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Engineering, Technology & Applied Science Research Vol. 6, No. 5, 2016, 1162-1166 1162  
  

www.etasr.com Ebrahimi et al.: Effect of Pre-gelatinized Wheat Starch on Physical and Rheological Properties of... 
 

Effect of Pre-gelatinized Wheat Starch on Physical 
and Rheological Properties of Shortened Cake Batter 

and Cake Texture  
 

Fatemeh Ebrahimi 
Department of Food science and 
Technology, Ayatollah Amoli 

Branch 
 Islamic Azad University 

Amol, Iran.  

Babak Ghiassi Tarzi 
Department of Food science and 

Technology 
Science and Research Branch 

Islamic Azad University  
Tehran, Iran 

Maryam Asghari  
Department of Food science and 

Technology  
Science and Research Branch 

Islamic Azad University 
Tehran, Iran 

 

 

Abstract—The focus of this study was the effect of 1.5%, 3% and 
4.5% pre-gelatinized wheat starch (based on the total weight of 
cake batter) on improving the qualitative properties of shortened 
cake batter. Specific volume and viscosity of the shortened cake 
batter were measured for controls, 1.5%, 3% and 4.5% 
gelatinized starch; some important properties such as texture and 
sensory evaluation were examined. By increasing pre-gelatinized 
wheat starch used in the batter, a significant difference was 
observed in the rheological properties of the batter. Cake batter 
properties were found improved compared to the control 
samples. The sample with 3% pre-gelatinized starch had a lower 
viscosity than other treatments. The treatment with 4.5% pre-
gelatinized starch had the lowest specific volume compared to 
other treatments. The overall results showed that the shortened 
cake with 3% pre-gelatinized starch was the best treatment in 
terms of texture and sensory evaluation factors. 

Keywords-pre-gelatinized wheat starch; rheological properties; 
shortened cake batter; viscosity 

I. INTRODUCTION  
Currently, there are many producers of baking products 

such as breads, cakes, muffins and biscuits in Iran. According 
to the Association of Iranian Confectionery Manufacturing 
Companies, over 240,000 tons of cake is produced annually for 
use in domestic and foreign markets [1]. One of the important 
problems with cakes is that they stale fast. They quickly lose 
their freshness within a few days and become leathery and 
hardly chewable. Economically, it is important to keep cakes 
fresh. Flat cakes have generally very short shelf life; thus, 
additives such as modified starch can improve their quality [2, 
3]. The main ingredients of cake are flour, sugar, eggs and fat, 
each of which has an important role in the structure and quality 
of the product [4]. Extensive research has been conducted on 
the material and process conditions of cake products. Variety, 
quality and shelf life of cakes are always a concern of 
researchers. The improved cooking methods, storage at certain 
temperature and additives improve texture, strengthen the 
gluten network, provide softness and smoothness and postpone 
staling.  

Instant starches or hydro-colloids added to baked goods can 
increase moisture survival [5, 6]. Moisture content is an 
important parameter for staling, because retro gradation of the 
starch is reduced with increasing moisture content [5, 6]. In [7], 
wheat starch was replaced by 3, 5 and 7% retrograded waxy 
corn starch to produce bread and evaluated rheological 
properties of the batter and sensory properties of the breads by 
farinograph and extensographic after 24, 48 and 72 hrs. Results 
of the rheological tests showed that this starch increase water 
absorption. In general, the replaced starch quickly increased 
viscosity; however, it was not able to keep its stability. The 
batter made by the replaced starch was weaker and less stable 
than the batter made by wheat starch. Results of sensory 
evaluation showed higher acceptability for these breads; 
addition of 5-7% starch considerably improved shelf life of the 
bread. The breads remained softer and more humid during 6 
days of storage time [7]. In [8], it was shown that that moisture 
content increase shelf life of the product by 2%. Therefore, 
high moisture lost in bakery products is one of the reasons for 
accelerated staling of these types of products [8]. In [9], authors 
evaluated the effect of different types of starch (corn, potato, 
waxy maize and pre-gelatinized) added to cake formulation in 
order to delay staling of the cake and found that pre-gelatinized 
starch contributes to reduced moisture loss during cooking and 
storage and cakes containing pre-gelatinized starch are softer 
than the control cake. In [10], it was reported that the overall 
stiffness of cakes consists of two separate factors: 1) stiffness 
effects caused by moisture transfer to the crust and 2) internal 
stiffness of the cell wall matter associated with starch retro 
gradation during storage. In [11], authors studied the effect of 
rice starch on rheological properties of the batter at different 
temperatures. Rice starch was gelatinized at 20, 40, 60 and 90 
minutes. The results showed that gelatinization temperature 
increased by increasing the time to 60 minutes. The rice starch 
batter had higher viscosity and lower moisture content for a 
longer period of time. This is probably due to lower amylose 
and protein content of the modified starch batter. 



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www.etasr.com Ebrahimi et al.: Effect of Pre-gelatinized Wheat Starch on Physical and Rheological Properties of... 
 

II. MATERIALS AND METHODS 
Materials used to produce shortened cake batter included 

wheat starch, sugar, water, eggs, inverted sugar, oil, emulsifier, 
vanilla and baking powder as well as pre-gelatinized starch. 
Materials and equipment used for production of pre-gelatinized 
wheat starch included wheat starch, water and extruder. 
Materials used for physicochemical tests included buffer, 
petroleum ether, 2% boric acid, 0.1 N hydrochloric acid, 
50%NaOH, concentrated sulfuric acid, catalyst, reagent 
solution (methyl red + ethanol + methylene blue). 

A. Production of Pre-Gelatinized Wheat Starch 
To produce the pre-gelatinized wheat starch, wheat starch 

and water were mixed and pre-gelatinized in an extruder at 70-
100 °C and 30-80 rpm. Then, the water was evaporated in a 
dryer. The mixture was crushed to smaller pieces by a mill 
[12]. 

B. Production of Shortened Cake Batter 
To produce shortened cake batter, eggs, sugar and 

emulsifier were mixed by a mixer at high speed for 3 minutes 
(Table I). Then, oil and water were added to the mixture and 
stirredbya stirrerat high speed. Next, starch, vanilla, baking 
powder, inverted syrup, pre-gelatinized starch and salt were 
added and the mixture was stirred at medium speed for 3 
minutes [13]. To produce batter with the pre-gelatinized starch, 
three units of water per unit of pre-gelatinized starch minus the 
same amount of null flour were added to the mixture. 

TABLE I.  FORMULATION OF THE CONTROL AND SAMPLE CAKES 

R
aw

 
m

at
er

ia
l 

C
o

n
tr

o
l 

1
.5

%
 p

re
-

g
el

at
in

iz
ed

 
st

ar
ch

 

3
%

 p
re

-
g

el
at

in
iz

ed
 

st
ar

ch
 

4
.5

%
 p

re
-

g
el

at
in

iz
ed

 
st

ar
ch

 

Starch 36 34.5 33 31.5 
Oil 10 10 10 10 
Sugar 20 20 20 20 
Baking powder 1 1 1 1 
Emulsifier 1.5 1.5 1.5 1.5 
Egg 11 11 11 11 
Water 19.5 24 28.5 23 
Invert syrup 3 3 3 3 
Vanilla 0.1 0.1 0.1 0.1 
Pre-gelatinized 
flour 

0 1.5 3 4.5 

C. Tests for Pre-gelatinized Starch and Starch Used in the 
Formulation 

Moisture, ash and protein content of the starch were 
calculated by AACC 08-01, AACC 44-15 and AACC 46-13, 
respectively. Starch fat was evaluated according to the national 
standard of Iran. 

D. Tests for Batter 

Determination of Specific Volume 

Specific weight of the batter was calculated by measuring 
the weight ratio of 240 ml batter to 240 ml water [14]. Specific 
volume was calculated by the following formula: 

 waterdistilled 240ml ofweight 

batter 240ml ofweight 
= volumespecificBatter  

Determination of Batter Viscosity 

Viscosity of cake batter was measured by the Brookfield 
model, DV-II + programmable. Since Brookfield viscometer 
cannot easily measure viscosity of the cake batter, viscosity of 
batters was measured under certain conditions using a 
particular spindle. Viscosity of the samples was measured 
using spindle 64, 1 RPM and 73 torque at 30 s [15]. 

E. Tests for Cake 

Cake Texture Assessment 

Texture analysis test was performed by texture profile 
analyzer with AACC 74-04 in days 15 and 30 of storage on 
controls and the samples treated with 1.5%, 3% and 4.5% pre-
gelatinized starch. For the compression test, the samples were 
first cut into 2.5 cm cubes; then, the cubes were compressed by 
a plate probe by 50% at 1 mm/s. The compressive force applied 
to the samples was reported in Newton. Maximum force 
applied to the samples indicated higher stiffness of the samples. 
Moreover, sensory properties of the cakes such as color, flavor 
and texture was tested by 8 trained evaluators using a 9-point 
hedonic method. In this test, number 1 represented the lowest 
score given by the evaluators and number 9 the highest [16]. 
All physical and chemical tests were performed 3 times on 3 
different days. Data obtained was analyzed using a completely 
randomized design (CRD) by the SPSS software, version 19. 
The mean of treatments was compared by Duncan's multiple 
range test to the average level of error 5%. Moreover, the data 
obtained from sensory evaluation was analyzed by the 
Friedman test. 

III. RESULTS  

A. Starch 
The results related to flour and pre-gelatinized starch are 

shown in Table II. The results are significantly different 
(p<0.05). 

TABLE II.  RESULTS OF THE TESTS ON NULL FLOUR AND THE PRE-
GELATINIZED STARCH (EACH NUMBER INDICATES 3 ITERATIONS) 

Test Null flour 
Pre-gelatinized 

starch 
Protein (%) 11.89 13.91 

Ash (%) 0.5 0.5 
Moisture (%) 14.71 3.34 

Fat (%) 0.86 0.18 
Wet gluten 28.35 Not measurable 

Gluten index (%) 87.3 Not measurable 
Falling number 614.5 115 

Sedimentation number 25 32 
Pan 77.43 17.13 

Sieve 125 20.80 13.69 
Sieve 180 1.05 45.34 

Particle size 

Sieve 475 1.08 24.28 
pH 5.75 5.81 



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B. Specific Volume of Batter 
The results related to the effect of pre-gelatinized starch on 

specific volume of batter are shown in Figure 1 and Table III. 
Statistically, there was no significant difference in specific 
volume of 1.5% and 3% treatments, while controls and 4.5% 
treatments were significantly different from each other and 
other treatments. Specific volume of cake batter as a factor for 
assessing overall ability of the batter to maintain air provides 
limited information regarding the size and extent of the gas 
cells [16]. 

According to [17], higher specific volume of cake batter 
reflects lower volume of the cake. This report is consistent with 
the current study, where the increased amount of pre-
gelatinized starch used reduced the specific volume of cake 
batter. Eventually, an increase was observed in volume of the 
cakes containing more pre-gelatinized starch. According to 
observations, the increase in pre-gelatinized starch softened the 
batter texture which made the mixing easier. Since mechanical 
factors (mixing) are one of the factors effective in increasing 
cake volume, the increase in pre-gelatinized starch and water 
content and a reduction in the amount of null flour used in the 
cake batter influenced aeration and thus the amount of air in the 
batter and reduced the specific volume. 

C. Viscosity of Batter 
As shown in Figure 2, there is a significant difference in 

viscosity of all treatments. The 3% treatment had the lowest 
viscosity while the 1.5% treatment was the most viscose 
sample. According to the results, the pre-gelatinized starch 
added to the batter formulation reduced viscosity by 3%, while 
4.5% pre-gelatinized starch added to the cake batter increased 
viscosity by3% compared to the sample. The results showed 
that the 3% treatment had the highest reduced viscosity 
compared to the control treatment. 

Pre-gelatinized starch changes the elasticity of the batter 
and increases gas storage capacity, reducing the consistency of 
the batter. This means that the batter is softer, that is, its 
viscosity is reduced compared to the control sample. Thus, the 
increased softness is followed by reduced viscosity of the 
batter. Pre-gelatinized starch has a very high water holding 
capacity. Therefore, addition of certain amounts of pre-
gelatinized starch will result in increased residual moisture and 
reduced viscosity of the batter. The results indicate that the 3% 
treatment had the lowest viscosity compared to controls and 
other treatments. In [18] it was stated that the flour boiling 
happens simultaneously with partial drying of the starch 
molecular structure under heat, which is also true for the pre-
gelatinized starch. The increased solubility of the pre-
gelatinized starch can be due to partial breaking and increased 
mobility of the molecules by absorbing water as well as 
physical porous structure of this type of starch [19]. 

D. Cake Texture 
The cake samples produced were tested for F(max) which is 

a measure of the force on the cake samples. The changes 
related to maximum force were tested for all samples in three 
different days of storage (1, 15 and 30). It was observed that a 
larger increase in the pre-gelatinized starch used in the product 

structure and reduced amount of flour was followed by reduced 
stiffness of texture. Therefore, 4.5% treatment had the softest 
tissues compared to other treatments. This can be attributed to 
water absorption of the pre-gelatinized starch. In addition, there 
is a direct relationship between moisture and stiffness. Water 
absorption and thus moisture content will have a direct effect 
on textural properties of bakery products. Pre-gelatinized starch 
changes elasticity of the batter and increases gas storage 
capacity. The increased gas storage capacity and consequently 
reduced consistency of the batter will soften the cake texture. 
Thus, the pre-gelatinized starch plays an important role in 
reducing stiffness of the cake texture by reducing elasticity. 
Moreover, texture analysis showed that the cake had higher 
stiffness in day 30 compared to day 1 and 15. 

E. Sensory Evaluation 
According to the results of the sensory evaluation test, 3% 

treatment obtained higher score for flavor, color and general 
acceptance compared to other treatments. In contrast, 
acceptance of texture was higher for 4.5% treatment compared 
to other treatments. The pre-gelatinized starch will improve 
taste, color and texture of the final product. 

 

 
Fig. 1.  Effect of pre-gelatinized starch on specific volume of cake batters. 

Letters indicate significant mean of treatments at 0.05 

TABLE III.  RESULTS RELATED TO BATTER SPECIFIC VOLUME  

Treatment Specific volume 
Control sample 0.93c 
1.5% treatment 0.83b 
3% treatment 0.85b 

4.5% treatment 0.70a 

 

 
Fig. 2.  Effect of pre-gelatinized starch on viscosity of cake batters. Letters 

indicate significant mean of treatments at 0.05 

TABLE IV.  RESULTS RELATED TO SPECIFIC VISCOSITY OF BATTER 

Treatment Viscosity 
Control sample 14.42c 
1.5% treatment 15.97d 
3% treatment 12.15a 
4.5% treatment 13.58b 



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Fig. 3.  Comparison of means of three days F-Max (N) 

 

 
Fig. 4.  Comparison of the effect of day on OF-Max (N) * letters indicate 

significant mean of treatments in 0.05. 

 

 
Fig. 5.  Comparison of mean of sensory evaluation 

IV. DISCUSSION 
A significant difference was observed in specific volume of 

the 4.5% treatment and the control. Due to its higher water 
absorption capacity, the 3% treatment had the lowest viscosity 
than other treatments. Physicochemical tests on the cake 
samples indicated no significant difference in moisture, aw, 
volume, color and stiffness of the 1.5% treatment and the 
control (P>0.05), while a significant difference was observed in 
the results of physicochemical tests as the amount of pre-
gelatinized starch was increased in the formulation (P<0.05); 
the increase in the amount of 3% pre-gelatinized starch was 
associated with an increase in moisture, aw and volume of the 
treatment. This led to an increase in quality of the 3% sample. 
Results of cake texture assessment which were evaluated for 
the effect of various amounts of the pre-gelatinized starch on 
the cake texture showed that the increase in the pre-gelatinized 
starch used in the structure as well as the reduction in the 
amount of the used null flour was associated with a decrease in 
stiffness of the cake samples; the 4.5% treatment had the 
softest texture compared to other treatments. Moreover, cake 
texture assessment for various amounts of the pre-gelatinized 
starch in days 1, 15 and 30 indicated no significant difference 
in stiffness (P>0.05). Cake texture assessment showed that the 
control and treatments were more stiff in day 30 compared to 
day 1 (P<0.05). Moisture of the null flour is higher than that of 
pre-gelatinized starch, because the pre-gelatinized starch is 

exposed to a combination of moisture, pressure, temperature 
and mechanical cuts during its production using extrusion 
process which is a special process in short time and high 
temperature and the pre-gelatinized starch loses its moisture 
[20].  

V. CONCLUSION 
The pre-gelatinized starch, as an improver, has a positive 

effect on nutritional value and leads to changes in 
physicochemical properties of the finished product. 
battersMixes with different percentages of pre-gelatinized 
wheat starch were investigated in this paper. The results 
presented in this paper showed that the increased amount of 
pre-gelatinized starch reduced the specific volume of cakes. 
The best results derived from a 3% pre-gelatinized starch. 
Sensory evaluation of the cake samples, performed by trained 
sensory evaluators, showed that the cake produced by 3% pre-
gelatinized starch had the highest score on flavor, color and 
general acceptance compared to other treatments. A better 
texture however was achieved with a 4.5% mix. As higher 
amount of pre-gelatinized starch replaced the null flour, some 
properties of the cake such as texture and general acceptance 
also improved. 

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