THE IMPORTANCE OF GEOBACILLUS SPP. AS GROUP OF BACTERIAL CONTAMINATES IN THE DAIRY INDUSTRY

Authors

1 Animal Health Research Institute, Assiut Regional Laboratory

2 Animal Health Research Institute, Assiut Regional Laboratory.

Abstract

Infant formulae are modern artificial substitutes for human breast milk. Formulas are designed for infant consumption, and are usually based on either cow milk or soy milk. Geobacillus represents aerobic or facultative anaerobic, neutrophilic, obligatory thermophilic, endosporeforming bacteria. A total of ninety random samples of milk powder, Infant milk powder and milk-cereal based weaning food (30 samples each) were purchased from different shops and pharmacies in Assiut city. Samples were examined for total thermophillic count, total spore count at 37°C and 55°C. The incidences of Geobacillus spp. and other bacillus spp. were also determined. The mean value of total thermophillic colony count/g was 10×103; 13×103 and 12×103/ g of examined dried milk powder, infant milk formulae and milk-cereal based weaning food samples, respectively at 37°C. While at 55°C, it was 1×102 and 7.6×102/g in the same samples, respectively. Infant milk formulae were free. In addition, the mean of total spore count at 37 and 55°C were 22×102 and 10×103/g in milk powder samples, respectively and 11×103 and 59×102 in milk-cereal based weaning food samples and 13×103 in infant milk formulae at 37 °C. Geobacillus stearothermophilus could be isolated only from milk-cereal based weaning food in percentage of 16.7%. Some other Bacillus spp < /em>. could be detected at different temperatures with different percentages. Lipolytic and proteolytic activities of G. stearothermophilus were also evaluated.

Keywords


THE IMPORTANCE OF GEOBACILLUS SPP. AS GROUP OF BACTERIAL CONTAMINATES IN THE DAIRY INDUSTRY

 

MARWA M.N. EL-GENDI and NAHED M. WAHBA

Animal Health Research Institute, Assiut Regional Laboratory.

Email: moazahmednofel@yaloo.com

 

 

ABSTRACT

 

 

 

Infant formulae are modern artificial substitutes for human breast milk. Formulas are designed for infant consumption, and are usually based on either cow milk or soy milk. Geobacillus represents aerobic or facultative anaerobic, neutrophilic, obligatory thermophilic, endosporeforming bacteria. A total of ninety random samples of milk powder, Infant milk powder and milk-cereal based weaning food (30 samples each) were purchased from different shops and pharmacies in Assiut city. Samples were examined for total thermophillic count, total spore count at 37°C and 55°C. The incidences of Geobacillus spp. and other bacillus spp. were also determined. The mean value of total thermophillic colony count/g was 10×103; 13×103 and 12×103/ g of examined dried milk powder, infant milk formulae and milk-cereal based weaning food samples, respectively at 37°C. While at 55°C, it was 1×102 and 7.6×102/g in the same samples, respectively. Infant milk formulae were free. In addition, the mean of total spore count at 37 and 55°C were 22×102 and 10×103/g in milk powder samples, respectively and 11×103 and 59×102 in milk-cereal based weaning food samples and 13×103 in infant milk formulae at 37 °C. Geobacillus stearothermophilus could be isolated only from milk-cereal based weaning food in percentage of 16.7%. Some other Bacillus spp. could be detected at different temperatures with different percentages. Lipolytic and proteolytic activities of G. stearothermophilus were also evaluated.

 

 

 

Received at: 29/9/2013

 

Accepted: 26/10/2013

 

Key words: Geobacillus spp., dairy industry, milk

 

 


INTRODUCTION

 

Thermophilic bacilli, such as Anoxybacillus, Geobacillus and Bacillus are common contaminants growing within the processing lines of milk powder producing factories. Spores surviving processing (filling, temperature, sterilization of packaging material, etc.) can germinate, grow, and proliferate in the product (Scheldeman et al., 2006). Moreover, these contaminants are used as indicator organisms for plant hygiene and specification limits based on their numbers have been implemented to ensure milk powder quality.

 

Recently, Nazina et al. (2001) reclassified some existing Bacillus species within group V into the new genus Geobacillus based on phenotypic and genotypic characteristics. So far, the most recently published and recognized species are Geobacillus caldoxylosilyticus, G. debilis, G. gargensis, G. jurassicus, G. kaustophilus, G. lituanicus, G. pallidus, G. stearothermophilus, G. subterraneus, G. tepidamans, G. thermocatenulatus, G. thermodenitrificans, G. thermoglucosidasius, G. thermoleovorans, G. toebii, G. uzenensis and G. vulcani (Nazina et al., 2001, 2004;Banat et al., 2004; Schaffer et al., 2004; Zeigler et al., 2005).

 

G. stearothermophilus spores (formerly B. stearothermophilus) are extremely heat resistant, up to 20 times more resistant than Clostridium botulinum spores (Watanabe et al., 2003; Iciek et al., 2008). G. stearothermophilus spores typically survive canning and sterilization procedures of food products (Denny, 1981 and Brackett, 2001) and may cause spoilage problems especially where foods must be stored at elevated temperatures for a long time. Growth of G. stearothermophilus spores results in flat sour spoilage because acid is produced but with little or no gas generated (Brackett, 2001). Due to its heat resistance, this microorganism is often used as a biological indicator for testing the efficacy of sterilization processes (Chopra and Mathur, 1984 and Phillips and Griffiths, 1990). Furthermore, the capacity of this bacterium to adhere to stainless steel and grow in biofilms appears to be a likely cause of contamination of manufactured dairy products (Flint et al., 2001).

 

In the dairy industry, the thermophilic bacilli are usually enumerated using an aerobic plate count (APC) incubated at 55 °C. Those that have been isolated from dairy products at this incubation temperature can be divided into two groups: the obligate thermophiles and the facultative thermophiles (also known as thermotolerant microorganisms). The obligate thermophiles grow only at elevated temperatures (approximately 40–68°C) and include Anoxybacillus flavithermus and Geobacillus spp. (Flint et al., 2001; Ronimus et al., 2003; Scott et al., 2007). The facultative thermophiles belong to the Bacillus genus and tend to grow at both mesophilic and thermophilic temperatures, depending on the strain. Some examples of species include B. licheniformis, B. coagulans, B. pumilus, B. sporothermodurans and B. subtilis (Crielly et al., 1994; Flint et al., 2001; Ronimus et al., 2003, Scheldeman et al., 2005).

 

Feeherry et al. (1987) noted that many food products cannot withstand the heat treatment needed to inactivate thermophilic spores. Therefore, other measures such as the control of contamination of ingredients by thermophilic organisms, rapid cool below 4 °C after thermal processing, and controlled storage are required to prevent spoilage. 

 

MATERIALS and METHODS

 

Collection, preparation and serial dilutions of samples:

A total of 90 random samples of milk powder, Infant milk powder and milk-cereal based weaning food (30 samples each) were purchased from different shops and pharmacies in Assiut city, Egypt. These samples were still valid for consumption as shelf life is at least to be more than one year from production time. Cartons and cans of samples were cleaned, thoroughly mixed and aseptically opened. Ten fold serial dilutions were carried out according to A.P.H.A. (1992).

 

Enumeration of total thermophiles:

1 ml of the sample and its decimal dilutions was plated using milk plate count agar (MPCA) and incubated at 37 and 55 °C for 48 h as described by Frank and Yousef(2004).

 

Enumeration of total Spores:

Firstly, the samples were heated at 80 °C for 20 min. to inactivate the vegetative cells and activate the spores, enabling them to germinate. The heat-treated sample is pour plated with MPCA supplemented with 0.2% starch and is incubated at 37°C and 55°C for 48 h. The starch is added as an aid for spore germination (Murphy et al., 1999; McGuiggan et al., 2002and Coorevits et al., 2008).

 

Isolation of Geobacillus spp.:

Tryptic soy agar with 0.2% soluble potato starch was chosen as the isolation medium and incubated at 37°C and 55°C for 48 h (Ronimus et al., 2003).

 

Identification of isolates:

Identification of bacterial isolates was performed based on their morphological, physiological, and biochemical characteristics, as described in Bergey’s Manual of Systematic Bacteriology (Claus and Berkeley, 1986).

 

Lipolytic and protylytic activity:

To evaluate the proteolytic activity, the strains were plated on milk agar. The milk agar was prepared with plate count agar supplemented with 1% skimmed milk powder (Beerens and Luquet, 1990). The plates were incubated at 30ºC for 48 hours. The positive results were indicated by transparent halo zone around the colonies.

 

For the evaluation of lipolytic activity, the strains were plated on tributyrin agar, prepared with plate count agar supplemented with 1% tributyrin (Beerens and Luquet, 1990). The plates were incubated at 30ºC for 48 hours. The positive results were indicated by transparent halo zone around the colonies.

 

 

RESULTS

 

Table 1: Statistical analytical results of Total Thermophilic Count at 37°C and 55 °C.

 

At 55 °C

At  37°C

No. of the examined samples

Examined samples

Count /g

Positive samples

Count/ g

Positive samples

 Mean ±St Error

Max.

Min.

%

No.

Mean

Max.

Min.

%

No.

1×102

1×102

1×102

6.7

2

10×103

38×103

1×102

70

21

30

Milk powder

 

0

0

0

0

0

13×103

79×103

2×102

63.3

19

30

Infant milk powder

7.6×102

1×103

2×102

43.3

13

12×103

33×103

4×103

83.3

25

30

Milk- cereal based weaning food

 

 


Table 2: Statistical analytical results of Total Spore Count at 37°C and 55 °C.

 

At 55 °C

At  37°C

No. of the examined samples

Examined samples

Count /g

Positive samples

Count/ g

Positive samples

Mean

Max.

Min.

%

No.

Mean

Max.

Min.

%

No.

10×103

38×103

1×102

13.3

4

22×102

15×103

1×102

83.3

25

30

Milk powder

 

0

0

0

0

0

13×103

44×103

20

33.3

10

30

Infant milk powder

59× 102

19×103

1×103

43.3

13

11×103

81×103

1×103

60

18

30

Milk- cereal based weaning food

 

 

 

 

 

Figure 1: Incidence of Geobacillus spp. in the examined samples at 55 ºC.

 

 

 

 

 

 

Figure 2: Incidence of other Bacillus spp. in the examined samples at 37 °C.

 

 

 

 

Figure 3: Incidence of other Bacillus spp. in the examined samples at 55 °C.

 


DISCUSSION

 

Although it is universally accepted that these thermophilic bacilli do not constitute a health risk to the consumer, they have been deemed to be an indicator of plant hygiene during processing, and specification limits have been implemented based on numbers of thermophilic bacilli in products (Murphy et al., 1999; Kwee et al., 1986;Ronimus et al., 2003). Recently, the thermophilic bacilli could not only cause spoilage due to their production of acids and thermostable enzyme excretion, but also cause food-borne illness (Burgess et al., 2010).

 

In the present study, the mean count of total thermophillic count at 37°C in the examined samples were 10×103, 13×103and 12×103/g and found to be 1×102, 0 and 7.6×102 /g at 55°C in examined samples of milk powder, infant milk formulae and milk-cereal based weaning food samples, respectively (Table 1). The percentage of total thermophilic counts at 37°C were 70, 63.3 and 83.3 %, while at 55 °C were 6.7, 0 and 43.3in the examined samples respectively. Dong et al. (2012) could isolate B. licheniformis in percent of 27.8%in the examined samples of milk powder and it considered higher than that obtained in this study. Thermophilic bacilli had been isolated from milk powder plants in New Zealand and also from milk powders collected from 18 countries around the world, and the dominant thermophilic bacilli in milk powder samples were relatively consistent (Ronimus et al., 2003; Rueckert et al., 2004; Scott et al., 2007).

 

From Table (2), total spore count were detected in 83.3, 33.3 and 60 % in examined samples of milk powder, infant milk formulae and milk-cereal based weaning food samples, respectively at 37°C. At 55°C, total spore count failed to be detected in the examined samples of infant milk formulae, while the mean total spore count reached to 10×103 and 59× 102 /g in the examined samples of milk powder and milk-cereal based weaning food, respectively.

 

Spores are resistant to heat, mechanical disruption and a wide variety of chemicals, making it very hard to destroy them in dairy manufacturing processes (Jones et al., 2005 and Scheldeman et al., 2006).

 

Typically, milk powder is produced continuously over an 18–24 h processing period during which the number of thermophilic bacilli in the product often mirrors that of a typical bacterial growth curve. Thus, with increased processing time, the number of thermophiles increases until specification limits are reached and the process run is terminated to prevent product downgrading. Many factors, such as the microbiological quality of the raw milk or the thermal operating conditions in the plant (low-, medium or high heat treatments) or the plant hygiene can all affect the growth of thermophiles in the processing line, making it difficult to predict a processing time that ensures thermophile numbers at the end of the run are below specified limits. In practice, actual numbers of contaminants in milk powders are determined retrospectively by plate counting, providing results commonly after 16–48 h. Due to these microbiological constraints, it is common practice to terminate processing runs by initiating CIP (cleaning in place) with the expectation that the numbers of thermophilic bacilli will be below their specification limits (Stadhouders et al., 1982; Murphy et al., 1999; Kwee et al., 1986; Ronimus et al., 2003).

 

It's of interesting observation, that G. stearothermophilus could be isolated only from milk-cereal based weaning food in percentage of 16.7 % (5 samples) and failed to be detected in other examined samples (Fig.1). Dong et al. (2012) could isolate G. stearothermophilus in higher percentage from milk powder (12.4%) Geobacillus strains have been isolated from temperate areas, as well as hot environments, such as hot springs, oilfields, deep sea sediments, sugar refineries and dairy factories (Tai     et al., 2004).

 

 Other Bacillus spp., could be found in the examined samples of milk powder where B. cereus and            B. circulans in percentage of 33.3 and 33.3 % at 37°C, respectively. While, B. lichenformis could be isolated in percentage of 13.3% at 55 °C. At 37°C,    B. cereus, B. circulans and B. pumilus could be identified in 16.7, 13.3 and 20% of isolates of infant milk formulae, respectively. Milk-cereal based weaning food samples found to be contaminated with B. cereus, B. circulans, B. papilliae and B. schlegellii at 37 °C and contaminated with B. lichenformis and B. schlegellii in percentage of 16.7 and 43.3%, respectively at 55 °C (Figures 2 and 3).

 

Another study in New Zealand milk powder plants revealed that seven strains of thermophilic bacilli were able to grow at 55 °C or above and recognized as the major contaminants growing in the processing lines (Ronimus et al., 2003). These are G. stearothermophilus, Anoxybacillus flavithermus, B. licheniformis and B. subtilis. Furthermore, a second investigation on milk powders from 18 different countries demonstrated that A. flavithermus. B. Licheniformis and G. stearothermophilus  represent world-wide sources of contamination being near-ubiquitously present in milk powders, and are thus of economic importance in processing (Rueckert et al., 2004).

 

Strains of obligate and facultative thermophiles are capable of producing acids, as well as a variety of heat-stable enzymes, including proteinases and lipases, which could result in the spoilage of dairy products (Gundogan and Arik, 2004; Murugan and Villi, 2009). In the present study, all G. stearothermophilus isolates have lipolytic and proteolytic activities. The real potential for the obligate thermophiles to spoil dairy products is thought to be low, as dairy products are generally stored at temperatures below 37 °C, temperatures at which obligate thermophiles will not grow. However, G. stearothermophilus has been associated with ‘flat-sour’ spoilage in a variety of canned food products, including evaporated milk (Kalogridou-Vassiliadou, 1992). In the case of facultative thermophiles, some strains of B. licheniformis are also capable of producing a slimy extracellular substance that can affect the quality of pasteurised milk and cream (Gilmour and Rowe, 1990).

 

In fact, the levels of thermophiles in raw milk are usually very low (e.g. b10 cfu/mL) (Hill and Smythe, 1994;McGuiggan et al., 2002). On rare occasions when higher levels do occur (e.g. N100 cfu/mL), the predominant thermophilic species in this raw milk tend to be B. licheniformis and B. coagulans. However, when the final product from raw milk of this quality is processed, the predominant thermophilic species tend to be A. flavithermus and Geobacillus spp (Burgess et al., 2010).

 

CONCLUSION

 

These contaminants are used as indicator organisms for plant hygiene and specification limits based on their numbers have been implemented to ensure milk powder quality. The attention of industry and researcher should be focused on dairy products stored at room temperature, since the occurrence of strains producers of proteases was highest at 30ºC. Taking into account that these products have a long shelf life, these enzymes may act on proteins, altering their sensory characteristics. Consumers’ demands increasingly aim at high-quality, minimally processed, nutritious and fresh-like products. Traditional thermal processing methods cause loss of desirable properties related to texture, flavor, color, and nutrient value. However, the most serious commercial problems with product sterility are caused by thermally resistant spores. In an attempt to provide alternatives to solve these problems,

 

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أهمية أجناس الجيوباسيلس کمجموعة من الملوثات البکتيرية في صناعة الألبان

 

مروة محمد نبيل الجندي ، ناهد محمد وهبة

Email: moazahmednofel@yaloo.com

                                                        

 تعد کل من الألبان الجافة والأغذية الجافة المحتوية علي اللبن من الأغذية واسعة التدوال لدي الکبـار والأطفال، وتلوثها بميکروب الجيوباسيليس من الأمور التي تستوجب الاهتمام والدراسة لما يسببه هذا الميکروب من فساد لمنتجات الألبان وذلک لقدرته علي إفراز الإنزيمات والأحماض التي تسبب تحلل البروتينات والدهون في اللبن. لذلک تضمنت هذه الدراسة فحص عدد 90 عينة عشوائية من أغذية الأطفال اللبنية الجافة بواقع 30 عينة من لبن البودرة، 30 عينة من اللبن الجاف للأطفال و30 عينة من أغذية الفطام الجافة المحتوية علي خلاصة الحبوب. وکانت صالحة للاستهلاک حيث تمتد فترة صلاحيتها لمدة لا تقل عن عام من تاريخ الإنتاج وتم جمع هذه العينات من العديد من المحال التجارية والصيدليات في مدينة أسيوط لمعرفة مدي تلوثها بالميکروبات المختلفة. وتم فحص العينات عند درجة حرارة 37 و 55 °C حيث ان ميکروب الجيوباسيليس من مجموعة البکتيرية التي تنمو في درجات حرارة عالية. ودلت النتائج أن متوسط  العدد الکلي للميکروبات (عند°C 37) کان10×103 في اللبن البودرة بينما وصل الي13×103 و12×103 في لبن الأطفال وأغذية الأطفال الجافة المحتوية علي اللبن، علي التوالي. بينما کان متوسط العدد الکلي للميکروبات المحبة للدرجة الحرارة العالية عند درجة حرارة°C 55 1×102 و 7.6×102 في اللبن البودرة وأغذية الأطفال الجافة المحتوية علي اللبن ، علي التوالي. بينما لم تتواجد في لبن الأطفال وکانت متوسطات الحويصلات عند درجة حرارة °C37 علي التوالي هي 22×102 ،13×103و11×103 وبينما عند درجة حرارة 55 °C کانت متوسطات الحويصلات  10×103 و 59×102 علي التوالي في اللبن البودرة وأغذية الأطفال الجافة المحتوية علي اللبن ولم تتواجد في لبن الأطفال أيضا. أما الجيوباسيليس ستريوسيرموفيليس فقد تم عزلها فقط من أغذية الأطفال الجافة المحتوية علي اللبن بنسبة  16.7% من العترات المعزولة عند درجة حرارة 55°C. کما تم عزل بعض الأجناس الاخري من الباسيليس بنسب مختلفة وعند درجات حرارة مختلفة. وقد أثبتت النتائج قدرة الجيوبايليس علي تحليل البروتينات والدهون.     

 

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