good indicator of heat damage, sincethese products are often found in freshly produced milk powder and UHT milk, andstudies have correlated the formation of furosine with especially heat modifications ofβ-lactoglobulin (Van Renterghem and De Block 1996). Humidity plays a significantrole in Maillard reaction during storage of the powder. Even at low storage temperature,where furosine is not normally formed, humid conditions can accelerate the process(Van Renterghem and De Block 1996). Maillard reaction that reaches some of the endproducts will often go by the nomination of non-enzymatic browning and will yield apowder with a lower lightness value (L*) and more yellowness (b*) and redness (a*)(Thomas et al. 2004). Oxidation is another aspect that will give unpleasant flavour tothe powder and is often associated with surface composition of the particles and storageconditions (Pisecky 1997; Romeu-Nadal et al. 2007). Secondary lipid oxidation prod-ucts, such as hexanal, heptanal and nonanal, have aromatic properties linked to grassyand floral/citrus notes (Mahajan et al. 2004). Lipid oxidation in milk powder is assumedto be mainly from autoxidation, since enzymatic oxidation in powder is insignificantdue to the low water activity (Parkin 2008).
We previously showed that concentrating milk at the farm using reverse osmosis(RO) did not induce any change of free fatty acid concentration and proteolytic activity,provided that raw milk of good quality was used (Sørensen et al. 2016). It was thereforeassumed that the products made from the RO retentate, such as powder, would be ofsimilar quality compared to the products made from raw milk. The aim of this studywas thus to compare the quality of whole milk powders obtained either from RO
874 Sørensen I. et al.
retentate or from raw milk. In this aim, we produced milk powders from the same rawmilk, either pre-concentrated or not on the same spray drying pilot plant, and wecharacterized the properties of these powers and their storage stability, in comparison toreal-scale commercial whole milk powders.
2 Materials and methods
2.1 Production of retentate
Danish Cattle Research Centre (Aarhus University—Foulum, Tjele, Denmark) provid-ed raw milk for the RO filtration studies. From the bulk tank, 800 L of milk wastransferred to a smaller bulk tank with cooling and stirring system. The milk was amixture from Danish Holstein and Jersey cows (2:1 ratio). Membrane filtration wasconducted at the Danish Cattle Research Centre as a batch process, where the milkcirculated between the small bulk tank and the filtration plant (pilot filtration plantproduced by GEA, Skanderborg, Denmark), until the desired concentration factor wasreached. The filtration was carried out by RO with two 3.8″ pHt spiral woundmembranes produced by Alfa Laval (Lund, Sweden), with a total surface area of2 × 4.7 m2. Pressure across the membranes was 30 bar, and the process temperaturewas kept a 4 °C. To produce 400 L of permeate (with a volume concentration factor of2), a process time of 9 h was required. All the batches of raw milk had a dry matter of13.7%, and the RO filtration resulted in retentate with a dry matter of 25.0 and 24.7%.The morning after concentrating the milk, the retentate and 400 L of fresh raw milkfrom the same heard was transported to GEA Niro (GEA Process Engineering, Søborg,Demnark) and stored for 1 day at 4 °C, before further processing. This experimentalproduction was conducted as duplicates of both RO retentate and fresh raw milk on twosubsequent days. The samples, ‘Non-conc 1’ and ‘Conc 1’ referring to non-concentrated raw milk and pre-concentrated raw milk, were dried on the same day—on the second day after the production of ‘Conc 1’ retentate. The procedure was thenrepeated for ‘Non-conc 2’ and ‘Conc 2’.
2.2 Powder manufacture and storage
Before powder production, both the retentate and raw milk batches were thermised at67 °C for 90 s and afterwards evaporated to approximately the same level of dry mattercontent (41.5–46.8%), followed by homogenization. The powder was produced as amultistage drying process, with an inlet temperature of 180 °C and outlet of 75 °C. Asystem of three-stage fluidized beds was used, and powder fines retrieved from theoutlet air were recycled into the drying chamber close to the atomizer nozzle. Aschematic overview of the milk treatment and powder production is shown in Fig. 1.
The powders were stored in air and light sealed bags at room temperature ofapproximately 20 °C for 3, 6 and 12 months. The atmosphere was not modified, andno vacuum applied to the bags. Aliquots for furosine and oxidation measurements weretaken at the indicated time points and stored at −80 °C until analysed. The referencepowders were acquired from Arla Arinco (Arla Foods, Videbæk, Denmark) and ArlaAkafa (Arla Foods, Svenstrup, Denmark) and had been stored at the dairies in bulk
Quality of powder from raw milk RO retentate 875
bags at room temperature. Two reference samples had been stored in sealed packagewith alternated atmosphere. All the reference samples were acquired and analysed atthe same time at the end of the storage experiment. Thus, all the reference samples wereproduced at different times and as different batches.
2.3 Powder composition
2.3.1 Protein content
Protein content was estimated by the Kjeldahl method (AOAC 2005), using KjeltecInstruments (Kjeltec System Autosampler 8460 and Kjeltec System Autoburette 8400Analyser Unit, Foss, Hillerød, Denmark). The protein content was determined bydissolving a 0.2 g powder sample in 12 mL 98% sulfuric acid and 5 mL pure hydrogenperoxide. Two Kjeldahl taps (copper sulphate and potassium sulphate, Foss, Hillerød,Denmark) were added to the solution. The samples were then set to react at 420 °C for1 h and 20 min and added sodium hydroxide 27.5% to convert the ammonium sulphateinto ammonia gas, before being titrated with hydrochloric acid 0.1 M. The nitrogencontent was multiplied by a factor of 6.38, to calculate the estimated protein content ofthe sample.
2.3.2 Fat content
Total fat content was measured by the Rose-Gottlieb method (AOAC 2000). A 0.3 gpowder sample was dissolved in 10 mL demineralized water overnight. Afterwards,1 mL ammonia was added to the tubes together with 10 mL ethanol 96% and congo red
Two batches of both concentrated and non-concentrated 1 day of storage
Thermised
Retentate production
Homogenized
Evaporated
Transported/ stored at GEA
Spray dried
67ºC 90 s
Inlet temp. 180ºC Outlet temp. 75ºC Water content 1.9-3.6
Dry matter 41.5% - 46.8%
Fig. 1 Process diagram of powder production on pilot spray drier. Included is the pre-concentration step
876 Sørensen I. et al.
indicator solution. The fat phase was then dissolved in 25 mL diethyl ether and 25 mLpetroleum ether. After 30 min, the fat phase was withdrawn and the solvents evaporateso the fat was left at the bottom of the tube.
2.3.3 Insoluble particles
Insoluble particles were measured by dissolving 10 g of sample in 100 mL of waterusing a Solubility Index Mixer (type AC, Labinco BV, Breda, Nederland) for 1.5 min.The samples then rested for 15 min before being stirred and poured into 50-mLcentrifuge tubes and centrifuged for 5 min at 800 rpm at room temperature. The top45 mL was poured off and replaced by water. The samples were stirred beforecentrifugation was repeated. The amount of sediment was then regarded the insolubilityindex.
2.3.4 Surface free fat
Surface free fat analysis was conducted by Arla Arinco (Videbæk, Denmark). Thesamples were washed with petroleum ether, filtrated, and the solvent evaporated, soonly the surface fat of the particles would be left in the beaker.
2.3.5 Particle size distribution
Particle size distribution was determined by sieving 50 g of sample through a sievetower with a 630 μm and a 400 μm metal sieve with an amplitude of 60 for 3 min. Thedistribution of powder between the sieves was then measured.
2.4 Proteolysis
The powder was reconstituted in demineralized water to approximately the sameconcentration as raw milk and kept for 3 days at 4 °C. The composition of thereconstituted milk was measured by FT-IR (MilkoScan FT2, Foss, Hillerød, Denmark).The level of proteolysis was measured by the reaction between N-terminals of aminogroups and fluorescamine and quantified by a standard row of leucine. Thus, the resultswere measured as Leucine equivalents (mmol·L−1) divided by the total protein content.A description of the fluorescamine assay can be found in the study by Wiking et al.(2002). Results were obtained by analysis on a multi plate reader (BioTek Synergy 2,Holm & Halby, Brøndby, Denmark) with the Gen5 1.07.5 software (BioTek Instru-ments, Winooski, VT, United States). The concentration of free N-terminals was thendivided by the protein content in the reconstituted milk, to find the relative proteolysisin the sample. The measurements were conducted in triplicates.
2.5 Oxidation
The method for measuring oxidation products was adapted from Jensen et al. (2011),on the same equipment, with a few modifications to the procedure. A sample size of200 mg powder was put into a HPLC tube with 1 mL water and 5 μL 0.01 mg·mL−1
internal standard (hexanal D12). For subtraction of the volatile compounds into the GC-
Quality of powder from raw milk RO retentate 877
MS, a grey SPME fibre (50/30 um DVB/CAR/PDMS, stableflex 2 cm, Grey-notched)from Supleco (Bellefonte PA, USA) was incubated at 50 °C for 30 min and injectedinto a GC-MS MSD 5975 from Agilent Technologies (Waldbronn, Germany) with aninlet temperature of 275 °C. A mixed external standard was used for quantification ofthe oxidation products found: hexanal (targeted ion 56 m/z and qualifier ions 82 and72 m/z), heptanal (targeted ion 70 m/z and qualifier ions 55, 81 and 86 m/z) andnonanal (targeted ion 57 m/z and qualifier ions 98, 82 and 70 m/z) using hexanal D12as an internal standard according to Wold et al. (2015) using a target ion of 64 m/z andqualifier ions 80 and 92 m/z.
2.6 Colour
Colour was measured by colorimeter (Konica Minolta portable spectrophotometer, To-kyo, Japan), using the parameters L* (lightness), a* (red/green) and b* (yellow/blue). Themeasurements were conducted as triplicates through a thin transparent plastic bag.
2.7 Furosine
The method for furosine measurement was adapted from Jansson et al. (2014). Samplesof whole milk powder (0.15 g) were hydrolysed in 10 mL 8 mol·L−1 hydrochloric acidfor 20 h at 110 °C and filtered after cooling. The filtrated hydrolysate was diluted 1:4 in3 mol·L−1 hydrochloric acid, and 500 μL was transferred to HPLC filter vails. Furosineconcentration was determined through ion-pair RP-HPLC using a Spherisorb ODS25 μm column (250 × 4.6 mm i.d.) (Grace Davison, Australia), with 0.06 mol·L−1
acetate buffer and a flow rate of 0.5 mL·min−1. The amount of furosine was calculatedbased on a standard curve with a concentration of 0.3–10 μg·mL−1, made from a stocksolution of 0.604 mg·mL−1 furosine dihydrochloride (99.4% purity) from thePolyPeptide Group (Strasbourg, France).
2.8 Statistics
The statistical analysis of variance was processed through the statistical freewareprogram R 3.0.1 (R Foundation for Statistical Computing, Vienna, Austria). The effectsof powder fat content, storage time and protein content, respectively, on surface free fat,oxidation and furosine were analysed by the following model: γi = α + βχ(i) + ei,i = 1,…,11; where γ was the value of the dependant variable and χ was the value of theindependent variable in samples 1 to 11 and ei as the residual error. α and β were theintercept and slope estimated for the linear model. The effects of powder type onproteolysis and colour were tested by the model: γi = T(i) + ei; i = sample 1,…,11,where γ was the value of the dependant variable and Twas the effect of type in samples1 to 11 and ei as the residual error. Tukey’s HSD test (R package agricolae, version 1.2–4) was applied for evaluation of treatment differences among powder types. Oxidationproducts as dependant on interaction between storage time and powder type were of themodel: γij = SP(ij) + S(i) + P(j) + eij,; where γ refers to the value of the specific oxidationproduct as the dependant variable, Si = effect of storage time (i = 0, 3, 6, 12 months)and P = effect of powder type (j = conc, non-conc and reference). P < 0.05 was used asthe significant threshold in all the models.
878 Sørensen I. et al.
3 Results
3.1 Powder composition and characteristics
Prior to powder production, the raw milk had a fat content of 4.5–4.9% and aprotein content of 3.6%; while the pre-concentrated milk had a fat content of8.3–8.6% and a protein content of 6.8–6.9%. After powder production, bothbatches of powder made from non-concentrated milk had a fat content of 17.8–21.9% and a protein content of 29.3–30.8% (Table 1). The powders from pre-concentrated milk had a fat content of 29.9–31.0% and a protein content of26.3–26.5%. Variation in the powder composition between pre-concentrated andnon-concentrated was presumably a result of handling at the spray dryingfacility. The water content of all the samples was between 1.8–3.5%. Thesurface free fat varies between 0.17 g/100 g fat to 2.59 g/100 g fat, and thehighest amounts were found in the powder from pre-concentrated milk. Therewas a significant (P < 0.05; R2 = 0.89) correlation between the total fat contentin the powder and the level of surface free fat. All of the powders made fromraw milk and pre-concentrated milk had similar particle size distribution, withabout 98% of the particle mass having a diameter of 400 μm or smaller. Theinstant reference powders had a larger portion of particles in the 630 to 400 μmrange, and the regular reference powders were more or less equally distributedbetween the fraction of 630 to 400 μm and 400 μm to smaller.
3.2 Proteolysis and oxidation during storage
Proteolysis was measured as level of free N-terminals in the newly produced powdersand subsequently again after 3, 6 and 12 months of storage and compared to commer-cial powders of different ages as references relative to protein content (Fig. 2). No trendtowards increased proteolysis during storage was observed, and only the powder originhad a significant influence on the level of free N-terminals. Overall, the commercialreference powders had a higher level of proteolysis relative to protein content comparedto the small-scale produced powder form raw and pre-concentrated milk. The powderfrom raw milk had the lowest level of proteolysis in spite of being the powder with thehighest protein content.
During storage, an increase of the secondary lipid oxidation products hexanal,heptantal and nonanal was found. Interaction between storage time and powder type(powder from RO retentate and non-concentrated milk) was significant (Fig. 3). Thehexanal content increased from below quantification limit of 10 ng/100 mg sample infreshly produced powder to about 98 ng/100 mg sample in 12-month-old powder fromraw milk and 66 ng/100 mg sample in powder from pre-concentrated milk. Only thereference powder stored in a bulk bag for 12 months showed detectable concentrationsof oxidation products (Ref. regular 12 month in Table 1), with a hexanal concentrationof 144 ng/100 mg sample (Fig. 3a). Even with a significant influence of powder originon hexanal development during storage, the specific powder composition did not haveany impact on the result. There is a significant effect (P = 0.0015) of interactionbetween storage time and moisture content on the hexanal concentration. Heptanalincreased from below quantification limit of 5 ng/100 mg sample for both raw and pre-
Quality of powder from raw milk RO retentate 879
concentrated milk powder to about 21 ng/100 mg sample in the raw sample and 15 ng/100 mg sample in the pre-conc. sample (Fig. 3b). The 12-month-old reference sample(Ref. regular 12 month in Table 1) was comparable to the raw sample on heptanalcontent with 24 ng/100 mg sample. Like hexanal, there is a significant (P = 0.002)interaction between storage time and moisture content. Nonanal was below the detec-tion limit of 5 ng/100 mg sample in all the freshly produced samples and increased to9 ng/100 mg in the raw milk powders and 10 ng/100 mg in the pre-conc. powders after12 months of storage (Fig. 3c). The increase of nonanal during storage was significantfor all of them. After 6 months of storage, the raw milk powder had reached an averagelevel of nonanal comparable to what was also found after 12 months of storage. Theconcentration of nonanal powder from pre-concentrated milk increased significantlyfrom 6 to 12 months of storage and in the end exceeded the level found in the raw milkpowder samples, and a significant interaction between powder type and storage timewas found. However, the fat and protein composition of the powders did not have adirect impact on the nonanal development. The 12-month-old reference sample(Ref. regular 12 month in table 1) had a nonanal content of 6 ng/100 mgsample and is there for lower than both powder from raw milk and pre-concentrated milk.
Table 1 Composition and physical characterization of small-scale powders produced from non-concentrated(non-conc) raw milk and raw milk pre-concentrated (conc) at the farm from reverse osmosis, on twosubsequent days (1 and 2) of production, and several commercial reference samples (Ref.)—both instantand regular stored in bulk bags for up to 12 months and two reference powders stored in sealed bags withaltered air composition
Composition Particle size distribution
Fat%
Protein%
Water%
Surface fatg/100 g
fat
Insolubleparticles
≥630 μm 630–400 μm ≤400 μm
Non-conc 1 17.81 30.78 3.55 0.17 0.2 0.20 1.20 98.60
Conc 1 29.89 26.47 2.17 1.57 0.2 0.90 2.20 96.90
Non-conc 2 21.89 29.29 2.81 0.85 0.1 0.58 1.00 98.42
Conc 2 31.00 26.26 1.87 2.59 0.2 0.26 1.82 97.92
Ref. regular fresh 28.24 23.63 3.17 0.99 0.1 0.30 53.19 46.52
Ref. regular12 month
27.97 23.45 3.38 0.83 0.1 0.16 37.36 62.48
Ref. instant6 month
26.47 26.89 3.31 1.14 0.1 4.49 64.22 31.29
Ref. instant fresh 27.91 23.97 2.71 1.49 0.1 2.30 83.21 14.49
Ref. regular3 month
25.76 24.17 3.04 0.88 0.1 0.20 44.10 55.70
Ref instant sealed12 month
28.36 23.54 2.85 1.70 0.1 0.98 68.98 30.04
Ref regularsealed12 month
26.34 23.99 3.22 1.64 0.1 0.52 6.13 93.35
880 Sørensen I. et al.
3.3 Colour changes and furosine formation during storage of powder
No change of colour was observed during storage, and the L*, a* and b* variables wereonly significantly affected by powder type (from non-concentrated milk, pre-conc. milkand various commercial whole milk powders) as seen in Fig. 4a–c. The commercialsamples were on average lighter but with more colour—a,* indicating greenish colourand b*, indicating yellowish colour. The powders made from raw milk were thedarkest—with the lowest L* value—and had almost the same level of a* and b* asthe commercial powders. The powders from pre-concentrated milk were the lowest incolour—a* and b* and a lightness as the reference samples.
Storage time / months
0 2 4 6 8 10 12 14
Leu
-Equ
ival
ents
[m
mol
· L
-1]
/ pro
tein
%
18
20
22
24
26
28
30
32
34
36
38
Conc 1
Conc 2
Non-conc 1
Non-conc 2
Reference
Fig. 2 Proteolysis expressed as Leucine equivalents found in whole milk powders produced from non-concentrated (non-conc—batches 1 and 2) raw milk and pre-concentrated (conc—batches 1 and 2) raw milkmanufactured on a pilot-scale spray drier and several commercial reference powders, as dependent on storagefor 0, 3, 6 or 12 months at room temperature of approximately 20 °C
00
50
100
150
200
0 3 6 12
Hex
anal
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100m
g sa
mpl
e
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a
00
05
10
15
20
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30
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Hep
tana
l ng
/100
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sam
ple
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b
Non-conc Conc Ref
00
02
04
06
08
10
12
0 3 6 12
Non
anal
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mpl
e
Storage time / months
c
Fig. 3 Oxidation products found in powders produced from non-concentrated (non-conc) raw milk and pre-concentrated (conc) raw milk manufactured on a pilot-scale spray drier, compared to a commercial reference(Ref) sample. a hexanal concentration during storage. b Heptanal concentration during storage. c nonanalconcentration during storage. The error bars show the standard deviation found between thesamples of same type
Quality of powder from raw milk RO retentate 881
Furosine increased significantly (P = 0.03) upon storage of the powder samplesproduced from non-concentrated and pre-concentrated milk. The raw milk powder hadthe highest level of furosine, both before and after storage, and it was the powder typewith the highest amount of protein. Furosine was positively correlated with both proteincontent (P = 0.004; R2 = 0.7) and storage time, but no interaction between those factorswas found by statistical analysis. The linear relation is not very evident, so a largersample size might provide a model with better fit. When adding all the commercialreference samples, a more robust statistical model could be formed on the influence ofprotein and storage time on the concentration of furosine (Fig. 5). There was nocorrelation found between colour and furosine concentration, with the only relationbeing the powder composition that affects both colour and furosine.
4 Discussion
4.1 Impact of powder composition and pre-concentrating milk at the farm
In our recent study, we found that the technology of concentrating milk at the farm didnot affect the milk quality regarding lipolysis and proteolysis activity (Sørensen et al.2016) and thus theorized that the concentrated milk is still of a quality suitable for high-quality milk powder production.
The powder composition had a significant effect on many of the quality parametersanalysed in this study, i.e. surface free fat, proteolysis, colour and as a co-influence on thefurosine concentration. The surface free fat was highly correlated with fat content as to beexpected. Fitzpatrick et al. (2004) showed that it is not only the total fat content that isresponsible for the final content of free fat, and Koc et al. (2003) listed a number ofproduction factors during the spray drying process that might contribute to the final level offree fat, such as process temperature and shear stress. Surface free fat onwholemilk powdermight however not affect important parameters such as flow ability and hydrophobicity,since it is inevitable to have the particle surface covered in free fat, and thickness of the free
95.0
95.5
96.0
96.5
97.0
97.5
98.0
Non-conc Conc Ref
L*
-5.0
-4.5
-4.0
-3.5
-3.0
-2.5
-2.0
-1.5
-1.0
-0.5
0.0Non-conc Conc Ref
a*
10
11
12
13
14
15
16
17
Non-conc Conc Ref
b*
a
b
b
a
b
c
a
b
c
Fig. 4 Colour L* (lightness), a* (greenness) and b* (yellowness) as an average during storage of powdersproduced from non-concentrated (non-conc) raw milk and pre-concentrated (conc) raw milk manufactured ona pilot-scale spray drier, compared to several commercial reference samples (Ref)—both instant and regular, ofvarious ages. The lower case letters (a, b and c) indicate significant difference between groups on the same plot(P < 0.05). The error bars represent the standard error of mean found between the samples of same typethroughout the entire storage period
882 Sørensen I. et al.
fat layer is not correlated to quality loss (Nijdam and Langrish 2006; Kim et al. 2009). Ascan be seen from the results in this study, the powders made from pre-concentrated milkhad the highest amount of fat and surface free fat, but did not show any sign of poorerquality compared to the powder made from raw milk with less fat and surface free fat.
The powders from retentate and non-concentrated milk made on the small-scaleindustrial spray drier were characterized by most of the particles being smaller than400 μm. The particle size is highly dependent on production method, including initialconcentration, atomization, fluidized bed and return of fines into the drying chamber.Larger particles are associated with better wettability, flowability and lower bulkdensity and are therefore one of the parameters that defines instant powder (Pisecky1997). So the particle size distribution of the powders from the small-scale productionis to be expected, and the results correlate well with the study of Jin and Chen (2009),that reported particles in the size range of 100–450 μm.
Celestino et al. (1997) described how certain proteolytic enzymes, especially ofbacterial origin, might be resilient to the temperatures and conditions during spraydrying of the milk. The proteolytic activity during storage of the powder might howeverbe so low, that the proteolysis in the raw milk during storage before drying is still themajor contributor to the total concentration of proteolytic products. Thus, the activityduring powder storage may be negligible. These thoughts support the findings in thisstudy, where no effect of storage time has been observed, neither in the powdersproduced from raw and pre-concentrated milk nor any of the reference samples.
Generally, the colour of milk powder is often considered in relation to Maillardreaction (Le et al. 2011). In this study, no correlation between neither storage time nordevelopment of furosine was found, indicating that the Maillard reaction had not
Fig. 5 Furosine formation found in whole milk powders produced from non-concentrated (non-conc—batches 1 and 2) raw milk and pre-concentrated (conc—batches 1 and 2) raw milk manufactured ona pilot-scale spray drier and several commercial reference powders, as dependent on protein content of thepowders and storage time. Blue freshly produced, green 3 months, yellow 6 months and red 12 months
Quality of powder from raw milk RO retentate 883
reached a level that would result in browning. It could be expected that powders withhigher protein content would be more vulnerable to the heat treatment during powdermanufacture Rozycki et al. (2007) since colour development in whole milk powder isfaster during heat treatment, at a given temperature, with increased protein content, andthis was especially the case at pH 6–7. Thus, this emphasizes the importance of rawmaterial quality and production process for the final product.
Overall, the composition of the produced powders varied considerably. This madethe interpretations of the influence of composition of the milk (normal or concentrated)on the resulting powder quality difficult. Even though it can be considered as a strengthof the present study that an industrial low scale powder production was applied, it wasalso evident that there were challenges with reproducibility, due to the variability inhow the concentrated and raw milk was handled before drying. It is therefore concludedthat the variation between trial days and batches were larger than the contribution fromvariation in the milk used for spray drying.
4.2 Storage stability in relation to oxidation and furosine formation
In this present study, the oxidation products hexanal, heptanal and nonanal were foundto increase during storage and with interaction of powder type. These oxidationcomponents are often associated with oxidation of whole milk powders and infantformulas during storage, and they all have a rather low odour threshold (Fenaille et al.2003; Romeu-Nadal et al. 2007). Fat and protein contents of the powder did not have asignificant influence on oxidation, and the powder made from raw milk generally had ahigher level of oxidation despite the lower fat content and lower surface free fat,compared to the pre-concentrated milk from the same heard. Likewise, Zunin et al.(2015) found that there is no correlation between free fat and level of oxidation. It iswell known that water activity accelerates the process (Nielsen et al. 1997; Stapelfeldtet al. 1997), and in the present study, moisture content and storage interacted on theformation of hexanal and heptanal. Therefore, even though neither of the powdersamples in this study have considerably high moisture content, the differences are stillenough to have measurable impact on the powder quality.
Furosine is a so-called artificial amino acid that is formed by the acid hydrolysisduring the analysis of the first stage Maillard reaction products. The disadvantage ofusing furosine as an indicator of Maillard reaction is that during the acid hydrolysis,lysine is formed together with furosine, and if the Maillard reaction is on a moreadvanced stage, where fructoselysine has been further degraded, furosine will not beformed. The advantages are, on the other side, that even though lysine is formed by theacid hydrolysis during analysis, the furosine formation is still consistent. So whenevaluating furosine results, it is important to keep in mind whether the Maillard reactioncould be on a more advanced stage (Thomas et al. 2004). In this study, no changes incolour was found during storage, indicating that the Maillard reaction was still at aninitial stage and thus furosine analysis was considered to be a reliable marker. Maillardreaction is known to be accelerated by water activity (Van Renterghem and De Block1996; Thomsen et al. 2005). Nevertheless, the results of this study indicated nocorrelation between moisture content of the powder and furosine formed, in contrastto the oxidation results. Protein content was, however, found to be associated with afurosine formation, in accordance with the study of Morgan et al. (2005). This supports
884 Sørensen I. et al.
the findings in our study, where a combined effect of protein content and storage timeinfluenced the furosine formation, especially when including various commercialwhole milk powder as described by the model in Fig. 5. It could be argued that non-concentrated milk was subjected to more evaporation than pre-concentrated prior tospray drying. According to Oldfield et al. (2005), the preheat treatment is more harmfulto the whey proteins than the evaporation process. Thus, it does not appear to be of anydisadvantage to concentrate the milk through RO—even if it is conducted at the farm.Taken together, it seems like a promising method that does not have negative influenceon milk quality like proteolysis, in spite of the more concentrated milk matrix andcloser presence of e.g., milk enzymes and its milk substrates. However, an eventualimplementation will depend on economic calculations on the feasibility and willpotentially be of higher benefit in countries with long distances and extensive, butlarge farms.
5 Conclusion
The present study show that the concentration of proteolysis products depended on thepowder origin and especially the commercial powders had a higher level of proteolysis.Concentration of proteolysis products did not increase during storage of any of thepowders. Surface free fat was significantly correlated with the fat content of thepowders. Storage time influenced the concentration of the oxidation products hexanal,heptanal and nonanal for both powder from RO retentate and from non-concentratedmilk, and after 12 months, the oxidation was still in the same range as commercialwhole milk powder. Furthermore, hexanal and heptanal were influenced by the mois-ture content. The formation of furosine was dependent on both storage time and finalpowder composition, but the Maillard reaction was at an early stage and thus notreflected through colour measurements. Colour did not change during storage. The rawmaterial handling at the pilot-scale spray drier derived some compositional effect e.g.,protein and fat % in the powder, which could have affected some quality parameters,epically the moisture content of the produce powders was low. However, this is a well-known challenge when using pilot-scale instead of a real production scale. Overall,concentrating the milk at the farm prior to powder production did not affect the powderquality, compared to powder from non-concentrated milk, and thus seemed a promisingprocedure to avoid transport of large volumes prior to processing.
Acknowledgements We thank Søren Skjølstrup Jensen, Simon Andersen (Arla Food Ingredients, Videbæk,Denmark) and Nils Mørk (GEA Process Engineering, Skanderborg, Denmark) for the knowledge andtechnical assistance; Mette Krogh Larsen (Arla Arinco, Videbæk, Denmark) for acquiring reference samplesand laboratory facilities; and Rita Albrechtsen and Gitte Hald Kristiansen (Aarhus University, Deparment ofFood Science, Tjele, Danmark) for assisting in laboratory work.
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Appendix 1
Somatic cell count in reverse osmosis retentate – unpublished data
Introduction: In order to consider the impact from SSC on results of e.g. proteolysis in the raw milk
retentate, it was decided to acquire data on SSC before and after RO membrane filtration. Due to very
low SSC in the raw milk, and no significant correlation to other results of the studies, it was decided
not to conduct further experiments on the topic and not publish the data.
Materials and methods: During two subsequent days of experiment, 30 ml of retentate and raw milk
sample was collected as duplicates in labelled tubes with a preservative solution, and sent to Eurofins
Laboratories (Vejen, Denmark) for analysis. The samples were measured by flow cytometry on a
Fossomatic (Foss, Hillerød, Denmark).
Results: The raw milk had an average of 148.000 cells /ml, and the RO retentate of 1.5 VCF and 2 VCF
had an average of 125.000 cells/ml and 47.000 cells/ml respectively. The results had a very consistent
tendency of decreasing SSC during the filtration process.
Table 4: Average somatic cell count as cells pr ml sample of raw milk, reverse osmosis (RO) retentate of 1.5 voulme concentration factor (VCF) and RO retentate of 2 VCF.
Raw 1.5 VCF 2.0 VCF
148.000 125.000 47.000
Appendix 2
Colony forming units found in reverse osmosis retentate – unpublished data
Introduction: As microbial growth was a major concern during the initiation of the project, several
bacteological samples were collected in the entire duration of the studies. It was concluded that the
filtration process did not cause severe microbial problems, and thus the subject was not further studied.
Materials and methods: Samples of raw bulk milk and RO retentate were collected as duplicates by
using sterile syringes. The samples were put on ice in a thermo box and transported to Eurofins
Laboratories (Vejen, Denmark) for analysis. The analysis were conducted by flow cytometry on a
BactoScan (Foss, Hillerød, Denmark).
Results: the results showed that the filtration equipment had contamination issues from time to time,
and thus the CFU results were very inconsistent. After becoming aware of the issue, and making an
effort to properly avoid contamination, the CFU count was significantly reduced. The results in table 5
shows the average CFU/ml found in raw milk and RO retentate after implementation of a better
hygienic routine.
Table 5: Average CFU/ml in raw milk samples and RO retentate of 2 VCF.
Raw 2.0 VCF
3000 4500
Appendix 3
Viscosity of reverse osmosis retentate during storage – unpublished data
Introduction
After evaporation of the raw milk and RO retentate prior to drying, it was noticed that the RO retentate
was far more viscous than the raw milk at same dry matter content. It was unfortunately not possible to
conduct rheological measurements at that given time. So in order to assess these possible changes in
viscosity of RO retentate during storage, experiments were set up, so the viscosity vas measured during
storage at 4°C for both raw milk and RO retentate of various dry matter content. The gelation of heated
evaporated milk is mostly linked to the denaturation of whey proteins and rearrangement of three-
dimensional protein network (Bienvenue et al. 2003).
Materials and methods
Samples of raw milk and retentate of two different dry matter content were stored at 4°C, and viscosity
measured every day up to 3 days of storage. This was done on both samples with the full fat content
and samples skimmed directly after production. The viscosity was measured on a rheometer through a
bob cup system, with a cooling unit of 4°C.
Results and discussion
Figure 11 shows the collected results of viscosity. No significant changes have been observed during
storage of either raw milk or RO retentate, even though a tendency of viscosity increase is seen in the
full fat 2 VCF sample. The viscosity is significantly (p<0.001) dependent on dry matter content, and
thus also concentration factor. This is a known relation, so the results are as expected (Carr 1999).
0
0.005
0.01
0.015
0.02
0.025
0.03
0.035
Day 0 Day 1 Day 2 Day 3
Viscosity Pa*
s
Storage time
Whole milk
Raw
1.5 VCF
2 VCF
0
0.005
0.01
0.015
0.02
0.025
0.03
0.035
0 10 20 30 40Viscosity Pa*
sDry matter %
Whole milk
0
0.005
0.01
0.015
0.02
0.025
0.03
Day 0 Day 1 Day 2 Day 3
Viscosity Pa*
s
Storage time
Skim
Raw
1.5 VCF
2 VCF
0
0.005
0.01
0.015
0.02
0.025
0 5 10 15 20 25
Viscosity Pa*
s
Dry matter %
Skim
Figure 11: Viscosity of retentate and raw milk samples during storage
Appendix 4
Cream separation from reverse osmosis retentate – unpublished data
Introduction
It is essential to ensure that the retentate has the proper ability to be separated into cream and skim
milk, without too high loss of fat into the skim milk, in order for the milk to be further processed into
high quality products. According to Fjaervoll (1968), the ability to clean skim the skim milk fraction is
highly dependent on temperature and viscosity. Also factors such as fat content and fat globules size
will affect the process. Due to the higher viscosity found in the retentate, it could potentially be harder
to achieve a pure separation between skim milk and cream. Therefore, it was decided to include
separation experiments in the project.
As a result of equipment incapability, it was very difficult to control temperature during separation at
the pilot scale centrifuge. So the results have been sparse, but enough to give an indication of the
properties.
Materials and methods
The separation experiments were conducted preliminary on a lab centrifuge, prior to the pilot plant
centrifuge experiments. The lab tests were done on both raw milk and 2 VCF RO retentate at 4000 rpm
for 5 min at 4°C, 10°C, 20°C, 30°C and 40°C.
Assistance from GEA Westfalia, Germany, came to perform the pilot plant centrifugation trials, at the
AU Foulum facilities. First, the centrifuge capacity was adjusted on water, then a pre-experiment on
raw milk, before the experiment on 1.5 VCF and 2 VCF RO retentate. It was intended to perform the
separation on a range of temperatures in order to fully evaluate the separation properties of the
retentate. However, the temperature was not possible to fully control, so only a very limited range of
samples were collected.
The milk composition was measured on a Foss MilkoScan through FTIR, but the skim milk from
retentate has values exceeding the limits of calibration. Thus, samples were sent to Eurofins
Laboratories for chemical analysis of fat and protein content.
Results and discussion
The results from the lab scale experiments showed that separation of retentate is possible, and
especially at 40°C the separation was very clear (Figure 12).
Figure 12: Pictures of samples of 2 VCF retentate and raw milk, centrifuged in the lab at 40°C. A
separation between cream and skim milk is seen.
The results from the pilot plant centrifuge (table 6) show that it is possible for both 1.5 VCF and 2 VCF
retentate to be skimmed to a fat level below 0.1 %, and still have a rather high fat content in the cream.
A higher loss of protein into the cream was observed, compared to what would normally be the case for
skimming of raw milk.
Table 6: Fat and protein content of 1.5 VCF and 2 VCF retentate before centrifugation, and the fat and
protein content in the skim milk and cream at different processing temperatures.
Processing
temperature
Fat content
(g/100g)
Protein content
(g/100g)
2 VCF feed
7.1 6.73
2 VCF skim 48 0.05 5.66
2 VCF skim 44 0.1 7.04
2 VCF skim 43 0.09 7.13
2 VCF cream 40 32.43 4.64
1.5 VCF feed
6.57 5.34
1.5 VCF skim 39 0.07 5.81
1.5 VCF
cream 43 22.05 4.23