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Research Article
 

Quality Assessment of Milk Powders Packed in Sudan



Murwan Khalid, Sabah El Khier and A. Yagoub Abu El Gasim
 
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ABSTRACT

Physicochemical, microbiological and sensory characteristics of milk powders packed in Sudan were investigated and compared with international quality standards. The compositions (moisture, fat, protein, ash and lactose) of the locally packed milk powders are almost insignificantly different (p<0.05) and they are comparable to the compositional quality in US and Argentina. Despite the significant (p<0.05) variations in acidity and pH between milk powder samples, their levels remained within the acceptable standard levels. Results also showed that most milk powders packed in Sudan had partial solubility in water, in comparison with the instantly soluble standards. Microbiologically the samples were safe, but organoleptically they considered of fair quality.

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  How to cite this article:

Murwan Khalid, Sabah El Khier and A. Yagoub Abu El Gasim, 2009. Quality Assessment of Milk Powders Packed in Sudan. Pakistan Journal of Nutrition, 8: 388-391.

DOI: 10.3923/pjn.2009.388.391

URL: https://scialert.net/abstract/?doi=pjn.2009.388.391

INTRODUCTION

Cow’s milk is ranked first in the world. Meanwhile, it is considered one of the main components of the human diet in many parts of the world. It contains all essential nutrients. Most Cows' milk is consumed in the fresh or processed state. Processing treatments, with the aim of extending shelf life, have direct influences on the nutritional, biological and functional properties of milk nutrients (Nickerson, 1999; Ahmad et al., 2008).

Milk powder manufacture is a simple process now carried out on a large scale. It involves the gentle removal of water at the lowest possible cost under stringent hygiene conditions while retaining all the desirable natural properties of the milk; color, flavor, solubility and nutritional value. The milk powder contains lactose (38%), protein (26%), fat (26%) and ash (6%) in the same proportions as fluid milk (Eckles, 2001). Manufacture of milk powder was found abundantly in many developing countries because of reduced transport and storage costs. Standard powders, because of their fine dusty nature, do not reconstitute well in water. Agglomerated and instant powder was specially developed to counter this problem (Eckles, 2001). The milk powder is produced in three forms, full cream (26% fat), partially skimmed (8-24% fat) and skimmed (1.5% fat) milk powders for animal food in which fat not more than 1.5%. Milk powders with a standard fat content usually traded commercially for a variety of dairy and food application end uses (FAO, 1993; Keogh et al., 2003). The primary objectives for the thermal processing and drying of milk, in general, are to reduce natural pathogenic and spoilage microorganisms, to extend the shelf life of the milk and to ensure the safety of milk for human consumption. So, that the product can be consumed while still remaining safe, retaining acceptable quality and meeting customer expectations (Man and Jones, 1999).

However, several factors may contribute to changes in its physical and chemical properties which reduce shelf-life and thus its commercial value. Different researchers agree that the hygienic conditions under which raw milk is produced are the main factor affecting powder quality. Storage temperature and transportation may also influence the properties of milk powder, especially its solubility index and acidity (Fernandes de Oliveira et al., 2000; Eckles, 2001). To evaluate the quality and acceptability of a product, it is necessary to identify the characteristics of the constituents, the process and the storage conditions responsible (Man and Jones, 1999; Fernandez-Molina et al., 2005). Milk powders should be evaluated organoleptically, physicochemically and microbiologically to fully determine the quality and condition (USDEC, 2001).

In the recent years, many factories in Sudan had licenses for packing international brands of milk powders, such as Muawia Elberair Food Industry Company (Lodo), Blue Nile Dairy Company (kapo) and Gobber Food Stuff (Al marrai). However, little information is available on the quality of milk powders packed in the country. Therefore, the aim of this study was to investigate on the quality of the different brands of milk powder packed in Sudan in order to grade their quality in relation to the worldwide standards.

MATERIALS AND METHODS

Milk powder samples: Milk powder samples from different commercial brands (Kapo, Foremost, Al-marrai, Al-prince, Lodo and Nido) were purchased from the supermarkets in Khartoum state, Sudan. All the samples were packed (in metal cans) in Sudan. The milk powder of Nido brand was imported from Netherlands and used as control.

Compositional analysis: The moisture content of the milk powders was determined by the oven drying (105oC) method (AOAC, 1990). Ash was determined after mineralization of milk powder at 550oC according to AOAC (1990) and pH was measured using a pH meter (Hanna pH 210). Total nitrogen was determined by the Kjeldhal method (Bradley et al., 1992). Nitrogen content was converted into equivalent protein content using 6.38 as a converting factor (Karman and Van Boekel, 1986). Fat content was determined using Gerber method according to Bradley et al. (1992). Lactose was determined by the anthrone method (Richard, 1959). Powder samples were assayed for titratable acidity (% lactic acid) according to the method of Marshall (1992). Solubility in water was determined according to the standard method of AOAC (1990).

Organoleptic tests: Sensory evaluation tests for milk powder samples were done according to the British Standards methods (BS, 1986). Where, 10 g of milk powder were reconstituted in 90 g of water (colorless, tasteless and of excellent microbial quality at 25°C). The powder was mixed thoroughly in the water and then held in a covered glass container (in the dark) for about an hour at 20oC before evaluation. The reconstituted milk is examined for color, taste, flavor and odor and appearance.

Microbiological analyses: Microbiological analyses were performed on samples of milk powder following the procedures of the International Commission for Specification for Food (ICMSF, 1978). A tenfold serial dilutions up to 10-6 for each sample were prepared in 0.1% peptone water and subsequently plated onto standard Plate Count Agar (PCA) and Macconcey Agar (MA) to count total aerobic and coliform bacteria. PCA plates were incubated for 48±2 h at 32 ±1°C. MA plates for coliforms were incubated for 24±2 h at 32±1oC. The colony forming units (cfu) and the most probable number were employed to count total bacteria and coliforms, respectively. The results of microbiological assays were reported in duplicate.

Statistical analysis: Average results of triplicate samples were submitted to statistical analyses. Results were analyzed using analysis of variance of the SAS Institute-version 6.3-(SAS, 1997). Significant differences between means were determined at p<0.05.

RESULTS AND DISCUSSION

Physicochemical characteristics
Moisture, protein, fat, ash and lactose contents:
Proximate composition of the milk powders is presented in Table 1. The moisture contents of the local commercial milk powders (Kapo, Al-marrai, Foremost, Al-prince and Lodo) ranged between 2.06-2.40%, compared to 2.25% for the control Nido sample (Table 1). A significant (p<0.05) variation in moisture content of samples was observed. Physicochemical stability of milk powder during storage and distribution varies with the water content. Additionally, technological functionalities like dissolution or wettability can also be affected by the water content (Reh et al., 2004). The findings of this study indicated that the moisture content of all samples are lower than the recommended standards of Sudan (SSMO, 1999), USA (FDSPM, 2003) and Argentina (Item Codes 1, 2005) for powder milk. The powder samples almost had the same ash content, which was found lower than the standards of Sudan (SSMO, 1999) and USA (FDSPM, 2003), but agreed with that reported by Eckles (2001). Protein and fat contents of the local milk powders were similar and in line with the specified standards of Sudan, USA and Argentina (SSMO, 1999; FDSPM, 2003; Item Codes 1, 2005). A significantly higher lactose content in the composition of the locally packed milk powders than in the imported milk powder (Nido) was noticed. These results agreed with the standards of Sudan (SSMO, 1999) and USA (FDSPM, 2003).

pH, acidity and solubility: Table 2, presents the physical properties of the milk powders. Results reveled that Lodo milk powder (local) had the lowest acidity (1.34%) and the highest pH (6.80) almost similar to the control (Nido). The other local milk powders (Kapo, Foremost, Almarrai and Alprince) showed significant higher acidity ranged between 1.40-1.49%, simultaneously with a pH range of 6.60-6.70. The result are in coincidence with the standards of USA (FDSPM, 2003) and Argentina (Item Codes 1, 2005). The US Dairy Export Council reported that changes in pH do not appear to be significant for a milk powder user at the commercial level (USDEC, 2001). Result indicated that Nido and Foremost were instantly soluble in water (Table 3), comparable to the standards in USA (FDSPM, 2003) and Argentina (Item Codes 1, 2005). The other milk powders are partially soluble in water. The solubility of milk powders depends upon a number of factors such as the amount of dissolved minerals, “hardness”, in the water used, speed and duration of stirring and temperature and other factors (USDEC, 2001).

Microbiological and sensory evaluation: Compared to the count of bacteria in Nido (3x10), the bacterial populations in the all local milk powder samples were almost the same (3x102 to 3x103) (Table 3). Results, however, notified that the viable bacteria in the milk powders fall within the standard zone specified by Sudan (SSMO, 1999). Additionally, all the samples were found free from Coliform sp., thus considered microbiologically safe. Milk powder is generally considered a product of good microbiological quality (Fernandes de Oliveira et al., 2000), considering that it made from good quality milk and containing low microbial count and the moisture content is kept low (USDEC, 2001).


Table 1: Nutrient composition of milk powders
*Means of triplicate samples ±SD. Means having different superscripts within the column are significantly different at p<0.05. na, not available

Table 2: Physical quality of milk powders
*Means of triplicate samples±SD. Means having different superscripts within the column are significantly different at p<0.05. na, not available

Table 3: Microbiological and sensory quality of milk powders
*Means of duplicate samples

Nido and Foremost milk powders showed the highest scores for the organoleptic tests (9.5 and 9.0, respectively), while Kapo and Al-marrai gave score of 6.9. Alprince and Lodo gave scores of 6.6 and 6.3, respectively (Table 3). However, the overall sensory tests the samples subjected to indicated that both Nido and Foremost had good quality and the other samples had fair quality.

Conclusion: Results showed that milk powders packed in Sudan were in consistence with the international standards from standpoint of composition and microbiological safety. Nevertheless, they were almost inferior in sensory quality and solubility.

REFERENCES
1:  Ahmad, S., I. Gaucher, F. Rousseau, E. Beaucher, M. Piot, J.F. Grongnet and F. Gaucheron, 2008. Effects of acidification on physico-chemical characteristics of buffalo milk: A comparison with cow's milk. Food Chem., 106: 11-17.
CrossRef  |  Direct Link  |  

2:  AOAC., 1990. Official Methods of Analysis. 15th Edn., Association of Official Analytical Chemists, Washington, DC., USA., pp: 200-210.

3:  Bradley, Jr. R.L., E. Arnold Jr., D.M. Barbano, R.G. Semerad, D.E. Smith and B.K. Vines, 1992. Chemical and Physical Methods. In: Standard Methods for the Examination of Dairy Products, Marshall, R.T. (Ed.). 16th Edn., American Publication Health Association, USA., ISBN-13: 978-0875532080, pp: 433-529.

4:  Eckles, C.H., 2001. Milk and Milk Products: Technology, Chemistry and Microbiology. 4th Edn., Tata McGraw-Hill Publishing, New Dalhi.

5:  FAO, 1993. Manual of microbiological analysis. Since, 1929: Fluid milk, Ice cream, powder milk, 572 HWG. T-fortuna, C A 95540.

6:  FDSPM, 2003. Fundamentals of Dairy Science Powder Milk: USA Standards of Powder Milk. 2nd Edn., FDSPM, New York.

7:  De-Oliveira, C.A.F., L.L. Mestieri, M.V. Santos, J.F.G. Moreno, A. Spers and P.M.L. Germano, 2000. Effect of microbilogical characteristics of raw milk on the quality of whole milk powder. Braz. J. Microbiol., 31: 95-98.
Direct Link  |  

8:  Fernandez-Molina, J.J., G.V. Barbosa-Canovas and B.G. Swanson, 2005. Skim milk processing by combining pulse electric fields and thermal treatments. J. Food Process. Preserv., 29: 291-306.
Direct Link  |  

9:  ICMSF, 1978. International Commission on Microbiology for Specification for Food. Microorganisms in Food: Their Significance and Methods of Enumeration. 2nd Edn., University of Toronto Press, Toronto, Canada.

10:  Karman, A.H. and M.A.J.S. van Boekel, 1986. Evaluation of the Kjeldahl factor for conversion of the nitrogen content of milk and milk products to protein content. Netherlands Milk Dairy J., 40: 315-336.
Direct Link  |  

11:  Keogh, M.K., C.A. Murra and B.T. O`Kennedy, 2003. Effects of ultrafiltration of whole milk on some properties of spray-dried milk powders. Int. Dairy J., 12: 995-1002.
CrossRef  |  Direct Link  |  

12:  Man, C.M.D. and A.A. Jones, 1999. Shelf Life Evaluation of Foods. Aspen Publisher Inc., New York, pp: 132-134.

13:  Marshall, R.T., 1992. Standard Methods for the Examination of Dairy Products. 16th Edn., American Public Health Association (APHA), Washington, DC., USA., ISBN-13: 9780875532080, pp: 286-348.

14:  Nickerson, S.C., 1999. Milk Production: Factors Affecting Milk Composition. In: Milk Quality, Aspan, H.F. (Ed.). 1st Edn., Chapman and Hall, Glasgow, Scotland, UK., pp: 3-23.

15:  Reh, C., S.N. Bhat and S. Berrut, 2004. Determination of water content in powdered milk. Food Chem., 86: 457-464.

16:  Richard, E.L., 1959. The reaction of the lactose with anthrone and its application to estimation of lactose in casein and other dairy product. J. Dairy Res., 26: 53-57.

17:  SAS, 1997. SAS/STAT User's Guide, Statistics. Release 6.3., SAS Institute Inc., Cary, NC.

18:  SSMO, 1999. Sudanese standard and metrological organization. Powder Milk, Code x Standard 207.

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