Frozen, chilled and spray dried emu

Frozen, chilled and spray dried emulsions for whipped cream:Influence of emulsion preservation approaches on productfunctionality

abstract
This study compares the effect of frozen (
18 C) or chilled (4 C) storage, or spray drying approach of
emulsion on the physico-chemical, whipping and rheological properties of the resultant whipped creams
and/or their emulsions. The average particle size and apparent viscosity of spray dried emulsion were
significantly (p < 0.05) larger than those of frozen and chilled emulsions. The microstructural difference
was well correlated with the measured changes of particle size distribution. The flow curves of these
emulsions were best fitted with the Herschel-Bulkley model, showing pseudoplasticity. The partial
coalescence of fat droplets in powdered whipped cream (PWC) increased much slowly than other
emulsions, while whipped cream from chilled emulsion (CWC) exhibited greater partial coalescence of
fat than whipped cream from frozen emulsion (FWC) during whipping. Significant differences (p < 0.05)
of whipped cream under different processing (frozen or chilled storage and spray drying) were also
observed in yield stress, creep behavior and overrun.

1. Introduction
Whipped cream is a popular topping for desserts, cakes and
pastries. Creams arise mainly from the formation of a network by
partially coalesced globules. At present, whipped cream products
mainly rely on cold storage and transportation (i.e. at
18 ~
30 C)
for long-term stability, because of their inherent thermodynamic
instability.
Drying is one of the most commonly used food preservation
techniques, which may be a good approach to extending the shelflife
of perishable emulsion (Vega & Roos, 2006). Powdered whipped
cream (PWC) could be produced through homogenization and
spray drying, and then reconstituted in water to reform emulsion
before whipping. If the reconstituted cream still possesses good
whipping and organoleptic properties, such a drying approach
would greatly reduce cost and energy consumption at no expense
of cream product quality. There were only a limited number of
studies on PWC, especially on the effects of drying process on the
physical and rheological properties of PWC. Pyenson and Tracy
(1948) studied how the composition and spray drying process
influenced whipping and textural properties of powdered cream
for whipping.
Furthermore, although considerable published works studied
on the impact of heat treatment on the physico-chemical and
rheological properties of emulsion or foam, few studies focused on
the physical behavior and stability of whipped cream stored at
different low temperatures have been published. Cortes-Mu
noz, ~
Chevalier-Lucia, and Dumay (2009) found that low temperature
storage possessed issues related to the stability of emulsion due to
the variations of storage temperature. Therefore, it is worthwhile to
compare the effects of different shelf-life extending approaches (i.e.
chill or refrigerated storage versus spray drying approaches) on the
properties of traditional whipped cream and its emulsion.
Under these perspectives, the objective of this work was to
investigate how drying and frozen or chilled storage processes
affect the physico-chemical, microstructural, rheological, and
whipping characteristics of whipped cream. Optical microscopy
and scanning electron microscopy were used to visualize directly
the resultant cream emulsion and powders.
2. Materials and methods
2.1. Materials
Sodium caseinate (protein 95%) was obtained from New Zealand
Milk Products Co. (CA, USA). Sucrose ester (S1170) was donated by
Mitsubishi Chemical Co. (Tokyo, Japan). Polyglycerol ester triglyceryl
monostearate (TGMS) was supplied by Lonza Group Ltd. (NJ,
USA). Xanthan gum (80SP, food grade) was kindly donated by the
Cargill Group (Shanghai, China). Hydroxypropyl methylcellulose
(HPMC, food grade) was supplied by Dow Chemical Company
(Midland, MI, USA). Cocoa butter substitute BL-39 and BS-2000
were donated by Southseas Oil & Fat Industrial Inc. (Shenzhen,
China). Sodium dihydrogen phosphate and sodium hydrogen
phosphate were obtained from Guangzhou Reagent Company
(Guangzhou, China). Corn syrup was purchased from a local supermarket.
Oil Red O was from AMRESCO (Ohio, USA).
2.2. Preparation of cream emulsion, powder and foam
The water phase contained corn syrup (10%) and deionized
water (66.35%). The oil phase comprised 10% BL-39, 10% BS-2000,
0.90% sodium caseinate, 0.25% HPMC, 0.15% S1170, 1.80% TGMS,
0.25% xanthan gum, 0.10% sodium dihydrogen phosphate, and
0.20% sodium hydrogen phosphate. The two phases were mixed
together and stirred at 600 rpm and 60 C for 30 min for complete
hydration with a digital overhead stirrer (RW20, IKA Co. Ltd., Germany),
which were made in one batch. The balance was topped up
with deionized water to remain water amount fixed. The emulsions
were then homogenized twice using a 2-stage single-piston homogenizer
(APV-1000, Aluminium Plant & Vessel Co. Ltd.,
Denmark) with 40 MPa of pressure at the first stage and 10 MPa at
the second stage. The homogenized emulsions for whipped cream
were subsequently cooled to 15 C. Then a portion was used for
spray drying, a 2nd portion was hardened at
18 C overnight
(“Frozen Emulsion”, which would be thawed to 4 C before whipping),
whilst the remaining was stored at 4 C overnight (“Chilled
Emulsion”, which would be whipped immediately before use). For
powdered whipped cream, the homogenized and cooled emulsion
was subjected to spray drying on a laboratory scale spray dryer
(YC015, Pilotech equipment Company, Shanghai, China) with a
0.5 mm standard diameter nozzle and a water evaporation capacity
of 1500 mL/h. The feeding of emulsions was facilitated by a peristaltic
pump at a feed rate of 800 mL/h. The inlet and outlet temperatures
were maintained at 185 C and 90 C, respectively. The air
flow rate and atomization pressure were remained at 3 m3
/min and
0.3 MPa, respectively. The powders were collected from cyclone
and the dryer chamber by lightly sweeping the inner drying wall.
The water activity of freshly prepared powders was 0.4737 ± 0.0030
at 25 C (AquaLab water activity meter, 4 TE, Decagon devices, USA).
The powders were reconstituted in deionized water in a proportion
of 1:1.3 to rehydrate (“Spray dried emulsion”) in a stainless steel
barrels with cover at 4 C overnight before whipping. Chilled,
frozen, spray dried emulsion were prepared in one batch from the
original emulsion, respectively.
All kinds of emulsion samples were whipped with a kitchen
planetary mixer (KM800, Kenwood Ltd., UK) for 0e6 min at speed
setting 5 (approximately 160 rpm) at ambient temperature. After
whipping procedure, the whipped creams derived from the emulsions
after freezing, chilled storage and spray drying were ready for
analyses (i.e. termed FWC, CWC and PWC, respectively).
In addition, following the steps above, another batch of samples
was made several days later. Subsequent determinations for all
samples (including emulsions and whipped creams) of different
batches were done in triplicate, respectively.
2.3. Optical microscopy and scanning electron microscopy (SEM)
The three types of emulsions before whipping were diluted 10-
fold with deionized water, placed on a glass slide and covered with
cover slip. Microscopic observation was taken under 400
magnification (objective lens 40 and eyepiece 10) using a light
microscope Olympus CX31 (Olympus, Tokyo, Japan) equipped with
a digital camera MShot MD130 (Guangzhou Mingmei Technology
Co., Ltd., Guangzhou, China). Microscopic images were processed
by software Micro-Shot Basic (version 1.0).
A small amount of spray dried PWC powders were mounted on
the double-sided adhesive tape attached to a circular aluminum
stub, and sputter-coated for 5 min with 20 nm gold in a highvacuum
evaporator. Observations were performed by scanning
electron microscopy (SEM) with a field-emission gun (S-3700N,
Hitachi, Tokyo, Japan) at an accelerating potential of 15 kv with
800 or 4000 magnification.
2.4. Determination of particle size distribution
The particle size distribution and average diameter of emulsion
samples, which had been whipped for 0, 1, 2, 3, 4, 5 and 6 min, were
determined by Malvern Mastersizer 2000 (Malvern Instruments
Co. Ltd., Worcestershire, UK). Each type of emulsion was measured
in triplicate. The refractive index and adsorption of the dispersed
phase were set as 1.414 and 0.001, respectively, and the refractive
index of the continuous phase was 1.330 (Long, Zhao, Zhao, Yang, &
Liu, 2012). The testing emulsion in the sample chamber was diluted
1000-fold with deionized water. The volume weighted average
diameter (d4,3, mm) was calculated by Eq. (1).
d4;3 ¼ Xnid4
i
.Xnid3
i (1)
where ni is the number of particles with the same diameter; di is the
particle size.
2.5. Measurement of rheological properties
Emulsion and foam samples were analyzed in situ using the
Mars III rheometer (Thermo Haake Co. Ltd., Karlsruhe, Germany)
equipped with a Universal Temperature Controller System (Thermo
Haake Co. Ltd., Karlsruhe, Germany). The data of the rheological
measurements were processed using the Rheowin Data Manager
software Version 4.30 (Thermo Haake Co. Ltd., Karlsruhe, Germany).
The testing samples were gently placed between the flat
plates, the excess ones were removed cautiously with a spatula. All
the rheological measurements were done in triplicate and
controlled at 20 ± 1 C with a fixed gap distance of 1 mm.
Both shear stress and apparent viscosity showed dependence on
shear rate or time in the controlled rate mode. The measurements
were carried out using a P60 TiL polished sensor. The shear rate was
linearly increased from 0.1 to 100 s
1 for 150 s, with 100 data points
being collected. The Herschel-Bulkley model (Anton, Chapleau,