Your search keyword '"R.G. Bell"' showing total 4 results

1. Heat injury and recovery of Streptococcus faecium associated with the souring of chub-packed luncheon meat

Author

Karen M. De Lacy and R.G. Bell

Subjects

Hot Temperature, Meat, Sodium, Food spoilage, Pasteurization, chemistry.chemical_element, Souring, Bacterial growth, Biology, Sodium Chloride, medicine.disease_cause, Applied Microbiology and Biotechnology, Microbiology, law.invention, chemistry.chemical_compound, law, medicine, Food microbiology, Food science, Sodium nitrite, Sodium Nitrite, Streptococcus, Hydrogen-Ion Concentration, Meat Products, chemistry, Food Microbiology

Abstract

The presence of NaCl in the heating medium provided some protection from lethal heat damage for cells of a Streptococcus faecium strain isolated from luncheon meat whereas the presence of NaNO2 either alone or in addition to NaCl, had no significant effect on cell survival. Subsequent recovery and growth of heat-damaged cells was retarded by the presence of NaCl. When NaNO2 was present in addition to NaCl the inhibitory effect of the latter was reduced. These principal components of the luncheon-meat-cure are apparently opposed in their activities on post-heating recovery and growth of Strep. faecium. Product stability, i.e. duration of the lag before growth occurs, is directly related to the severity of the heat treatment and to the concentration of NaCl in the product. Therefore the resistance of pasteurized chub-packed luncheon meat to streptococcal spoilage during storage at temperatures conducive to microbial growth results from a prolonged heat-induced salt-maintained pre-growth adjustment phase rather than to any inherent inhibitory property of the luncheon meat to the growth of non-heat-damaged Strep. faecium cells.

Published

1984

2. Microbial spoilage of luncheon meat prepared in an impermeable plastic casing

Author

R.G. Bell and C.O. Gill

Subjects

Meat, Bacteria, Starch, Food Handling, Food spoilage, Temperature, Bacillus, Micrococcus, Biology, biology.organism_classification, Applied Microbiology and Biotechnology, Microbiology, Lactic acid, chemistry.chemical_compound, Hydrolysis, chemistry, biology.protein, Food Microbiology, Food science, Amylase, Nitrite, Plastics

Abstract

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.

Published

1982

3. Nitrite loss and spoilage microflora development in chub-packed luncheon meat

Author

R.G. Bell and Karen M. De Lacy

Subjects

Meat, Food Handling, Food spoilage, Pasteurization, Bacillus, chemistry.chemical_element, Biology, Bacterial growth, Applied Microbiology and Biotechnology, Microbiology, Oxygen, law.invention, chemistry.chemical_compound, Denitrifying bacteria, law, Animals, Food science, Nitrite, Nitrites, Temperature, Streptococcus, biology.organism_classification, Meat Products, chemistry, Food Microbiology, Food Preservatives, Anaerobic exercise

Abstract

Residual nitrite was lost from chub-packed luncheon meat during storage through both chemical breakdown and microbial consumption. The relative importance of these mechanisms in this pasteurized product was determined by the speed of development of the spoilage microflora, which is influenced by storage conditions. The nitrite half-life due to chemical loss was 13 d at 25 degrees C and 36 d at 10 degrees C. When microbial growth occurred these half-lives were reduced to 2.6 d and 21 d, respectively. Qualitative differences in the microflora that developed at these two temperatures (denitrifying Bacillus spp. at 25 degrees C and non-denitrifying Streptococcus spp. at 10 degrees C) account for the large temperature effect. Growth of Streptococcus spp. increased the rate of chemical nitrite loss in chubs by reducing the pH value. Nitrite did not inhibit the aerobic growth of either Bacillus or Streptococcus species associated with spoilage but did inhibit the anaerobic growth of Bacillus spp. This bacteriostatic effect of residual nitrite in anaerobic conditions will decrease during storage as nitrite level falls and oxygen penetrates the chub pack. Nitrite-mediated bacteriostasis does not obviate the need for refrigerated storage but does afford a real, if ephemeral, safeguard against spoilage occurring during short periods of temperature abuse.

Published

1983

4. Influence of NaCl, NaNO2 and oxygen on the germination and growth of Bacillus licheniformis, a spoilage organism of chub-packed luncheon meat

Author

R.G. Bell and Karen M. De Lacy

Subjects

Hot Temperature, Meat, Food spoilage, chemistry.chemical_element, Bacillus, Biology, Sodium Chloride, Applied Microbiology and Biotechnology, Microbiology, Oxygen, chemistry.chemical_compound, Food Preservation, Botany, Spore germination, Food science, Bacillus licheniformis, Sodium nitrite, Nitrites, Spores, Bacterial, Sodium Nitrite, fungi, Hydrogen-Ion Concentration, biology.organism_classification, Spore, chemistry, Germination, Food Microbiology, Anaerobic exercise

Abstract

The thermal resistance of Bacillus licheniformis spores was increased from a D70-value of 590 min to one of 900 min by the addition of 4% NaCl to the heating medium [tryptone-yeast extract-glucose (TYG) broth, pH 6.8], but was decreased to 470 min in TYG broth acidified to pH 4.4. Sodium nitrite (0.02%) enhanced spore destruction at 80 degrees C but not at 70 degrees C; addition of 4% NaCl eliminated this effect. Less than half the number of spores surviving heat comparable to commercial cooking were heat-damaged to the extent of being unable to grow aerobically in the presence of 4% NaCl. No growth occurred during anaerobic incubation even when the media contained no added NaCl. Oxygen was not required to trigger spore germination, but trace amounts were needed for the successful outgrowth of germinated spores. Spore germination was accelerated and enhanced by the presence of at least 2% NaCl. Therefore under anaerobic conditions NaCl promotes microbiological stability because the germinated spores cannot develop further and become moribund. It is concluded that the plastic casing of luncheon-meat chubs is not sufficiently oxygen-impermeable to allow the product a long shelf-life other than at chill temperatures unless the chubs are stored in an oxygen-free atmosphere.

Published

1984