effect of solubilised carbon dioxide at low partial
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Effect of solubilised carbon dioxide at low partial pressure oncrystallisation behaviour, microstructure and texture of anhydrousmilk fat
Tuyen Truong, Martin Palmer, Nidhi Bansal, Bhesh Bhandari
PII: S0963-9969(17)30087-XDOI: doi: 10.1016/j.foodres.2017.02.022Reference: FRIN 6605
To appear in: Food Research International
Received date: 29 November 2016Revised date: 22 February 2017Accepted date: 26 February 2017
Please cite this article as: Tuyen Truong, Martin Palmer, Nidhi Bansal, Bhesh Bhandari, Effect of solubilised carbon dioxide at low partial pressure on crystallisation behaviour,microstructure and texture of anhydrous milk fat. The address for the corresponding authorwas captured as affiliation for all authors. Please check if appropriate. Frin(2017), doi:10.1016/j.foodres.2017.02.022
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Effect of solubilised carbon dioxide at low partial pressure on
crystallisation behaviour, microstructure and texture of anhydrous milk fat
Tuyen Truong, Martin Palmer, Nidhi Bansal, Bhesh Bhandari*
ARC Dairy Innovation Hub
School of Agriculture and Food Sciences, the University of Queensland, QLD 4072,
Australia
Abstract
The crystallisation and melting behaviour, fat polymorphs, microstructure and texture of
anhydrous milk fat (AMF) was investigated in the presence of dissolved CO2 (0 – 2000 ppm)
under two crystallising conditions (non-isothermal versus isothermal). CO2 was found to
induce higher onset crystallisation temperature during cooling from 35 to 5oC at 0.5
oC min
-1.
X-ray scattering analysis showed that, in the presence of dissolved CO2, this rapid
crystallisation caused the formation of unstable, polymorph fat crystals. For milk fat
crystallised under isothermal condition at 25oC for 48h, dissolved CO2 improved solid fat
content, slightly depressed melting temperature and exhibited a sharper melting peak.
Microstructure of AMF visualised by Polarised light microscopy of crystallised AMF showed
that increasing dissolved CO2 concentration was associated with smaller crystal size and
greater crystal number. The bulk properties of the fat appeared to mirror the microstructural
differences, in that the texture of CO2-treated AMF was harder under isothermal condition
but became softer than untreated AMF under cooling condition. The results of this study are
of significance in understanding how CO2 treatment might be used to modulate the
crystallisation behaviour of milkfat and thereby the structural development and physical
functionality of fat-containing dairy products.
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Keywords: AMF; milkfat; crystallisation; CO2; microstructure; texture
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1. Introduction
Milk fat is an important determinant of quality and functionality in milk and dairy products.
Milk lipids comprise 98% triacylglycerols (TAG) and have a widely varied fatty acid
composition with more than 400 species (Christie, 1995). The melting point range of milk
lipids is correspondingly wide, varying in temperature from -40 to 40oC and commonly
exhibiting three overlapping endotherms. These correspond to three incompletely miscible
fractions of milk fat (low-, middle-, and high-melting point fractions). In its solid state, milk
fat consists of a mixture of crystals with three main polymorphic forms (, ’, and ), of
which ’ polymorph is dominating (Sato, 2001). The type of fat crystal network, which is
dependent on the particular combination of fat polymorphs and the crystal habit (size and
shape), determines the microstructure of milk fat, which in turn, helps to determine the
physical functionality of dairy products such as butter, cheese and whipped cream (Danmark
& Bagger, 1989; Goff, 2002; Lopez, Camier, & Gassi, 2007; Moens, Masum, & Dewettinck,
2016). Therefore, being able to understand and control the crystallisation behaviour of milk
fat is essential in manufacturing fat-structured dairy products of consistent quality.
For bulk fat, crystallisation behaviour is governed by fat composition, cooling rate and
processing conditions. Fat crystallisation can also be influenced by dissolved or suspended
entities present in the fat. Most crystallisation occurs in complex food systems with more
than one ingredient. Ingredients may be present as natural admixtures or impurities or they
may be deliberately incorporated as additives in food formulations. Such ingredients may
have a considerable effect on nucleation and crystal growth mechanisms and kinetics, thus
impacting crystallization structure and properties of fat or other components (Hartel, 2001).
In fact, impurities are commonly found to inhibit or facilitate nucleation and crystallisation,
leading to the use of compounds like glycerol monooleate or sucrose esters, which are added
to control crystallization in some fat systems. The presence of these additives acts to
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influence the inter-solubility of low and high melting point TAGs, thereby influencing the
crystallisation behaviour of the high melting point TAGs.
Carbon dioxide (CO2) is a hydrophobic gas that is soluble in milkfat and other lipids. This
gas is used in many modified atmospheric packaging systems for fruits, vegetables, drinks,
meat and cheese. This gas also has the highest solubility in both muscle and fat tissues among
other gases (Gill, 1988; Mitz, 1979) and higher solubility in water than nitrogen (N2) (50–70
times less) or oxygen (O2) (25–35 times less soluble) (Jakobsen & Bertelsen, 2006; Jakobsen,
Jensen, & Risbo, 2009; Mitz, 1979). The gas solubility coefficients of N2, O2 and CO2 in
hydrogenated lard at 65oC are reported as 0.0844, 0.145 and 0.920 vol /vol fat, respectively
(Formo, 1979). Our previous study (Truong, Palmer, Bansal, & Bhandari, 2017) showed that
CO2 is highly soluble in anhydrous milk fat (AMF) with a solubility coefficient of 1648 ppm
kg fat-1
atm-1
. The dissolution behaviour appeared to be dependent on both intrinsic (partial
pressure and temperature) and extrinsic variables (fatty acid composition and physical state
of the AMF).
When CO2 is in its supercritical phase (above 31.1oC and 7.38 MPa), it can be employed in
various food applications such as removal of undesirable components in food (i.e. cholesterol
in milk fat, milk powder and alcohol in cider), encapsulation of liquids, extraction of
carotenoids and natural complex (i.e. phenols and tannins) (Bradley, 1989; Brunner, 2005;
Chitra, Deb, & Mishra, 2015; Murga, Ruiz, Beltran, & Cabezas, 2000; Sun & Temelli, 2006).
Being soluble in lipids, CO2 can take part in the crystallisation process, in turn, affecting the
product property. It was reported that supercritical CO2 impacted on the crystallisation and
melting properties of polymers such as polypropylene and polystyrene (Cao et al., 2014). In
food-related system, recently Uniliver has patented a new process known as “Supercritical
Melt Micronisation (ScMM)” which is a spray crystallisation technology in which fat melt is
saturated with CO2 at high pressure and atomised through a nozzle (Bezemer, Huizinga, &
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Malseen, 2012). Due to the rapid pressure drop at the nozzle, the CO2 evaporates causing
rapid super-cooling, crystallisation and expansion of the fat particles. The extremely porous
nature of the fat particles allows blending it with oil to make a stable fat spread. This is due to
the adsorption of oil into the pores of fat. This is a high pressure process and requires
specialised equipment. To the best of our knowledge, there is no published research on the
influence of CO2 at low pressure on the crystallisation behaviour, microstructure and
functionality of an edible fat system.
This study aimed to investigate effect of dissolved CO2 at low partial pressure (0 – 1 atm) on
the crystallisation, microstructural and textural properties of AMF, with a view to exploring
the industrial potential of this technique to manipulate the functional properties of fat-
structured dairy products.
2. Materials and Methods
2.1 Materials
Anhydrous milk fat was purchased from Rogers & Company Foods Pty Ltd (Hampton East,
Victoria, Australia). It was stored in cold room (4oC) until use. Dry ice, the solid form of
CO2, was supplied in pelleted form by University of Queensland (Brisbane, Australia). Dry
ice was stored in foam box at -80oC to prevent sublimation. Weight of individual dry ice
pellets was approximately 1 -3 g. The transformation of solid CO2 (dry ice) to gas phaseCO2
happens at -78.5oC, which is its sublimation point at atmospheric pressure (Perry & Green,
2007).
2.2 Dissolution of CO2 into AMF
CO2 was dissolved into AMF using a home-made apparatus, which is fitted with a digital
manometer (DC-400, GTS Gauges Transmitters Switches, Midvale, Western Australia)
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connected to the screw cap of a Schott bottle (0.627 L) (Truong et al., 2017). When the dry
ice was placed into the container and the screw cap immediately closed, the dry ice
sublimated in the closed system. In presence of the AMF, difference in gaseous
concentrations between the headspace and the sample is a driving force for a gas transfer
until the equilibrium state is obtained. Since this apparatus was operational in a static and
batch modes, the known amount of initial dry ice and the partial pressure reading allowed
calculation of the dissolved CO2 concentration into the milk fat sample (in continuous mode
without opening the system) as follows:
s
headspaceCO
eqCORTW
MwCOVpC
2
.2
2
1000 [Eq. 1]
where CCO2 eq. is the equilibrium amount of dissolved CO2 (ppm by mass) taking into account
any related dissociation and hydration products, pCO2 (pCO2 initial – pCO2 final) is the
difference in partial pressure drop due to CO2 gas adsorption into sample, Vheadspace is the
headspace gas volume (L), MW is the molecular weight of CO2 (44.01 g mol-1
) and Ws is the
weight of the milk fat (kg).
2.3 Experimental procedure
Figure 1 depicts the experimental procedure. The AMF was completely melted at 70oC for 1
h and cooled to 35oC. At 35
oC, dry ice was added into liquid AMF at three concentrations (0,
1000, and 2000 mg kg-1
) and equilibrated for 24 h in an incubator, also at 35oC. Dissolution
of CO2 into AMF was monitored by changes in partial pressure, as described above.
Investigation of the effects of dissolved CO2 on the physical properties and crystallisation
behaviour of the AMF was then undertaken under two crystallising conditions:
(a) The first scheme involved non-isothermal (cooling) crystallisation of the AMF, from
35 to 5oC at a cooling rate of 0.5
oC min
-1. Nucleation and fat crystal growth of the
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control and CO2-treated AMF were examined in the first 60 min of solidification
process by polarised light microscopy. In parallel, 40 mL of each sample was sub-
divided into a plastic container and allowed to cool to 5oC. The sub-samples were
stored at 5oC for 48h and then measured for CO2 retention, hardness and thermal
properties.
(b) In the second scheme, the control and CO2-treated AMF was cooled from 35 to 28oC
at a cooling rate of 0.5oC min
-1 and isothermally crystallised at 28
oC. Examination of
the crystal habit during solidification process for 60 min was undertaken at 28oC,
using polarised light microscopy. Sub-samples (40 mL each) were immediately
transferred into plastic container and allowed to cool to room temperature (25oC).
Similar to the first scheme, after 48 h of storage, measurements of CO2 retention,
hardness, and thermal properties were also carried out.
2.4 Measurements
2.4.1 Absorption and retention of CO2 into AMF
The CO2 concentration dissolving into liquid AMF after 24 h of equilibration at 35oC was
calculated according to Eq. 1. The CO2 retention level in (semi-) solid AMF after storage for
48 h at either 5 or 25oC was measured using the titration method described by Jakobsen and
Bertelsen (2006). In this method, two 100 mL Buchner flasks, one containing 0.5M H2SO4 (5
mL) and the other containing a standardised Ba(OH)2 solution 0.1N, were connected by
neoprene tubing. Approximately 2 g of the sample was placed into the flask containing
H2SO4 solution. Upon equilibration for 18 – 24 h, CO2 was evolved and reacted with the
standardised Ba(OH)2, yielding precipitated BaCO3. Standard HCl solution (0.1 M) was used
to titrate the residual amount of Ba(OH)2 with phenolphthalein as the indicator.
2.4.2 Differential Scanning Calorimetry (DSC)
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Crystallisation and thermal properties of the AMF were measured using a Differential
Scanning Calorimeter (DSC1 STARe System, Mettler-Toledo, Schwerzenbach, Switzerland).
Calibration were undertaken using an indium standard (melting point = 156.66°C, ΔH
melting = 28.41 J g-1
). Approximately 10-15 mg of AMF was placed in a 40 μL aluminium
pan, which was then hermetically sealed (an empty pan was used as a reference).
Crystallisation properties of the sample were investigated in cooling mode (#1 scheme) while
heating profile was monitored for both schemes. The sample in #1 scheme was cooled in the
DSC pan from 35 to 5oC at a cooling rate of 0.5
oC min
-1. Regarding thermal properties,
depending on the investigation scheme, the DSC pan was heated from either 5oC or 25
oC to
60oC at a heating rate of 5
oC min
-1 to measure endpoint of melting (TM-endset) and melting
enthalpy (HM). Solid fat content (SFC) was calculated based on the relative proportion of
total melting enthalpy to that of reference (bulk milk fats solidified at -70oC). STAR
e
Excellence Software (Mettler-Toledo, Schwerzenbach, Switzerland) was used to analyse
thermographs. All measurements were performed at least in duplicate.
2.4.3 Small and wide angle X-ray scattering (SAXS/WAXS)
Structure and polymorphs of fat crystals in solid state at 5oC (#1 scheme) were examined
using a SAXSess mc2 combined SAXS/WAXS spectrometer (Anton Paar GmbH, Graz,
Austria) as described elsewhere (Truong, Morgan, Bansal, Palmer, & Bhandari, 2015).
Briefly, the sample was placed in a paste cell (CAT. 17233, Anton Paar GmbH, Graz,
Austria), which was previously cooled at 5oC. The paste cell was then inserted to a pre-
chilled sample holder at 5oC. Equilibration was undertaken in the sample holder at 5
oC for 30
min before measurement at the same temperature for 20 min. Peakfit software (SeaSolve
Software Inc., San Jose, CA, US) was used to analyse the SAXS/WAXS peak position and
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peak area (integrated intensity) as detailed by Lopez, Lavigne, Lesieur, Bourgaux, and
Ollivon (2001a).
2.4.4 Polarised light microscopy (PLM)
Nucleation and growth of fat crystals were observed using PLM. An aliquot of AMF (10 L)
was pipetted onto a microscope slide, which was then placed onto a LTS120 sample chamber
connected to a PE-95 Linkpad temperature controller (Linkam Scientific Instruments, UK).
This Peltier controlled system covers working temperature from -40oC to 120
oC with 0.1
oC
temperature control and stability. The pipette tip, microscopic slide and cover slip were all
pre-warmed at the investigated temperature (i.e. 35 or 28oC) before sampling. Observation of
microstructure of AMF was conducted using an Olympus CX41 microscope (Tokyo, Japan)
at 4 magnification. Image analysis was undertaken by ImageJ software (Schneider,
Rasband, & Eliceiri, 2012).
2.4.5 Texture analysis
Hardness of the AMF, expressed as the maximum force (N), was measured using a texture
analyser (TA.TX2 Stable Micro Systems, UK) (Wright, Scanlon, Hartel, & Marangoni,
2001). In a compression test mode, the 2 mm cylindrical probe was set to travel a distance of
10 mm with test speed of 1 mm s-1
. Each measurement was triplicated. The longer-term effect
of CO2 on hardness of the AMF was also examined after 9 days of storage.
2.4.6 Statistical analysis
All measurements were done at least in duplicate. Statistical analyses of the data were
conducted using the statistical package MINITAB ® Released 16 (Minitab Co., US). One-
way ANOVA and Tukey’s LSD was employed to determine significant differences of
treatment means at P<0.05.
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3. Results and Discussion
3.1 CO2 absorption and retention
Table 1 summarises the dependence of dissolved CO2 concentrations on initial CO2
concentrations, showing that CO2 solubilities increased with increasing initial CO2
concentrations. CO2 was highly dissolved in liquid AMF at 35oC/24 h with 953 and 1887
ppm for 1000 and 2000 ppm of initial concentrations, respectively. This agreed well with our
observation in the previous study on solubility of CO2 in AMF (Truong et al., 2017). When
AMF was cooled either from 35 to 5oC (#1 scheme) or 35
oC to 25
oC (#2 scheme) and then
stored at the final temperatures for 48 h, retention of CO2 was still more than 60% at all
conditions (Table 1). Accordingly, any observed modifications in physical and textural
properties can then most likely be ascribed to the presence of dissolved CO2.
3.2 Crystallisation and thermal properties
Crystallisation and thermal properties of AMF was measured using DSC. For the #1 scheme,
all AMF samples showed similar DSC cooling patterns with two main crystallisation peaks
(Figure 2A), indicating the crystallisation of high- and low-melting point TAGs. It is clear
that CO2 promoted the nucleation process in the first 60 min of solidification during cooling
from 35 to 5oC (Figure 2A). The onset crystallisation temperature of AMF under CO2
dissolution (23.8 and 25.3oC) was significantly higher than that of original AMF (19.2
oC)
(Table 2). Crystallisation enthalpies also slightly increased with higher amounts of dissolved
CO2. This increasing trend in crystallisation parameters could be explained by CO2 acting as
a template for crystallisation of AMF. In other studies, both hydrophobic and non-
hydrophobic additives have been reported to promote lipid crystallisation (Smith, Bhaggan,
Talbot, & van Malssen, 2011; Yoshikawa, Kida, & Sato, 2014). Hydrophobic additives
having similar configuration chemically or structurally (monoacylglycerols, monopalmitin) to
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lipids can act as seeding nuclei for lipid crystallisation (Fredrick et al., 2013; Verstringe,
Danthine, Blecker, Depypere, & Dewettinck, 2013) while non-hydrophobic additives
(inorganic particles: carbon nanotube, graphite, and talc; organic molecules: theobromine,
terephthalic acid) can interact with lipid molecules via hydrophilic interactions (Yoshikawa et
al., 2014). Being a soluble gas, it is possible that CO2 could promote crystal nucleation during
cooling. However, it seems that the effect of supercooling was dominating in the #1 scheme
as the differences in melting properties of the CO2 dissolved AMF after cooling and storing at
5oC for 48 h were not statistically significant (Table 2). DSC thermal profiles of both non-
treated and CO2-treated AMF in the #1 scheme were similar with three major melting peaks
at 5-10oC, 10-23
oC, and 23-39
oC. In contrast, influence of absorbed CO2 on melting
properties of AMF was more pronounced in #2 scheme, which had no supercooling. While
the low melting peaks (range of 25-30oC) of the three samples remained unchanged, the
endset melting point was slightly depressed (Table 2). The main melting peak (range of 30 –
43oC) at 2000 ppm addition was shifted to a lower temperature (34
oC) and sharper than those
of the lower CO2 concentration (37oC) (Figure 2C), indicating melting of more uniform fat
crystals. Furthermore, melting enthalpy (indicating for relative crystallinity or solid fat
content) was enhanced with increasing dissolved CO2 concentration (Table 2). This result
agrees with observations on crystallisation of polymers that dissolved CO2 facilitates mobility
of polymer chains and enhances crystal growth, resulting in increased crystallinity of
polymers (Cao et al., 2014; Lei, Ohyabu, Sato, Inomata, & Smith, 2007; Nofar, Zhu, & Park,
2012).
3.3 Fat polymorphs
As dairy products are generally stored under refrigeration, further characterisation of fat
crystals formed in the #1 scheme was performed by X-ray scattering at 5oC. As shown in
Figure 3, X-ray scattering patterns of TAG in all samples showed a typical profile of milk fat
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(Truong et al., 2015). In the SAXS region, double- (2L) and triple-chain length (3L)
structures were noted for TAG longitudinal packings. In the WAXS region, ’ and fat
polymorphs were detected, representing TAG lateral packings. Noticeably, when AMF was
crystallised in the presence of CO2, AMF exhibited a peak at 4.15 Å, representing fat
crystals. Previous study reported that formation of less close-packed fat crystals indicates
occurrence history of rapid crystallisation and/or a higher number of fat crystals (Lopez,
Lavigne, Lesieur, Bourgaux, & Ollivon, 2001b). In this study, this is consistent with the
earlier crystallisation temperatures measured by DSC (Table 2) and higher number of
crystals seen by microscopy as discussed later (section 3.4). In addition, as the proportion of
phase represented about one-third (34 = 36%) of the total crystalline phases (Table 3), it
would be expected that melting temperatures and melting enthalpies of CO2 –treated AMF
would be lower compared to the untreated sample. However, no association between crystal
polymorph type and melting properties was observed. This might be ascribed to the
dominating effects of the ’ and crystal forms in melting characteristics. In other words, the
increase in crystal proportion was insufficient to induce a noticeable decrease in melting
properties. Previous study on crystallisation of other lipid materials also reported insignificant
correlation between crystal structures and melting behaviour under some specific conditions
(Frydenberg, Hammershoj, Andersen, & Wiking, 2013).
3.3.1 Microstructure
Figure 4 shows the evolution of AMF microstructure during cooling from 35 to 5oC at 0.5
oC
min-1 (
#1 scheme). The first visible fat crystals in CO2-treated AMF were detected at 22.5oC,
which was earlier than that of the untreated AMF (20oC). This observation was very close to
values obtained from DSC at the same cooling rate (Table 2). Quantitative analysis of PLM
images on solid fraction area and number of crystals (Figure 5 A&B), demonstrated that
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crystal nucleation happened faster and a larger number of fat crystals formed in the CO2 -
treated AMF. This was consistent with X-ray scattering, which showed crystal formation in
the presence of CO2. Figure 5A shows that, solidification was faster in the CO2 -treated
AMF, with the maximum solid fraction at 15oC while the untreated AMF had the highest
solid fraction at the end of crystallisation process (5oC). The number of fat crystals reached a
peak at 15oC and decreased, presumably due to crystal-crystal interaction to form bigger
crystals at lower temperatures (Figure 5B). At 5oC, the solid fraction and number of crystals
of CO2 –treated AMF were only slightly higher than the values for the control sample (Figure
5 A&B). This indicates that induction of crystallisation was promoted by dissolved CO2
during cooling. However, in this case the effect of dissolved CO2 was not carried over to the
end of the cooling regime as the microstructure of all AMF samples was quite comparable at
5oC. This means the effect of supercooling overrules the effect of dissolved CO2 obtained
during nucleation. When AMF was crystallised isothermally at 28oC (#2 scheme), crystal
morphology was similar for all treatments, with well-formed spherulites present in all
samples. However, there were marked differences in fat crystal size and number of fat
crystals. For each time point, smaller crystals and more crystals were observed with
increasing dissolved CO2 concentration (Figure 6). Quantification of solid fraction and
particle counts based on PLM images showed that crystal nucleation was induced much faster
on 2000 ppm CO2 addition (Figure 5 C&D). For example, after 20 min of crystallisation at
28oC, the solid fraction in 2000 ppm CO2-treated AMF (4%) was 2 to 3-fold greater than that
at the lower CO2 concentration or control (Figure 5C). Correspondingly, AMF treated with
2000 ppm CO2 yielded about 2 to 3 times more crystals than that of the 1000 ppm treatment
and control sample at 20 min of crystallisation (Figure 5D). The increasing trend of both
solid fraction and crystal counts in 2000 ppm added AMF continued until the end of
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experiment duration (90 min). This implies that CO2 also promotes crystal growth, even over
longer crystallisation times.
3.3.2 Hardness
The physical and functional properties of lipids are greatly governed by their
crystallisation/melting behaviour. For both schemes investigated , i.e. cooling and isothermal
crystallisation, it is obvious that presence of dissolved CO2 impacted on the
crystallisation/melting profiles, the fat polymorphs and the microstructure of fat crystal
network formed. These differences resulted in changes in hardness of AMF at specific
conditions as illustrated in Figure 7. Hardness of AMF stored at 25oC significantly increased
with increasing CO2 concentration (P < 0.05). This result is in accordance with the DSC and
PLM results, showing that AMF exhibited a sharper melting profile, greater degree of
crystallisation, smaller crystal sizes and larger number of crystals in the presence of dissolved
CO2. Interestingly, under refrigeration conditions, softer texture was observed in the CO2 -
treated AMF (P < 0.05) even though its melting properties were very similar to those of the
untreated AMF. In fact, the larger number of small fat crystals in the CO2-treated AMF
provided more contact points in the fat phase, the rigidity of the fat crystal network should be
enhanced. Thus the texture of CO2-treated AMF should be harder in this case (as
demonstrated at 25oC). The opposing result suggests that the hardness of AMF depends on
many interrelated factors. Possible explanations for softer texture of CO2-treated AMF fat
crystal network at 5oC may have been due to (i) the presence of the larger proportion of
crystals induced by CO2 addition (Figure 3); (ii) an important role of interaction strength
between structural elements of fat crystal network (i.e. fat crystal/fat crystal interactions) and
(iii) the interference of embedded gas bubbles in the rigidity of the fat crystal network.
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Figure 7 also shows that there was a slight increase in hardness of all AMF samples when
measuring texture again after 9 days of storage. However, these changes are not statistically
significant different (P > 0.05) between day 2 and day 9 of storage duration (Figure 7). The
changes in hardness of AMF in longer term is related to post-crystallisation phenomenon,
which might be attributable to polymorphic transformations, evolution of new crystals and
presence of solid bridges between structural components (Johansson & Bergenstahl, 1995).
4. Conclusions
This study demonstrates the impact of dissolved CO2 at low partial pressure on
crystallisation, melting behaviour, microstructural and textural properties of AMF under two
contrasting (isothermal vs. non-isothermal) crystallisation regimes. CO2 promoted crystal
nucleation and growth under both crystallisation conditions, as well as an accumulation of the
metastable fat crystal polymorph. CO2 treatment also resulted in a reduction in crystal size
and increase in total number of fat crystals, which in turn, affecting the hardness of AMF at
both 25 and 5oC. These initial results suggest that there may be some potential for industrial
use of CO2 to modulate the physical functionality of milkfat. Further studies are now needed
to investigate whether these effects are also apparent in more complex systems, such as butter
and dairy blends. It will also be critical to understand the optimum amounts of CO2 required
to generate the desired effects as well as the possibility of any concomitant changes to
sensory properties and chemical stability.
Conflict of interest
There are no conflicts of interest regarding this paper.
Acknowledgements
This research was supported under Australian Research Council's Industrial Transformation
Research Program (ITRP) funding scheme (project number IH120100005). The ARC Dairy
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Innovation Hub is a collaboration between The University of Melbourne, The University of
Queensland and Dairy Innovation Australia Ltd.
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Figure 1. Flow chart of experimental plan
Figure 2. Representative cooling and heating profiles of AMF subjected two crystallisation
conditions: cooling from 35 to 5oC at 0.5
oC min
-1 (A), stored at 5
oC for 48h and heated from 5 to 60
oC
at 5oC min
-1 (B - #1 scheme); heating only from 25 to 60
oC at 5
oC min
-1 upon solidification of AMF at
25oC/48 h (C- #2 scheme).
Figure 3. Longitudinal and lateral packings of the AMF at various dissolved CO2 concentrations at
5oC upon 48 h of storage (#1 scheme).
Figure 4. Polarised light micrographs of AMF during cooling from 35 to 5oC at cooling rate of 0.5
oC
min-1
.
Figure 5. Percentage of area fraction (degree of crystallisation) and number of particle counts (crystal
number) in AMF as a function of dissolved CO2 levels during cooling (A & B) and isothermally
crystallised at 28oC (C & D) conditions.
Figure 6. Effect of dissolved CO2 concentration on milk fat crystal habit upon isothermally
crystallisation at 28oC for first 90 min.
Figure 7. Impact of dissolved CO2 concentration on AMF hardness upon storage for 2 and 9 days at
the two crystallising conditions; for each storage temperature regime (i.e. 25 and 5oC), same letter
denotes insignificant difference (P <0.05) among three levels of carbonation.
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Table 1. Absorption and retention of CO2 (mg kg-1
) in the AMF
Initial CO2
conc.
Dissolved CO2 at
35oC/ 24 h
CO2 retention at
5oC/48 h
CO2 retention at
25oC/48 h
0 2228 2228 2228
1000 95312 82320 63757
2000 188727 137930 120035
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Table 2. Effect of dissolved CO2 on crystallisation and thermal properties of AMF under the two crystallisation
conditions
Initial CO2
level
TC-onset Crystallization
enthalpy
TM-endset Melting
enthalpy
mg kg-1 o
C J g-1 o
C J g-1
#1 scheme (supercooling)
0 19.2±0.4 b 34.6±5.6
a 38.5±0.1
a 104.1±3.6
a
1000 23.8±1.3 a 37.7±1.3
a 39.8±1.0
a 110.3±2.6
a
2000 25.3±1.6 a 40.0±0.1
a 40.4±1.5
a 111.3±6.6
a
#2 scheme (isothermal)
0 n/a n/a 43.7±0.2 a 33.0±1.1
b
1000 n/a n/a 43.7±0.0 a 31.8±0.9
b
2000 n/a n/a 43.4±0.1 b 43.0±1.0
a
For each scheme, the superscript shared the same letter at the same column had no significant difference (P <
0.05)
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Table 3. Effect of dissolved CO2 concentrations on relative proportion of TAG longitudinal and lateral
structures of the AMF
CO2 level 3L 2L Proportion of polymorph forms
under total WAXS scattered peaks,
% SAXS
peak
% area SAXS
peak
% area ’
0 ppm 64.18 Å 17.97 41.63 Å 82.03 0.0 80.2 19.9
1000 ppm 65.59 Å 33.91 41.54 Å 66.09 36.2 50.9 12.9
2000 ppm 63.84 Å 28.36 41.93 Å 71.64 34.1 53.7 12.2
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HIGHLIGHTS
Dissolved CO2 induced higher onset crystallisation upon cooling of AMF
Dissolved CO2 caused formation of unstable, polymorph fat crystals
Carbonation on AMF modified thermal properties and texture of AMF
CO2 treatment resulted in a reduction in crystal size in microstructure of AMF
Dissolved CO2 can be used to modulate the physical functionality of milkfat
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