EXPERIMENTAL STUDIES ON THE INHIBITORY EFFECT OF DIFFERENT CONCENTRATION OF POTASSIUM SORBATE ON THE VIABILITY OF YERSINIA ENTEROCOLITICA IN POULTRY MEAT FILLETS

Document Type : Research article

Authors

Department of Food Hygiene-Animal Health Research Institute-Dokki-Giza-Egypt

Abstract

The effect of different concentrations of potassium sorbate on the survival of Yersinia enterocolitica (serotype: O:8) contaminated chicken fillets incubated at 4oC for 21 days were compared.
The potassium sorbate concentrations compared included 3, 5, 10% expressed as 400, 668 and 1325 ppm. sorbic acid respectively.
The decrease in viable Yersinia cells was compared based on the concentration of acid salt dip, pH determination after 10 days of storage and calculated concentration of sorbic acid throughout and at the end of storage period.
Results indicated that 4oC storage temperature and 10% potassium sorbate treatment (1325 ppm sorbic acid) attached to low pH value (5.4) provided the most effective inhibitory system against Yersinia enterocolitica in chicken fillets. The shelf life of sorbate treated samples was extended more than 10 days at 4oC over the control samples (without sorbate treatment). Quantities of sorbic acid found in the samples treated with potassium sorbate were below the acceptable daily intake (ADI) established by the Food and Agriculture Organization/World Health Organization.

Keywords


EXPERIMENTAL STUDIES ON THE INHIBITORY EFFECT OF DIFFERENT CONCENTRATION OF POTASSIUM SORBATE ON THE VIABILITY OF YERSINIA ENTEROCOLITICA IN POULTRY MEAT FILLETS

By

Nour, M. K. Hassan and Isis, G. Antown

Department of Food Hygiene-Animal Health Research Institute-Dokki-Giza-Egypt

SUMMARY

The effect of different concentrations of potassium sorbate on the survival of Yersinia enterocolitica (serotype: O:8) contaminated chicken fillets incubated at 4oC for 21 days were compared.

The potassium sorbate concentrations compared included 3, 5, 10% expressed as 400, 668 and 1325 ppm. sorbic acid respectively.

The decrease in viable Yersinia cells was compared based on the concentration of acid salt dip, pH determination after 10 days of storage and calculated concentration of sorbic acid throughout and at the end of storage period.

Results indicated that 4oC storage temperature and 10% potassium sorbate treatment (1325 ppm sorbic acid) attached to low pH value (5.4) provided the most effective inhibitory system against Yersinia enterocolitica in chicken fillets. The shelf life of sorbate treated samples was extended more than 10 days at 4oC over the control samples (without sorbate treatment). Quantities of sorbic acid found in the samples treated with potassium sorbate were below the acceptable daily intake (ADI) established by the Food and Agriculture Organization/World Health Organization.

INTRODUCTION

Yersinia enterocolitica is psychrotrophic bacterium which has only in the last decades become established as food borne human pathogen. During this time a number of food borne disease outbreaks have been attributed to this organism (Abraham et al., 1997and Ackers et al., 2000). There have been numerous studies that have reported on the incidence of Yersinia enterocolitica on fresh poultry meat in Egyptian markets ranged from 8.5 to 18% (Abd El-Monem and Saad, 1998). Green Wood and Hooper (1990) found that poultry and meat products were contaminated by Yersinia enterocolitica mainly during subsequent processing.

The most common symptoms of Yersinia infection is gastroenteritis although other symptoms can include mesenteric lymphadenitis, terminal ileitis and arthritis (Cover and Aber, 1989). Moreover, this organism is unique among common food borne pathogens in being able to mimic appendicitis as a result of invasiveness of the organism via intestinal epithelial tissue in addition to the enterotoxin and enzyme production (Meer et al., 1991). Wei et al., (2001) mentioned that Yersinia enterocolitica is a psychrotrophic pathogenic bacterium that has an important public health concern in food industry, this               pathogen was well documented as a causative agent of human gastroenteritis and also it could grow under anaerobic condition and at temperature as low at -20oC.

The ability of food borne pathogens to survive in acidic environments is important because acidity is often used in foods to control these bacteria, Yersinia enterocolitica is one pathogen that has shown this ability.

Stern and Pierson (1979) reported that four separate strains of Yersinia enterocolitica grew at pH 4.6, Kendall and Gilbert (1980) demonstrated that this organism grew at pH 4.4 and above and survived for at least 72 hours at pH 4.2 and Robert, (1987) also found viable Yersinia enterocolitica cells after 21 days at pH 4.0 at 5oC. Helms et al., (2003) stated that short and long term mortality was associated with infection with Yersinia enterocolitica and added that in Denmark from 1991-1999 the number of patients suffering from Yersinia was 4045 and the number of death was 32 persons (0.08%).

Extensive researchers on the use of sorbic acid and its salts as preservative in foods was reviewed (Sofa and Busta, 1981; Sofa and Busta, 1983 and Elliott et al., 1985).

Sorbic acid and potassium sorbate were originally used to inhibit the growth of molds and yeasts, but it has been found that they also act upon Staphylococuus aureus, Colstridium botulinum, salmonellae, Pseudomonas and Yersinia. Antimicrobial effect in meat products has been studied for inhibiting bacterial growth in sausage (Tompkin et al., 1974), for prolonging shelf life of poultry (Robach and Sofa, 1982). Myers et al., (1983) studied the effect of sorbate to diminish the growth of Yersinia species and mentioned that the results were highly satisfactory. Greer (1982) investigated the influence of this preservative on the growth of psychrtrophic bacteria which deteriorate beef.

The antimicrobial properties of sorbic acid salts especially potassium sorbate are very important and more preferable application due to high solubility in water. The low water solubility is a disadvantage of sorbic acid. At 25oC, the solubility of acid in water is 0.16% and of potassium sorbate in water is over 50%. An increase in fat content of tissue will also lower the amount of sorbic acid in the aqueous phase where it is needed for microbial control. Sorbic acid is a lipophilic acid preservative with a short chain length and this kind of substance inhibits both Gram positive and Gram negative bacteria (Sofa and Busta, 1981).

The purpose of the present study was to evaluate the effectiveness of potassium sorbate (different concentrations) expressed as sorbic acid (ppm), storage temperature (4oC) and pH (5.3-5.9) on the quality of refrigerated chicken fillets artificially contaminated with Yersinia enterocolitica (serotype O:8).

MATERIALS AND METHODS

Cultures:

Culture used for this study was Yersinia enterocolitica (serotype O:8 strain) provided by Department of Food Control, Faculty of Veterinary Medicine, Zagazig University. Before used in experiments culture was checked for purity by streaking onto Cefsulodin Irgasan-Novobiocin (CIN) agar; Oxoid), and incubated at 32oC for 18-24 hours, up to 5 typical forms dark red bulls eye like colonies with a transparent border were picked up and maintained on Tryptic Soy Agar salnts (TSA; Difco) incubated for 24 hours at 25oC and held at 5oC until use.

Preparation of samples:

Chicken fillets from freshly slaughtered chicken were received from the processing plant in a chilled condition (muscles were cut in slices, transversely to the fibers, 10 cm in diameter and one cm thick, 120 gm weight). Samples (16 slices) were divided into 4 groups, 3 groups as examined samples and one control. All samples were exposed to ultraviolet rays (lamp, Clean Air Techniek bv, Netherlands) for surface sterilization and the treatment began within 3 hours upon receipt.

Appropriate Yersinia culture suspension was diluted into one liter of phosphate buffer (pH 7.2) to give a cell suspension of 104 cfu/ml. Experimentally examined samples and control ones (4 groups) were inoculated by dipping in Yersinia suspension for 1 minute and drained dry. Each group of experimentally examined samples were then dipped for one minute in 3% aqueous solution of potassium sorbate for the first group, 5% for the second group and 10% for the third one. Control group was dipped in sterile distilled water, all samples were individually bagged and stored at 4oC for 21 days.

Sorbate analysis:

Sorbate assay in chicken meat fillets was performed by triplicate on samples 10 cm diameter and 1 cm thick using ultraviolet spectrophotometer with ethyl ether extraction in acid medium according to AOAC (1990). A Double-Beam UV-Visible digital spectrophotometer model UV-150 (Shimad ZU Corp., Tokyo) was used, and the absorbance was determined at 250 nm. Measurments were performed throughout and at the end of the storage period. Total concentration of sorbate was expressed as ppm. sorbic acid based on the weight of the sample (Zamora and Zaritzky, 1987).

PH determination:

PH determination was performed after 10 days of storage period by using pH meter model 3310 (Jenway LTd. UK).

Microbiological analysis:

After each storage interval (0, 3, 7, 10, 14, 17 and 21 days), The packages were opened aseptically at random using sterile forceps. A ribbon (10cm2 in surface and approximately 0.3 cm thick) was removed along the lateral area of the muscle by means of a sterile forceps and scalpel. Each sample (20 g) was then placed in 500 ml flask containing 180 ml of sterile 0.1% peptone broth and shaken for 15 minutes at 250 rpm and 30oC (shaker Model G-52). Appropriate dilutions were made with sterile 0.1% peptone broth and duplicate plates of CIP agar were used, enumeration of typical Yersinia colonies was performed at 32oC for 24 hours.

 

RESULTS

Table (1) Determination of potassium sorbate (as sorbic acid ppm) in the examined chilled poultry fillets.

pH of inoculated samples

% of potassium sorbate dip

Sorbic acid (ppm)

No. of samples

 

0

0

4 (control)

5.8

3.0

400

4 (samples)

6.0

5.0

668

4 (samples)

6.2

10.0

1325

4 (samples)

 

 

 

 

Table (2) Effect of storage period on residual sorbic acid in the examined samples.

Sorbic acid in chicken meat (ppm)

Storage period (days)

0

3

7

10

14

17

21

400

397

399

400

402

400

395

392

668

663

665

665

670

668

665

670

1325

1321

1327

1329

1330

1328

1327

1327

 

Table (3) Behavior of Yersinia enterocolitica under treatment by different potassium sorbate concentrations.

    Log cfu/gm

 

Time/day

Control

Potassium sorbate concentration

3%

5%

10%

0

4.8

4.8

4.6

4.2

3

6.6

4.1

4.0

3.7

7

7.2

4.5

4.2

3.4

10

7.9

5.4

4.6

4.2

14

8.2

6.9

5.3

4.6

17

8.5

6.2

5.8

4.8

21

9.0

6.6

5.5

4.3

 

 

  

 

 

 

DISSCUSION

Results of this investigation revealed that there were apparent differences in the antimicrobial activity of various sorbic acid concentrations on Yersinia enterocolitica. In this way these results support those found in similar studies with other microorganisms (Minor and Marth, 1972).

The initial sorbate concentration layer at the surface of samples diffuses into the meat bulk due to the concentration gradient (Torres et al., 1985). During prolonged storage time sorbate profile tends to reach a uniform distribution, and it is convenient to express this concentration based on sample weight. Solutions of potassium sorbate in a range 3-10% left residues between 400-1325 ppm of sorbic acid in poultry meat (Table 2).

Observed difference between residual sorbate levels in refrigerated meat samples during storage period (Table 1) were not statistically significant (p>0.05). These results agreed with data reported by Robach et al., (1980). Zamora and Zairtzky (1987) reported that, average of residual potassium sorbate (as sorbic acid-669 ppm) in beef slightly increased during the storage period (38 days at 4oC) up to 679 ppm). Data obtained from this study indicated that a one minute dip of chicken fillets in 5% (w/v) potassium sorbate significantly improved their storage life at 3oC between 0 and 21 days of storage.

Sorbate treated slices by 3% had about 2 log cycle reductions in Yersinia count per cm2 compared to control ones, but reached to 4 log cycle reduction at 10% potassium sorbate concentration comparable with control samples (Table 3 and Figure 1).

A marked difference in Yersinia enterocolitica counts between control and sorbate treated samples was observed after 10 days of storage period.     Figure (1) showed that counts reduction of sorbate treated slices were 3, 3.5 and 4 log cycle per cm2 at 3%, 5% and 10% potassium sorbate concentration and pH values 5.6, 5.3, 5.4 respectively compared by control samples. These results agree with that obtained by To and Robach (1979); Elliott et al., (1985) and Robert (1987).

Spoilage of control samples, as judged by slime and odour formation started after 7 days while sorbate treated samples were in good condition up to 17 days of storage at 3oC. Zamora and Zaritzky (1987) studied the effectiveness of potassium sorbate in poultry, finding that a dipping of 30 seconds of 8% solution (residue of 1200-1300 ppm of sorbic acid) prolonged the shelf life of the product at 3oC from 10 days (control) to 17 days.

The birds in this study were processed in a commercial plant; hence results should have commercial application.

Growth of Yersinia enterocolitica was controlled by sorbate treatment so, sorbates are considered as Generally Regarded As Safe (GRAS) food additives, no resistant bacterial strains were developed by its use in poultry and treated poultry is highly acceptable organoleptically (To and Robach, 1979).

Zamora and Zaritzky (1987) determined that application of 3200 ppm sorbic acid in fresh poultry (10% potassium sorbate used as a dip for 60 seconds) did not affect sensory characteristics of cooked poultry.

Sorbic acid is considered to be a non-toxic compound for human beings, as it is metabolized like fatty acids, i.e. to carbon and water.

 An Admitted Daily Intake (ADI) of up to 1500 mg of sorbic acid for a 60 kg body weight was established by FAO/WHO (1974). Assuming an average daily consumption of beef (150 gm) and considering the maximum residue in the slices determined in the present study (1325 ppm sorbic acid). The mean daily intake resulted in 198.75 mg of sorbic acid, this value is well below the ADI within the limits established by the results, and the risk for the use of potassium sorbate in beef was negligible, because the amount ingested was quite low.

The benefits included the accomplishment of an optimal quality product (chicken meat fillets) with a longer shelf life, which made marketing for longer periods of time possible.

REFRENCES

Abd E-Monem, K. H. M. and Saad, S. M. (1998): Yersinia enterocolitica in poultry and meat products. J. Egypt. Vet. Med. Ass., 58: 545.

Abraham, M.; Pai, M.; Kang, G.; Asokan, G. V.; Magesh, S. R.; Bhattacharji, S. and Ramakrishna, B. S. (1997): An outbreak of food poisoning in Tamil Nadu associated with Yersinia enterocolitica. Indian J. Med. Res., 106: 465.

Ackers, M. L.; Schoenfeld, S.; Markman, J.; Smith, M. G.; Nicholson, M. A.; Dewitt, W.; Camerson, D. N. Griffin, P. M. and Slutsker, L. (2000): An outbreak of Yersinia enterocolitica O:8 infection associated with pasteurized milk. J. Infec. Dis., 181: 1834.

AOAC (1980):  "Official Methods of Analysis" Edi W. Horwitz, Methods 20: 104 Association of Official Analytical Chemists, Washington, DC.

Cover, T. L. and Aber, r. (1989): "Yersinia enterocolitica" New England J. Med., 321: 16.

Elliott, P. H.; Tom.ins, R. I. and Gray, R. J. H. (1985): Control of microbial spoilage on fresh poultry using a combination potassium sorbate/carbon dioxide packaging system. J. Food Sci., 50: 1360.

FAO/WHO (1974): Joint Expert Committee on Food Additives 17th Report. WHO Techn. Rep. Ser., No. 539 World Health Organization, Geneva.

Green Wood, M. H. and Hooper, W. L. (1990): Excereation of Yersinia species associated with consumption of pasteurized milk. J. Epidmiol. Infect. 104: 350.

Greer, G. G. (1982): Mechanism of beef shelf life extension by sorbate. J. Food Prot., 45: 82.

Helms, M.; Vustrup, P.; Gierner-Shmidt, P. and Ibak, M. K. (2003): Short and long term mortality associated with food borne bacterial gastrointestinal infection: Registry based study. B M I 326 (7385): 357.

Kendall, M. and Gilbert, R. J. (1980): Survival and growth of Yersinia enterocolitica. P. 215-226. In. G. W. Gould and J. E. L. in extremes of environment. Society of Applied Bacteriology Technical Series. No. 15. Academic Press. London.

Meer, r. R.; Baker, J.; Bodyfett, F. W. and Griffiths, M. (1991): Psychrotrophic Bacillus species in fluid milk products. A review. J. Food. Prot., 54: 969.

Minor, T. E. and Marth E. H. (1972): Loss of viability by Staphylococcus aureus in acidified media. I. Inactivation by several acids, mixtures of acids, and salts of acids. J. Milk food Technol., 35: 191.

Myers, B. R.; Edmondson, J. E.;Anderson, M. E. and Marshall, R. T. (1983): Potassium sorbate and recovery of pectinolytic psychrotrophs from vacuum packaged pork. J. Food Prot., 46: 499.

Robach, M. C. and Sofa, J. N. (1982):  Use of sorbates in meat products, fresh poultry and poultry products. A review. J. Food Prot., 45: 374.

Robach, M. C.; To, E. C.; Meyelav, S. and Cook, C. F. (1980): Effect of sorbates on microbial growth in cooked turkey products. J. Food. Sci., 45: 638.

Robert, E. B. (1987): Effects of various acids on growth and survival of Yersinia enterocolitica. J. Food Prot., 50: 603.

Sofa, J. N. and Busta, F. F. (1981): Antimicrobial activity of sorbate. J. Food Prot., 44: 614.

Sofa, J. N. and Busta, F. F. (1983): Sorbate In: "Antimicrobials in Foods" (Ed). A. L. Branen and P. M. Davidson, P. 141 Marcel Dekker, Inc. New York.

Stern, N. J. and Pierson, M. D. (1979): Yersinia enterocolitica: A review of the psychrtrophic water and food pathogens. J. Food Sci., 44: 1736.

To, E. C. and Robach, M. C. (1979): Potassium sorbate dip as a method of expanding shelf life and inhibiting the growth of Salmonella and Staphylococuus aureus on fresh, whole broilers. J. Poultry Sci., 59: 726.

Tompkin, R. B.; Christianen, L. N.; Shaparis, A. B. and Bolin, H. (1974): Effect of potassium sorbate on Salmonellae, Staphylococuus aureus, Clostridium perfringens and Clostridium botulinium in cooked, uncooked sausage. Appl. Microbiol., 28: 262.

Torres, J. A.; Motoki, M. and Karel, M. (1985): Microbial stabilization of intermediate moisture food surface. I. Control of surface preservative concentration. J. Food Proc. Preserv., 9: 75.

Wei, G. K.; Fang, T. J. and Chenn, W. C. (2001): Development and validation of growth model for Yersinia enterocolitica in cooked chicken meats packaging under various atmosphere packaging and stored at different temperature. J. Food Prot., 64: 987.

Zamora, M. C. and Zaritzky, N. E. (1987): Potassium sorbate inhibition of microorganisms growing on refrigerated packaged beef. J. Food Sci., 52: 257.

 

 

 

الملخص العربى

دراسـة معملية عن التأثير المثبط للترکيزات المختلفة لسـوربات البوتاسيوم على حيوية ميکروب اليرسـينيا إنتيروکوليتيکا فى فيليه لحوم الدواجن

 

تم دراسة تأثير الترکيزات المختلفة (3, 5, 10٪) المثبطة لسـوربات البوتاسيومفى صورة حمض السوربيک (400, 668, 1325 جزء فى المليون) على حيوية ميکروب اليرسينيا إنتيروکوليتيکا (عترة نموذجية من نوع 0.8) التى تم تلويث عينات فيلية الدواجن بها وتم إجراء التجربة المعملية فى مدة 21 يوم عند درجة تبريد قدرها 4 درجة مئوية وکانت نتائجها کالتالى:

 الترکيز الأعلى للبوتاسيوم سوربات (10٪) 1325 جزء فى المليون حمض سوربيک عند أقل درجة ترکيز هيدروجينى( 5 ) وکان لها التأثير المبثط  الأقوى على ميکروب اليرسينيا إنتروکوليتيکا فى فيلية الدجاج المختبر مما أطال فترة عمر صلاحية للعينات لأکثر من عشرة أيام عن العينات الضابطة وذلک فى درجة حرارة الثلاجة (4 درجة مئوية).

کما أوضحت التجربة أن أعلى کمية من حمض السوربيک (بوتاسيوم سوربات ) أستخدمت فى هذه الدراسة المعملية کانت أقل بکثير من الحد المسموح تناولة يوميا من خلال الوجبات الغذائية طبقا للمواصفات الدولية المتعارف عليها .

کما تم مناقشة الأهمية الحيوية لإستخدام أملاح السوربات فى الأغذية لإطالة فترة صلاحيتها.

Abd E-Monem, K. H. M. and Saad, S. M. (1998): Yersinia enterocolitica in poultry and meat products. J. Egypt. Vet. Med. Ass., 58: 545.
Abraham, M.; Pai, M.; Kang, G.; Asokan, G. V.; Magesh, S. R.; Bhattacharji, S. and Ramakrishna, B. S. (1997): An outbreak of food poisoning in Tamil Nadu associated with Yersinia enterocolitica. Indian J. Med. Res., 106: 465.
Ackers, M. L.; Schoenfeld, S.; Markman, J.; Smith, M. G.; Nicholson, M. A.; Dewitt, W.; Camerson, D. N. Griffin, P. M. and Slutsker, L. (2000): An outbreak of Yersinia enterocolitica O:8 infection associated with pasteurized milk. J. Infec. Dis., 181: 1834.
AOAC (1980):  "Official Methods of Analysis" Edi W. Horwitz, Methods 20: 104 Association of Official Analytical Chemists, Washington, DC.
Cover, T. L. and Aber, r. (1989): "Yersinia enterocolitica" New England J. Med., 321: 16.
Elliott, P. H.; Tom.ins, R. I. and Gray, R. J. H. (1985): Control of microbial spoilage on fresh poultry using a combination potassium sorbate/carbon dioxide packaging system. J. Food Sci., 50: 1360.
FAO/WHO (1974): Joint Expert Committee on Food Additives 17th Report. WHO Techn. Rep. Ser., No. 539 World Health Organization, Geneva.
Green Wood, M. H. and Hooper, W. L. (1990): Excereation of Yersinia species associated with consumption of pasteurized milk. J. Epidmiol. Infect. 104: 350.
Greer, G. G. (1982): Mechanism of beef shelf life extension by sorbate. J. Food Prot., 45: 82.
Helms, M.; Vustrup, P.; Gierner-Shmidt, P. and Ibak, M. K. (2003): Short and long term mortality associated with food borne bacterial gastrointestinal infection: Registry based study. B M I 326 (7385): 357.
Kendall, M. and Gilbert, R. J. (1980): Survival and growth of Yersinia enterocolitica. P. 215-226. In. G. W. Gould and J. E. L. in extremes of environment. Society of Applied Bacteriology Technical Series. No. 15. Academic Press. London.
Meer, r. R.; Baker, J.; Bodyfett, F. W. and Griffiths, M. (1991): Psychrotrophic Bacillus species in fluid milk products. A review. J. Food. Prot., 54: 969.
Minor, T. E. and Marth E. H. (1972): Loss of viability by Staphylococcus aureus in acidified media. I. Inactivation by several acids, mixtures of acids, and salts of acids. J. Milk food Technol., 35: 191.
Myers, B. R.; Edmondson, J. E.;Anderson, M. E. and Marshall, R. T. (1983): Potassium sorbate and recovery of pectinolytic psychrotrophs from vacuum packaged pork. J. Food Prot., 46: 499.
Robach, M. C. and Sofa, J. N. (1982):  Use of sorbates in meat products, fresh poultry and poultry products. A review. J. Food Prot., 45: 374.
Robach, M. C.; To, E. C.; Meyelav, S. and Cook, C. F. (1980): Effect of sorbates on microbial growth in cooked turkey products. J. Food. Sci., 45: 638.
Robert, E. B. (1987): Effects of various acids on growth and survival of Yersinia enterocolitica. J. Food Prot., 50: 603.
Sofa, J. N. and Busta, F. F. (1981): Antimicrobial activity of sorbate. J. Food Prot., 44: 614.
Sofa, J. N. and Busta, F. F. (1983): Sorbate In: "Antimicrobials in Foods" (Ed). A. L. Branen and P. M. Davidson, P. 141 Marcel Dekker, Inc. New York.
Stern, N. J. and Pierson, M. D. (1979): Yersinia enterocolitica: A review of the psychrtrophic water and food pathogens. J. Food Sci., 44: 1736.
To, E. C. and Robach, M. C. (1979): Potassium sorbate dip as a method of expanding shelf life and inhibiting the growth of Salmonella and Staphylococuus aureus on fresh, whole broilers. J. Poultry Sci., 59: 726.
Tompkin, R. B.; Christianen, L. N.; Shaparis, A. B. and Bolin, H. (1974): Effect of potassium sorbate on Salmonellae, Staphylococuus aureus, Clostridium perfringens and Clostridium botulinium in cooked, uncooked sausage. Appl. Microbiol., 28: 262.
Torres, J. A.; Motoki, M. and Karel, M. (1985): Microbial stabilization of intermediate moisture food surface. I. Control of surface preservative concentration. J. Food Proc. Preserv., 9: 75.
Wei, G. K.; Fang, T. J. and Chenn, W. C. (2001): Development and validation of growth model for Yersinia enterocolitica in cooked chicken meats packaging under various atmosphere packaging and stored at different temperature. J. Food Prot., 64: 987.
Zamora, M. C. and Zaritzky, N. E. (1987): Potassium sorbate inhibition of microorganisms growing on refrigerated packaged beef. J. Food Sci., 52: 257.