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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 56, 2017 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Jiří Jaromír Klemeš, Peng Yen Liew, Wai Shin Ho, Jeng Shiun Lim
Copyright © 2017, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-47-1; ISSN 2283-9216 

Physicochemical Properties and Storage Stability of 
Margarine Containing Anthocyanins from Roselle Calyces 

Dayang Norulfairuz Abang Zaidel*a, Nur Shakira Sahata, Yanti Maslina Mohd 
Jusoha, Ida Idayu Muhamadb 
a
Faculty of Chemical Engineering, Universiti Teknologi Malaysia, 81310 UTM Johor Bahru, Malaysia,  

b
IJN-UTM Cardiovascular Engineering Centre, Universiti Teknologi Malaysia, 81310 UTM Johor Bahru, Malaysia. 

dayang@cheme.utm.my 

Addition of encapsulated anthocyanins in margarine formulation improves the stability of margarine. In this 
study, investigation on the storage and stability characteristics of water-in-oil emulsion, i.e. margarine, 
containing encapsulated or non-encapsulated anthocyanins from Roselle was carried out. Encapsulation of 
anthocyanins was performed using microwave-assisted technique to study the dispersion and stability of 
anthocyanins in the margarine. Margarines were formulated with three different oil-to-aqueous ratios (88:12, 
86:14 and 84:16). The blend formulation was compared with commercial margarine and the stability of the 
margarine was determined by using chemical, physical and texture stability analysis and. Margarine 
containing non-encapsulated anthocyanin showed improved stability compared with encapsulated 
anthocyanin.  

1. Introduction 

There have been increased attractions in the development of food colorants from natural or natural-derived 
alternatives as the synthetic pigments are increasingly rejected by the consumer (Stintzing and Carle, 2004). 
Anthocyanin is one of the example colorant widely used as natural colorant in food industry. Anthocyanin from 
different sources gives different processing and storage stability such as storage temperature, light, pH, 
concentration, ascorbic acid, sugar and oxygen (Rein, 2005). 
Recently, the biological activities of anthocyanin, such as antioxidant activity, protection from atherosclerosis 
and anticarcinigenic activity, aphrodisiac properties (Duke and Ducellier, 1993) have been investigated, and 
reported that anthocyanins can provide some beneficial effects in the treatment of disease such as 
neuronaland cardiovascular illnesses, cancer and diabetes (Lule and Xia, 2005), lower blood pressure and 
improve the digestive system in humans (Muhammad and Shakib, 1995).  
Several studies have reported that the isolated anthocyanins are highly instable and very susceptible to 
degradation. Stability of  anthocyanins is affected by several factors such as pH, SO*,storage temperature, 
chemical structure, concentration, light, oxygen, solvents, copigmentation and ‘thin film’ effects, the presence 
of enzymes, flavonoids, proteins and metallic ions (Rein, 2005).  
Encapsulation is a useful means of protecting colorant from degradation and preventing premature colour 
development. Microencapsulating a pigment in matrix suitable for given application improves the stability of 
the color both in bulk and in food formulations while ensuring end-product functionality. Encapsulated natural 
colours have better heat, light and pH stability. Hence, encapsulation of colour has longer shelf life, improved 
stability over a wider pH range and the prevention colour development during storage while delivering the 
intended colour upon preparation. Currently, there are high interests of using microwave technique for 
encapsulation among food researchers due to its high potential capabilities such as shorter drying time, low 
cost, improved product quality and also have flexibility in producing a variety of dried product (Haghi and 
Amanifard, 2008). 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1756176

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Zaidel D.N.A., Sahat N.S., Jusoh Y.M.M., Muhamad I.I., 2017, Physicochemical properties and storage stability of 
margarine containing anthocyanins from roselle calyces, Chemical Engineering Transactions, 56, 1051-1056  DOI:10.3303/CET1756176   

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This study aims to investigate the storage and stability characteristics of water-in-oil emulsion, i.e. margarine, 
containing encapsulated anthocyanins from Roselle. Comparison between margarines formulated containing 
non-encapsulated and encapsulated anthocyanins were investigated.  

2. Materials and methods 

2.1 Preparation of Roselle samples 

The sample preparations for Roselle were performed according to Tsai et al. (2001) with modification. The 
fresh Roselle calyces (Hibiscus sabdariffa L.) which was obtained from Johor (FAMA Pontian) were dried at 
50 °C for 36 h and stored at 25 °C. The dried Roselle calyces were shredded into small calyces by using food 
shredder and put in dry wide-mouthed bottle containers, covered and labeled.  

2.2 Extraction of anthocyanins 

The extraction of anthocyanins was performed according to Looi (2008) with modification. The shredded 
Roselle calyces were added in distilled water in different beaker. The mixtures were stirred and heated at 35 
°C on hotplate for an hour until a red colour appeared. The extracted solution was poured through the coffee 
filter to remove the pieces of Roselle. The procedures were replicated three times with the same roselle. For 
third time replication, the samples were soaked and stored in refrigerator for 24 h until all anthocyanins were 
almost fully extracted or the fibre become colourless through observation. 25 mL of the extracted solutions 
were collected in universal bottle for concentration determination, respectively while the least was collected in 
a beaker. 

2.3 Encapsulation of anthocyanins using microwave-assisted technique  

The encapsulation of anthocyanins was performed according to Abbasi and Rahimi (2006) with modification. 
Anthocyanins (roselle extract) as core material were mixed well with Maltodextrin at ratio 1:10 (v/v) inside a 
round glass plate. Mixtures were place in a domestic microwave oven (1,200 W) until the wall materials 
started to melt or burnt.  

2.4 Blend Preparation 

The oil blend was performed according to Ming et al. (1999) with modification. Liquefied palm stearin (PS), 
palm oil (PO) and palm kernel oil (PKO) were mixed in proportions of 70:10:20 respectively, identified by the 
mass ratio of the blend. 

2.5 Margarine Formulation 

The formulation of margarine was performed as described by Kim et al. (2006) with modification. The 
ingredients (w/w %) were lipid phase, 84 % (oil blend, 79.5 % and soy lecithin fluid, 0.5 %) and aqueous 
phase, 16 % (distilled water, 9 %; anthocyanins, 9 % and table salt, 2 %). The lipids and water were heated to 
60 °C separately and combined into a table top homogenizer. The mixture was emulsified by vigorously mixing 
for 60 min. Commercial synthetic butter flavour was added to cover any distinction in the aroma of the 
samples. The mixture was crystallized using a water bath for 15 min. The solid emulsion then was refrigerated 
overnight at 20 ºC. The overall steps are repeated for other two lipid-to-aqueous ratios: 86:14 and 88:12, 
different type of encapsulated material according to the formulation table in Table 1. The margarines were 
placed into plastic tubs and stored at two different temperatures 25 °C and room temperatures.  

Table 1:  Formulation Table of Margarine 

Sample 
Factor 1 
Oil-to-aqueous Ratio 

Factor 2 
Type of Encapsulated Material 

1 84/16 Non-encapsulated 
2 84/16 Maltodextrin 
3 86/14 Non-encapsulated 
4 86/14 Maltodextrin 
5 88/12 Non-encapsulated 
6 88/12 Maltodextrin 

2.6 Determination of color parameters  

Colour parameters (L, a*, b*, C and H) were measured using colorimeter (Konica Minolta). The sample was 
placed in glass plate. The start button was pressed when the colorimeter was ready to evaluate. The L, a*, b*, 
C and H value appeared at the screen of colorimeter and was recorded. 

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2.7 Dissolution test  

Encapsulated sample (50 mg powder) was mixed with one mL distilled water at room temperature in a test 
tube. The time taken for powder to dissolve in water was recorded. The analysis was repeated three times 
where time is recorded. 

2.8 Determination of Fatty Acid (FA) Profile by Gas Chromatograph (GC)  

FAs composition of PO/PS binary fat blends were determined by following the same procedure reported by 
Saadi et al. (2011). 1 µL was taken carefully from the top layer and injected manually at 20 °C in the splitless 
mode. Then, the sample prepared was chromatographed to determine the FAs composition. By using the 
retention time of their TAG standards used (St. Louis, MO, USA), the FAs composition were identified and 
calculated. 

2.9 Analysis of Solid Fat Content (SFC) of margarine  

Nine tubes were used for each sample. Each sample was tempered at 70 °C for 30 min, followed by chilling at 
0 °C for 90 min and then kept at the desired temperatures for 30 min prior to measurements. The melting, 
chilling and holding of the samples were carried out in pre-equilibrated thermo-stated baths. The SFC was 
measured within the temperature ranges 5 to 40 °C (Saadi et al., 2012). 

2.10 Determination of melting point  

The capillary tubes were placed in cold water then heated (0.5°C/min) until the level of the fat matter rises in 
the capillary tube. The melting temperature was noted (ISO International Standard, 2002b). 

3. Results and discussion 

3.1 Extraction of anthocyanins 

After three replications of extraction by using 100 % distilled water method, it was expected that all 
anthocyanins were fully extracted from roselle. This was shown from the red solution obtained and after three 
replication of extraction the roselle obtained was becoming colourless fibre. Total concentration of anthocyanin 
obtained for roselle was 135.33±2.0 mg/L. The first concentration of extracted anthocyanin with 200 mL pure 
water was 186.55±2.0 mg/L; second concentration of extraction with 100 mL pure water was 117.95±2.0 
mg/L, and third extraction of anthocyanin from the same sample was 59.91±2.0 mg/L. The physical properties 
of extracted anthocyanins from Roselle was shown in Table 2. 

Table 2:  Physical properties for extracted anthocyanins from Roselle. 

Total soluble solid (°Brix) 10.8±1.0 
Total anthocyanin content (mg/L) 135.33±2.0 
Colour parameters 
L* 
a* 
b* 
C* 
H° 

 
41.4±1.0 
+0.3±2.0 
+8.6±2.0 
8.6±1.0 

88.1±1.0 

3.2 Encapsulation of anthocyanins  

Table 3 shows the physical properties for encapsulated anthocyanins from roselle using maltodextrin as the 
wall material. The encapsulated anthocyanins from roselle had low moisture content and were soluble fast in 
water. 

Table 3:  Physical properties for encapsulated anthocyanins from roselle using maltodextrin as wall material. 

Moisture Content (%) 7.2409±0.0001 
Dissolution test (s) 5±1 
Color parameters 
L* 
a* 
b* 
C* 
H° 

 
51.0±1.0 
+4.4±2.0 
+6.9±2.0 
8.2±1.0 
56.6±1 

 

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The moisture content reported was low, low moisture content is good for the stability of encapsulated 
anthocyanins. The encapsulated anthocyanins were soluble in 5s which is suitable for application in margarine 
formulation process. Hooe (2009) in their work, has reported that maltodextrin showed the greatest protecting 
effect for anthocyanins stability because the percentage of anthocyanins degradation is lower compared to 
anthocyanins encapsulated with Gum Arabic. In solution state, degradation of anthocyanins encapsulated by 
maltodextrin is lower rather than anthocyanins encapsulated by Gum Arabic and non-encapsulated 
anthocyanins. 

3.3 Fatty acid content analysis 

From Figure 2, the percentage of fatty acid of C12%, R12% and RE12% are almost similar. These shows that 
addition of anthocyanins did not affect the composition of fatty acid of margarine formulated. However, the 
lauric acid(C12) and myristic acid (C14)  composition lower than in Planta. However, palmitic acid (C16) and 
oleic acid (C18:1) composition are slightly higher than in Planta. The linoleic acid (C18:2) composition are 
almost similar with Planta. The results were almost similar for solid/liquid ratio of 14% and 16%. These 
emphasizes that the fatty acid composition did not effected by the addition of anthocyanins. 

                    

       

Figure 2: Fatty Acid Content (%) margarine formulated for (a) solid/liquid ratio 12 % (b) solid/liquid ratio 14 % 
(c) solid/liquid ratio 16 % 

3.4 Solid fat content of margarine containing anthocyanins 

The SFC rates of the samples varied with the temperature. Indeed, it decreases with decreasing temperature. 
The values obtained for the margarine are close whatever the temperature. This proves that the margarines 
had the same composition and therefore their preparation was made according to the good manufacturing 
practices. At 20 °C, the SFC were more than 10 %, at 30 °C, they were above 5 %. At 40 °C, the values were 
very low (below 5 %). These results were in agreement with those obtained by Karleskind (1992). At 37 °C 
SFC must be less than 6 %. In the present study, margarine had already a SFC lower than 6% at 30°C which 
indicates that these margarines melts easily in the mouth.  
At 20 °C, all margarines have more than 10 % SFC and shows more than 20 % SFC at 25 °C. At  
30 °C, the SFC percentages is recorded at very low percentage which is lower than 5 % as shown in Figure 3. 
These results is coherent with the agreement on producing a good spreadibility and texture of margarine 
formulation. 

3.5 Slip melting point analysis 

The melting points give an indication of the temperature at which margarine should be smooth in the mouth. 
Figure 4 shows changes in SMP of different margarines formulated throughout 12-week storage period. All the 
margarines are due to the polymorphic transformation from the β’ to the β form. Food systems with β- form 
crystals are usually firmer with higher SMP due to the stronger crystal network required to link the large-

(a) (b) 

(c) 

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needle crystal (Zhang et al., 2009). The melting point international standard range of margarine are between 
28 °C and 34 °C which implies that margarine can melt rapidly in the mouth and be firm at room temperature 
to resist to mechanical work during its spreadability. In Figure 4, the melting points of the margarine 
formulated were not significantly different and fluctuates throughout the storage time. The melting points of the 
margarine formulated were above than 28 °C. R12% and R14% show a stable SMP value within 12 weeks 
storage time. However, RE14% and RE16% shows a significance fluctuations during the storage time. 

  
 
 

    
 
 

 

Figure 3: Solid fat content (%) margarine with 25°C storage temperature at 20°C (a) solid/liquid ratio 12% (b) 
solid/liquid ratio 14% (c) solid/liquid ratio 16; Solid fat content (%) of margarine with 30°C storage temperature 
at 20°C (d)solid/liquid ratio 12% (e) solid/liquid ratio 14% (f) solid/liquid ratio 16% 

   
 
 

 
 
 

 

Figure 4: Slip Melting Points of margarine formulated with storage temperature at 25 °C (a) solid/liquid ratio  
12 % (b) solid/liquid ratio 14 % (c) solid/liquid ratio 16 %; Slip Melting Points of margarine formulated with 
storage temperature at 30 °C (d) solid/liquid ratio 12 % (e) solid/liquid ratio 14% (f) solid/liquid ratio 16 % 

0

5

10

15

20

25

30

C12% R12% RE12%

SF
C 

%

0

5

10

15

20

25

30

C14% R14% RE14%

SF
C 

%

0

5

10

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30

C16% R16% RE16%

SF
C 

%
0

5

10

15

20

25

30

C12% R12% RE12%

SF
C 

%

0

5

10

15

20

25

30

C14% R14% RE14%

SF
C 

%

0

5

10

15

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25

30

C16% R16% RE16%
SF

C 
%

0

10

20

30

40

50

C12% R12% RE12%

Te
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 (°
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C14% R14% RE14%

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(d) (e) 

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(d) (e) (f) 

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4. Conclusions 

Total concentration of anthocyanin obtained for Roselle was 135.33±2.0 mg/L. The first concentration of 
extracted anthocyanin with 200 mL pure water was 186.55±2.0 mg/L; second concentration of extraction with 
100mL pure water was 117.95±2.0 mg/L, and third extraction of anthocyanin from the same sample was 
59.91±2.0 mg/L. The moisture content reported was low which is good for stability of encapsulated 
anthocyanins. At 20 °C, all margarine have more than 10% solid fat content and shows more than 20 % SFC 
at 25 °C. At 30 °C the SFC percentages recorded at very low percent which is lower than 5 °C which is follow 
the agreement on producing a good spreadibility and texture of margarine formulation. The melting points of 
the margarine formulated were above than 28 °C. R12% and R14% show a stable SMP value within 12 
weeks’ storage time. So the best formulated margarine is R12% (solid/liquid ratio 88:12) which has a suitable 
SFC an SMP value compared to commercial margarine. 

Acknowledgments 

The authors would like to acknowledge Universiti Teknologi Malaysia and Ministry of Higher Education for the 
financial support under Research University Grant Scheme (Q.J130000.2544.06H39) and Fundamental 
Research Grant Scheme (R.J130000.7844.4F447). 

References 

Abbasi S., Rahimi S., 2008, Microwave-assisted Encapsulation of Citric Acid using Hydrocolloids, International 
Journal of Food Science and Technology 43, 1226-1232. 

Duke J.A., Ducellier M.J.B.J., 1993, Handbook of Medicinal Spices, CRC, Florida, USA, 53-55. 
Haghi A.K. Amanifard N., 2008, Analysis of Heat and Mass Transfer during Microwave Drying of Food 

Products, Brazilian Journal of Chemical Engineering 25, 491-501. 
Hui K.H., 2009, Microwave-Assisted Encapsulation of Anthocyanins from Roselle (Hibicus Sabdarifa L.) and 

its Thermal Stability Analysis, MSc Thesis, Universiti Teknologi Malaysia, Johor, Malaysia. 
Looi M.L., 2008, Nano Encapsulation of Anthocyanins from Brassica Oleracea, MSc Thesis, Universiti 

Teknologi Malaysia, Johor, Malaysia. 
Lule S.U., Xia W., 2005, Food Phenolics, Pros and Cons: A Review, Food Review International 21, 367-388. 
Rein M., 2005. Copigmentation Reactions and Color Stability of Berry Anthocyanins, PhD Thesis, University of 

Helsinki, Helsinki, Finland. 
Saadi S., Ariffin A.A., Ghazali H.M., Abdulkarim M.S., Huey C.B., Miskandar, M.S., 2012, Crystallisation 

Regime of w/o Emulsion [e.g. Multipurpose Margarine] Models During Storage, Food Chemistry 133, 
1485-1493. 

Stintzing F.C., Carle R., 2004, Functional Properties of Anthocyanins and Betalains in Plants, Food, and in 
Human Nutrition, Trends in Food Science and Technology 15, 19-38.  

Tsai P., McIntosh J., Pearce P., Camden B., Jordan B.R., 2002, Anthocyanins and Antioxidant Capacity in 
Roselle (Hibiscus Sabdariffa L.) Extract, Food International Research 35, 351-356. 

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