Microbial spoilage of pre-cooked potato-topped pies

The ecological succession of bacteria which developed in pre-cooked potato-topped pies stored at two different temperatures was examined. Bacillus, Streptococcus and Staphylococcus-Micrococcus spp. were the predominant organisms isolated from freshly prepared pies and those stored at 4°C and 37°C. None of these groups of bacteria caused significant biodeterioration of pies held at 4°C, but all groups grew well in pies stored at 37°C and achieved counts of ca 10⁸/g of sample. Bacillus spp. were the first group to grow, followed by Streptococcus and Staphylococcus- Micrococcus spp. Growth which occurred at 37°C did so at the expense of glucose, lactate accumulated and the pH of pie components decreased. Amylase activity detected in all pie components during storage was associated with the growth of Bacillus spp. and probably supplemented glucose already present in pies, by hydrolytic cleavage of potato, flour or binder starches. Spoilage caused by growth and activity of the bacteria isolated was not associated with visual signs of bio-deterioration, nor production of 'off' odour usually associated with spoilage of meats. These results suggest that pre-cooked potato-topped pies held at inappropriate temperatures represent a potential public health risk.     

Examination of bovine faeces for the isolation and identification of Clostridium species

Freshly cooked luncheon meat in a plastic (PVDC) casing had an aerobic plate count of about 10²/g. The flora was composed of approximately equal numbers of Bacillus and Micrococcus spp. Storage at 10°C for 42 d produced little increase in bacterial numbers, or changes in pH value or glucose content at either the surface or core of the luncheon meat. Storage at 25°C allowed Bacillus spp. to proliferate at the surface. The inhibitory effect of salt and nitrite on the growth of heated Bacillus spores at low redox potentials probably accounts for the absence of growth within the product. Growth at the surface was accompanied by a fall in pH (6.8 to 6.2) and an increase in glucose (1.6 to 3.6 mg/g) and L(+)-lactic acid (1.2 to 2.3 mg/g). By day 14 the Bacillus spp. had been displaced by a Streptococcus sp. (10⁷/g) which remained the dominant organism until the experiment ended on day 28. The pH continued to fall from 5.7 on day 14 to 5.2 on day 28, the L(+)-lactic acid rose to 6.1 mg/g, but the glucose remained constant at the day 7 level (3.6 mg/g). This indicates that glucose converted to lactic acid was largely replaced by hydrolysis of the starch portion of the luncheon meat mediated by amylases produced by the Bacillus microflora. It appears that growth of the Streptococcus is dependent upon the denitrifying activities of the initial Bacillus flora reducing the concentration of nitrite ion to non-inhibitory levels.     

Control of microbiological quality and shelf-life of catfish (Clarias gariepinus) by chemical preservatives and smoking

Fresh catfish ( Clarias gariepinus ) were subjected to different concentrations of sodium benzoate or potassium sorbate and smoked traditionally before evaluation for microbiological, chemical and organoleptic characteristics during ambient tropical storage. Unsmoked fish samples showed diverse microflora ( Enterobacter, Escherichia, Serratia, Bacillus, Staphylococcus, Streptococcus, Penicillium, Aspergillus and Achlya genera) while smoked samples were dominated by Gram-positive bacterial flora ( Bacillus, Staphylococcus and Streptococcus ) and spoilage moulds ( Penicillium verrucosum, Aspergillus flavus and Achlya spp.). Significant reduction in microbial population occurred in most samples following smoking with samples subjected to 0.4% (w/v) potassium sorbate showing the lowest microbial load and maximum shelf-stability. However, marked microbial increase occurred after day 4 of storage in control and benzoate-treated samples. Changes in pH were marginal but decreased after day 12 of storage. Moisture content decreased sharply after smoking and remained low after day 4 of storage. Overall, potassium sorbate treatment (0.4% w/v) was most effective in controlling microbial quality and extended the shelf-life of the samples by 8 d.     

The effect of variation of thermal processing on the microbial spoilage of chub-packed luncheon meat

Process pasteurization values for reference temperature 70°C (P₇₀) were calculated from the temperature profiles of 250 g luncheon meat chubs cooked under experimental conditions. A simple equation relating Process P₇₀-value and the time and temperature of cooking was derived. With minimal cooking (P₇₀= 40) the surviving microflora (10³/g) was dominated by species of Lactobacillus, Brochothrix and Micrococcus. These organisms were destroyed by more intensive cooking (P₇₀= 105), leaving a flora (10²/g) composed of Bacillus and Micrococcus species. The spoilage that developed after 14 d storage at 25°C reflected the severity of the heat treatment received by each chub: with P₇₀ between 40 and 90, a Streptococcus spoilage sequence occurred; with P₇₀ between 105 and 120, a Bacillus/Streptococcus spoilage sequence occurred; with P₇₀ of 135 and above, a Bacillus spoilage sequence occurred. Cooking to a P₇₀= 75 was adequate to reduce the surviving microflora to the 10²/g level associated with current good manufacturing practice.     

Heat tolerance of Salmonella typhimurium DT104 isolates attached to muscle tissue

Aerobic and anaerobic plate counts were compared for routine monitoring of the microflora, dominated by lactic acid bacteria, developing on vacuum- and carbon dioxide-packaged raw meat during chilled storage. No statistical differences were observed between aerobic and anaerobic enumerations, made on plate count and blood agar plates, of the microflora developing on beef striploins packaged under vacuum or carbon dioxide during 14 weeks' storage at 0°C. With both techniques the spoilage microflora development differed between the two packaging regimes. The results indicate that there is no necessity for aerobic plate counts to be replaced by anaerobic plate counts in the routine microbiological examination of the spoilage microflora developing on chilled meats packaged under anoxic modified atmospheres.     

The role of oxygen in the microbial spoilage of luncheon meat cooked in a plastic casing

The shelf life at 25°C of chub-packed luncheon meat was inversely related to oxygen (O₂) availability within the casing. With fibrous casings that are freely permeable to O₂, shelf life was less than 3 d. With plastic casings of low O₂ permeability, the shelf life was 7 d when air was trapped in the emulsion during the casing filling process, 14 d when air was not trapped (normal vacuum-stuffing) and greater than 28 d when vacuum-stuffed chubs were stored in hydrogen (H₂). The initial spoilage bacteria, Bacillus spp., grew only at the surface unless air was trapped in the emulsion when growth occurred throughout the luncheon meat. Bacillus spp. failed to grow on luncheon meat stored under H₂. Oxygen availability within the casing determined both the site and rate of microbial spoilage of chub-packed luncheon meat.     

Effect of Hyperbaric Carbon Dioxide Pressure on the Microbial Flora of Pork Stored at 4 or 14°C

Changes in the microbial flora of pork stored at 4 or 14°C were studied in 5 atm CO₂, 1 atm CO₂ or 1 atm air. The time needed for the total aerobic count at 4°C to reach 5 × 10⁶ organisms/cm² was about three times longer in 5 atm CO₂ than in 1 atm CO₂, and about 15 times longer in 5 atm CO₂ than in air. At 14°C there was no difference in growth rate between 5 atm CO₂ and 1 atm CO₂. No off-odour was detected after storage in 5 atm CO₂ for 14 d, but the pork in 1 atm CO₂ (6 d) was organoleptically unacceptable.
The predominant organisms on the pork from the processing line were: Flavobacterium spp., Acinetobacter calcoaceticus, Pseudomonas spp., Micrococcus spp. and Moraxella spp. After aerobic storage at 4°C (8 d) or 14°C (3 d) more than 90% of the flora consisted of Pseudomonas spp. At 4°C all Pseudomonas spp. were of the non-fluorescent type, whilst at 14°C 32% were Ps. putida and Ps. fluorescens. After storage in 1 atm CO₂ Lactobacillus spp. represented 66% of the flora at 14°C (6 d) and 100% at 4°C (40 d), with L. xylosus dominating. After storage in 5 atm CO₂ Lactobacillus spp. constituted the total flora at both temperatures with L. lactis (14°C) and L. xylosus (4°C) dominating.
It was concluded that high partial pressures of CO₂ have a considerable shelf-life prolonging effect by (i) selecting the microflora towards Lactobacillus spp. and (ii) reducing the growth rate of these Lactobacillus spp. The controlling and growth inhibitory effect of CO₂ was promoted by reduced temperatures.     

Microbial spoilage of pre-cooked potato-topped pies

The ecological succession of bacteria which developed in pre-cooked potato-topped pies stored at two different temperatures was examined. Bacillus, Streptococcus and Staphylococcus-Micrococcus spp. were the predominant organisms isolated from freshly prepared pies and those stored at 4 degrees and 37 degrees C. None of these groups of bacteria caused significant biodeterioration of pies held at 4 degrees C, but all groups grew well in pies stored at 37 degrees C and achieved counts of ca 10(8)/g of sample. Bacillus spp. were the first group to grow, followed by Streptococcus and Staphylococcus-Micrococcus spp. Growth which occurred at 37 degrees C did so at the expense of glucose, lactate accumulated and the pH of pie components decreased. Amylase activity detected in all pie components during storage was associated with the growth of Bacillus spp. and probably supplemented glucose already present in pies, by hydrolytic cleavage of potato, flour or binder starches. Spoilage caused by growth and activity of the bacteria isolated was not associated with visual signs of biodeterioration, nor production of 'off' odour usually associated with spoilage of meats. These results suggest that pre-cooked potato-topped pies held at inappropriate temperatures represent a potential public health risk.     

A note on the microbial spoilage of undercooked chub-packed luncheon meat

Contrary to expectations slight undercooking (68.5°C instead of 70°C for 90 min) dramatically increased the shelf-life of chub-packed luncheon meat stored at 25°C. The pH of undercooked chubs fell rapidly to below 5.0 as a result of the growth of enterococci. The accumulated acid prevented the growth of Bacillus spores and gave the luncheon meat a not unpleasant tangy flavour. Degradative changes associated with the spoilage of commercially cooked chub-packed luncheon meat did not occur, even after 42 d storage. Apparently, post-cooking fermentation by enterococci can effectively convert a perishable product into a 'shelf stable' one by lowering the pH below 5.0.     

Observations on the Microbiology of Cooked Chicken Carcasses

S ummary . The residual microbial flora and the flora developing during storage at 1–3° and at 16°, of chicken carcasses cooked in a circulating moist air oven operated at 85°, have been studied. All parts of the carcasses reached and maintained 85° for at least 50 min, and the residual flora consisted largely of spore forming bacteria. The predominant residual species were Bacillus subtilis and Clostridium bifermentans. Non-sporing bacteria were not detected after cooking nor after storage at 1–3° for up to 7 days. Storage at 16° for 3 days markedly increased the number of non-sporing organisms although off-odours typical of spoilage were not apparent until at least 10 days. Staphylococcus aureus and Salmonella spp. were not detected after cooking and storage and Cl. welchii was rarely isolated. It is concluded that poultry cooked by this method present a minimal risk of food-borne infection or intoxication by these organisms if contamination after cooking is avoided, the carcasses are cooled rapidly to c , 3° and stored at this temperature or frozen.     

Factors affecting the growth of Listeria monocytogenes on minimally processed fresh endive

The influence of various factors on the fate of Listeria monocytogenes on cut leaves of broad-leaved endive has been studied. Factors considered were temperature, characteristics of the leaves (age, quantity and quality of the epiphytic microflora) and characteristics of the L. monocytogenes inoculum (concentration, strain). The increases in numbers of L. monocytogenes were lower than those of the aerobic mesophilic microflora at 3°, 6°, 10° and 20°C. Doubling times of the populations of L. monocytogenes were in the same order of magnitude as those of aerobic bacteria at 10° and 20°C, but longer at 3° and 6°C. There were positive significant correlations between growth of L. monocytogenes and populations of aerobic bacteria, and between growth of L. monocytogenes and extent of spoilage on the leaves.
Of 225 bacteria isolated from the leaves, 84% were identified as fluorescent pseudomonads; there was no difference in the species isolated from leaves that showed a low growth of L. monocytogenes and leaves that showed a high growth of L. monocytogenes. Populations of L. monocytogenes increased faster during the first 2 and 4 d of storage at 10°C on leaves inoculated with 10–10³ cfu g^-1 than on leaves inoculated with about 10⁵ cfu g^-1, but the population reached after 7 d was lower. The behaviour of L. monocytogenes was similar among the three strains tested.     

Lactic acid bacteria associated with a heat-processed pork product and sources of variation affecting chemical indices of spoilage and sensory characteristics

Aims:  To evaluate the potential for developing a quality index for a Danish modified atmosphere packaged (MAP) heat-processed and naturally contaminated pork meat product stored at 5°C.
Methods and Results:  The composition of the predominating microflora and changes in contents of tyramine, arginine, organic acids and sensory characteristics were analysed. The microflora was predominated by Lactobacillus sakei , Leuconostoc carnosum and Carnobacterium divergens . The presence of each species varied between products and batches resulting in limited usefulness of the concentrations of these bacteria or their metabolites as indices of quality. Furthermore, the three species differed in their metabolic activities as shown by use of a model meat extract. However, when MAP storage of the processed pork product was followed by aerobic storage then acetic acid showed some potential as a chemical indicator of sensory quality.
Conclusion:  Variation in processing parameters and spoilage microbiota limited the usefulness of concentrations of micro-organisms and their metabolites as indices of spoilage for the studied processed MAP pork product.
Significance and Impact of the Study:  The present study contributes to an understanding of the difficulties experienced in developing quality indices to be used in the control of microbial spoilage of processed MAP meat products.     

The microbial flora of smoked pork loin and frankfurter sausage stored in different gas atmospheres at 4°C

The development of the microflora of smoked pork loin and frankfurter sausage was followed during storage in vacuum, N₂ and CO₂ atmospheres at 4°C. The total aerobic count on the smoked pork loin reached 10⁷ organisms/g after 37 d in vacuum, 43 d in N₂ and 49 d in CO₂. The corresponding value for the sausage was 77 d in vacuum, while the growth stopped at 6 times 10⁴ organisms/g after 98 d in N₂, and at 4 times 10² organisms/g after 48 d in CO².
The predominant organisms on the fresh products were Bacillus spp., coryneform bacteria, Flavobacterium spp. and Pseudomonas spp.
At the end of the storage time the microflora on both products in the three gas atmospheres, consisted mainly of Lactobacillus spp. and two large groups of organisms that could not be identified as any described genus. Some of the unidentified strains could be classified as a Lactobacillus sp. after subsequent subculturing on laboratory media.
The numbers of Lactobacillus spp. at the end of storage decreased in the order, CO₂ > N₂ > vacuum. Lactobacillus viridescens generally constituted a substantial part of the Lactobacillus flora (5–72%). On the sausages two large uniform groups of unidentifiable homofermentative Lactobacillus spp. were also found.     

Effects of gaseous environment and temperature on the storage behaviour of Listeria monocytogenes on chicken breast meat

Portions of skinless chicken breast meat (pH 5·8) were inoculated with a strain of Listeria monocytogenes and stored at 1, 6 or 15°C in (1) aerobic conditions; (2) 30% CO₂+ air; (3) 30% CO₂+ N₂; and (4) 100% CO₂. When samples were held at 1°C the organism failed to grow under any of the test conditions, despite marked differences between treatments in spoilage rate and ultimate microflora. At 6°C counts of L. monocytogenes increased ca 10-fold in aerobic conditions before spoilage of the meat, but only when the inoculum culture was incubated at 1°C rather than 37°C. In CO₂ atmospheres growth of L. monocytogenes was inhibited on meat held at 6°C, especially under 100% CO₂. By contrast, storage at 15°C led to spoilage of the meat within 2 d, in all gaseous environments, and listeria levels increased up to 100-fold. Differences in the behaviour of L. monocytogenes on poultry and red meats are discussed.     

Growth of Bacteria on Meat at Room Temperatures

The development of spoilage flora and the growth of individual psychrotrophs and pathogens on meat held at 20 or 30°C were studied. Under aerobic conditions psychrotrophic pseudomonads accounted for 60% of the spoilage flora at 20°C, but <20% at 30°C where they were displaced by species of Acinetobacter and Enterobacteriaceae which included both mesophilic and psychrotrophic strains. Mesophiles dominated the anaerobic spoilage flora at 30°C when clostridia were the major species, but at 20° the flora contained mesophiles and psychrotrophs in similar proportions and was dominated by Enterobacteriaceae. These results were largely predictable from the growth rate data for individual organisms.
Interactions between species occurred more frequently at 20°C than at 30°C. When pathogenic species were grown at 20 or 30°Cin competition with equal numbers of psychrotrophic spoilage organisms, no interactions were observed. When pathogens were grown in competition with high numbers of psychrotrophs, only Lactobacillus growing anaerobically inhibited Salmonella typhimurium and Escherichia coli , but other pathogens were inhibited to varying degrees depending on the competing species and the incubation conditions. In general, the degree of inhibition was greater at 20 than at 30°C and facultative organisms were more susceptible under anaerobic than aerobic conditions. It appears that the cumulative stresses of low pH, suboptimal temperatures and competition with large numbers of saprophytic organisms can inhibit many of the pathogens likely to be present on meat. The organisms least affected by the conditions on meat surfaces, Salmonella and Esch. coli , are likely to be the main hazards on meat of normal pH held at room temperatures.     

Evaluation of the extent and type of bacterial contamination at different stages of processing of cooked ham

In an attempt to determine the composition and origin of the spoilage flora of refrigerated vacuum-packed cooked ham, the changes in microbial numbers and types were followed along the processing line. Results revealed Lactobacillus sake and Leuconostoc mesenteroides ssp. mesenteroides as the major causative agents of spoilage of sliced ham stored at 4 °C and 12 °C, due to recontamination in the cutting room. On the contrary, the progressive deterioration of whole ham under the same storage conditions was associated with a non-identifiable group of leuconostoc-like bacteria. Except for lactic acid bacteria, no other organism grew in vacuum packs of either sliced or whole ham. Although atypical leuconostocs could not be detected among isolates recovered from freshly produced whole ham, they appeared to survive cooking and proliferate during storage. Neither these organisms however, nor Lact. sake and Leuc. mesenteroides were important in curing and tumbling as carnobacteria, mainly Carnobacterium divergens, and Brochothrix thermosphacta dominated at this stage. A progressive inversion of the ham microflora from mostly Gram-negative at the beginning of processing to highly Gram-positive prior to cooking was noted. Listeria monocytogenes cross-contaminated ham during tumbling. However, the pathogen was always absent from the vacuum-packed product provided that heating to a core temperature of 70 °C occurred and recontamination during slicing and packing was prevented. The percentage distribution of different species of lactic acid bacteria as well as the uncommon phenotypic characteristics of some strains were discussed.     

Detection and characterization of a bacteriocin produced by Lactococcus lactis subsp. cremoris R isolated from radish

Bacteria isolated from radish were identified as Lactococcus lactis subsp. cremoris R and their bacteriocin was designated lactococcin R. Lactococcin R was sensitive to some proteolytic enzymes (proteinase-K, pronase-E, proteases, pepsin, α-chymotrypsin) but was resistant to trypsin, papain, catalase, lysozyme and lipase, organic solvents, or heating at 90 °C for 15, 30 and 60 min, or 121 °C for 15 min. Lactococcin R remained active after storage at −20 and −70 °C for 3 months and after exposure to a pH of 2–9. The molecular weight of lactococcin R was about 2·5 kDa. Lactococcin R was active against many food-borne pathogenic and food spoilage bacteria such as Clostridium, Staphylococcus, Listeria, Bacillus, Micrococcus, Enterococcus, Lactobacillus, Leuconostoc, Streptococcus and Pediococcus spp., but was not active against any Gram-negative bacteria. Lactococcin R was produced during log phase and reached a maximum activity (1600 AU ml⁻¹) at early stationary phase. The highest lactococcin R production was obtained in MRS broth with 0·5% glucose, at 6·5–7·0 initial pH values, 30 °C temperature and 18–24-h incubation times. Lactococcin R adsorbed maximally to its heat-killed producing cells at pH 6–7 (95%). Crude lactococcin R at 1280 AU ml⁻¹ was bactericidal, reducing colony counts of Listeria monocytogenes by 99·98% in 3 h. Lactococcin R should be useful as a biopreservative to prevent growth of food-borne pathogenic and food spoilage bacteria in ready-to-eat, dairy, meat, poultry and other food products. Lactococcin R differs from nisin in having a lower molecular weight, 2·5 kDa vs 3·4 kDa, and in being sensitive to pepsin and α-chymotrypsin to which nisin is resistant.     

Light butter: natural microbial population and potential growth of Listeria monocytogenes and Yersinia enterocolitica

Yarrowia lipolytica, Bacillus polymyxa and Enterococcus faecium were the most frequent yeast and bacterial spoilage species associated with commercial light butter. Following inoculation and incubation at 4°C, strains of Y. enterocolitica and L. monocytogenes exhibited growth rates higher than those of the naturally occurring microflora. Listeria monocytogenes displayed a higher aptitude to proliferate in such food while the cell increment of Y. enterocolitica was limited.     

Classification of the spoilage flora of raw and pasteurized bovine milk, with special reference to Pseudomonas and Bacillus

Eighty-one bacterial strains isolated from refrigerated raw milk, 124 from pasteurized milk and cream stored at 5°C and 7°C, and 19 type and reference strains of Pseudomonas spp. and Bacillus spp. were characterized by numerical phenotypic analysis. Data were processed with simple matching ( S _SM) and Jaccard ( S _J) coefficients, and UPGMA clustering. Fourteen clusters of Gram-negative bacteria were formed at S _J= 79% ( S _SM= 90%). Raw milk was exclusively spoilt by Gram-negative bacteria, the majority of which were Pseudomonas fluorescens biovar I, Ps. fragi, Ps. lundensis and Ps. fluorescens biovar III. Minor groups in raw milk included Enterobacteriaceae spp. and Acinetobacter spp. Pasteurized milk was spoilt by essentially the same Gram-negative organisms in 65% (5°C) and 50% (7°C) of the cases. The phenotypic characteristics of Gram-negative bacteria are given. Bacillus polymyxa (both temperatures) and B. cereus (only at 7°C) were responsible for 77% of samples spoiled by the Gram-positive organisms. Minor milk spoilage groups included other Bacillus spp. and lactic acid bacteria. All Bacillus spp. grew fermentatively in milk, and most strains denitrified. It is suggested that: (i) industrial recontamination tests of pasteurized milk are directed against Pseudomonas; (ii) milk is stored at 5°C or lower to avoid growth of B. cereus ; and (iii) the significance of gas-producing and nitrate/nitrite-reducing Bacillus strains is recognized in cheese production.     

Chemical and Microbiological Changes during Storage of Vacuum Packed Sliced Bacon

Summary: The micro-ecology of block cured, sliced, vacuum packed bacon has been studied during storage at 20 and 30°; high salt (8–12% NaCl, based on the aqueous phase) and low salt (5–7% NaCl) bacon were used. The dominant flora of all samples during the first 9 days' storage comprised catalase positive cocci. They persisted in the high salt bacon but, under lower salt conditions, group D streptococci and motile lactic acid bacteria became dominant.
Of the chemical changes studied, proteolysis, lipolysis and reduction of nitrate and nitrite were due largely to coagulase negative subgroup II staphylococci. Micrococci which predominated at 20° were capable of reducing nitrate to nitrite but of only slightly increasing free amino or fatty acids.
Inoculation of low count bacon with subgroup II staphylococci confirmed that this group was responsible for putrefaction in low salt bacon stored at temperatures above 20°. Similarly micrococci which tend to delay spoilage did not contribute much to the off odours and it was thought that the heterofermentative catalase negative organisms could contribute to typical sour spoilage.