Role of Curing Agents in the Preservation of Shelf-stable Canned Meat Products

Experiments were conducted to gain a better understanding of the mechanism by which sodium chloride, sodium nitrate, and sodium nitrite supplement the action of heat in preserving canned cured meat products. Heated spores of putrefactive anaerobe 3679h were less tolerant of all three curing agents in the outgrowth medium than were unheated spores. When the curing agents were added to the heating menstruum, but not to the outgrowth medium, sodium chloride and sodium nitrate tended to protect the spores against heat injury, but sodium nitrite did not. When the spores were both heated and cultured in the presence of the curing agents: (i) nitrate and salt increased the apparent heat resistance at low concentrations (0.5 to 1%) but decreased it at concentrations of 2 to 4%; (ii) nitrite was markedly inhibitory, especially at pH 6.0. At the normal pH of canned luncheon meats (approximately 6.0), nitrite appears to be the chief preservative agent against spoilage by putrefactive anaerobes.     

Inhibition of Clostridium perfringens by heated combinations of nitrite, sulfur, and ferrous or ferric ions.

Heating mixtures of sodium nitrite, cysteine, and either ferrous sulfate or ferric chloride at 121 C for 20 min at pH 6.5 or 6.3 produced a potent inhibitor of Clostridium perfringens vegetative cells and spores when added to previously heat-sterilized fluid thioglycolate medium. When the mixtures containing FeSO4 at pH 5.2 or FeCl3 at pH 2.7 were heated, the inhibitory effect was not produced. These responses seem to eliminate the possibility that cysteine nitrosothiol is the agent responsible for the heated-nitrite inhibition known as the Perigo effect. The variable pH responses also cast doubt upon the role of the black Roussin salt as the agent of the Perigo effect.     

Inhibition of Clostridium perfringens by heated combinations of nitrite, sulfur, and ferrous or ferric ions.

Heating mixtures of sodium nitrite, cysteine, and either ferrous sulfate or ferric chloride at 121 C for 20 min at pH 6.5 or 6.3 produced a potent inhibitor of Clostridium perfringens vegetative cells and spores when added to previously heat-sterilized fluid thioglycolate medium. When the mixtures containing FeSO4 at pH 5.2 or FeCl3 at pH 2.7 were heated, the inhibitory effect was not produced. These responses seem to eliminate the possibility that cysteine nitrosothiol is the agent responsible for the heated-nitrite inhibition known as the Perigo effect. The variable pH responses also cast doubt upon the role of the black Roussin salt as the agent of the Perigo effect.     

Relationship Between the Increased Sensitivity of Heat Injured Clostridium perfringens Spores to Surface Active Antibiotics and to Sodium Chloride and Sodium Nitrite

Spores of Clostridium perfringens NCTC 8798 became increasingly sensitive to inhibition by sodium chloride, sodium nitrite and a mixture of polymyxin and neomycin when heated at 70–100°C. That the increased sensitivity to each agent was caused by the same cellular damage was suggested by: (1) the temperature coefficients for induction of cellular damage leading to increased sensitivity to all three agents were the same; (2) in the absence of the agents, the spores regained resistance to all three at about the same time and in each case in the presence of cell wall-, protein- and DNA-synthesis inhibitors; (3) combinations of the agents were generally no more inhibitory to the heated spores than were the individual agents.     

Formation of Antibacterial Factor by Heating System Containing Nitrite and Tryptone

A Perigo-type antibacterial factor (PTF) was produced when tryptone (a pancreatic digest of casein) medium was heated with nitrite at 121°C for 20 min. This PTF was inhibitory against Staphylococcus aureus, Bacillus subtilis and Clostridium botulinum, but was not against Escherichia coli and Salmonella typhimurium. The inhibitory activity varied with the concentration of nitrite (5 ~ 100 ppm) and tryptone (1, 2, 4%), and with pH (4, 5, 6, 7). The maximum inhibitory activity was observed when the medium containing 4% tryptone and 0.2% thioglycolate was heated with more than 50 ppm nitrite at pH 6. The tryptone was separated into three fractions by gel filtration and PTF was produced in every fraction, although the inhibitory activity was different in each. Our PTF might be unstable towards oxygen because its activity was lost completely by shaking for more than 16 hr.     

Nisin: a possible alternative or adjunct to nitrite in the preservation of meats.

Nisin at 75 ppm (75 microgram/g) was superior to 150 ppm of nitrite in inhibiting outgrowth of Clostridium sporogenes PA3679 spores in meat slurries, which had been heated to simulate the process used for cooked ham. The inhibitory activity of nisin decreased as the spore load or pH of the slurries increased. Unlike nitrite, inhibition by nisin was unaffected by high levels of iron either as a constituent of meats or when added as an iron salt. In slurries treated with 75 ppm of nisin, refrigerated storage for 56 days resulted in depletion of nisin to a level low enough to allow outgrowth within 3 to 10 days if the slurries were subsequently abused at 35 degrees C. In contrast, a combination of 40 ppm of nitrite and either 75 or 100 ppm of nisin almost completely inhibited outgrowth in these slurries. The nisin-nitrite combination appeared to have a synergistic effect, and the low concentration of nitrite was sufficient to preserve the color in meats similar to that of products cured with 150 ppm of nitrite.     

Influence of acidification and type of acidulant of the recovery medium on Bacillus stearothermophilus spore counts

Unheated and heated (1 min at 121°C) Bacillus stearothermophilus spores were grown in non-acidified (pH 7) and acidified recovery medium at different pH levels (6.7, 6.5, 6.2 and 5.9) using citric acid or glucono-δ-lactone (GDL) as acidulants. It was observed that the lower the pH, the lower the proportion of micro-organisms which recovered. The level of recovery was not the same for both acidulants, meaning that at the same pH level citric acid showed a greater inhibitory effect that glucono-δ-lactone. Heat treatment sensitized spores to pH effect. A linear relationship of the behaviour of spores with each acidulant is proposed.     

Antibacterial Effect of Cysteine-Nitrosothiol and Possible Percursors Thereof

The postulated intermediate of nitrite-myoglobin reaction, cysteine-nitrosothiol, was prepared and its antibacterial effect was tested on Salmonella strains, Streptococcus faecium, and spores and vegetative cells of Clostridium sporogenes. Cysteine-nitrosothiol showed a higher inhibitory effect than nitrite. Preliminary results on the effect of simultaneous use of nitrite and cysteine on Clostridium sporogenes spores were also presented.     

Mechanism of the Heat Sensitization of Bacillus subtilis Spores by Ethidium Bromide

Pretreatment with ethidium bromide (5 μg/ml) followed by a water wash had no effect on unheated Bacillus subtilis spores, but the viability of these spores after heating was much lower than that of similarly heated spores exposed to water alone. The fate of water- or ethidium bromide-treated spores, unheated or heated, was followed by allowing them to germinate and outgrow in a minimal or a complex liquid medium. Spores exposed to ethidium bromide and then heated (85°C, 10 min) exhibited a developmental block during germination and outgrowth. Many of them were blocked at the stage when the bacterium emerged from the germinated spore. When 0.35 μg of ethidium bromide per ml was added to heated spores in the germination-growth medium, the outgrowth of heated spores was inhibited to the same extent as were pretreated spores. Ethidium bromide acted in the first hour of germination of heated spores since addition after this time was ineffective in inhibiting recovery events. Repair of heat-damaged spore DNA was detected during the first 2 h of germination. The addition of ethidium bromide (final concentration, 0.35 μg/ml) inhibited DNA repair during early outgrowth. Increased sensitivity of spores to heat after pretreatment with sublethal concentrations of ethidium bromide was due to the inhibition of the repair of heat-damaged DNA.     

Factors affecting growth from heat-treated spores of non-proteolytic Clostridium botulinum

Heat treatment of spores of non-proteolytic Clostridium botulinum at 85°C for 120 min followed by enumeration of survivors on a medium containing lysozyme resulted in a 4.1 and 4.8 decimal reduction in numbers of spores of strains 17B (type B) and Beluga (type E), respectively. Only a small proportion of heated spores formed colonies on medium containing lysozyme; this proportion could be increased by treatments designed to increase the permeability of heated spores. The results indicate that the germination system in spores of non-proteolytic Cl. botulinum was destroyed by heating, that lysozyme could replace this germination system, and that treatments that increased the permeability of the spore coat could increase the proportion of heated spores that germinated on medium containing lysozyme. These results are important in relation to the assessment of heat-treatments required to reduce the risk of survival and growth of non-proteolytic Clostridium botulinum in processed (pasteurized) refrigerated foods for extended storage.     

Growth from Spores of Clostridium perfringens in the Presence of Sodium Nitrite

The method by which sodium nitrite may act to prevent germination or outgrowth, or both, of heat-injured spores in canned cured meats was investigated by using Clostridium perfringens spores. Four possible mechanisms were tested: (i) prevention of germination of the heat-injured spores, (ii) prior combination with a component in a complex medium to prevent germination of heat-injured spores, (iii) inhibition of outgrowth of heat-injured spores, and (iv) induction of germination (which would render the spore susceptible to thermal inactivation). Only the third mechanism was effective with the entire spore population when levels of sodium nitrite commercially acceptable in canned cured meats were used. Concentrations of 0.02 and 0.01% prevented outgrowth of heat-sensitive and heat-resistant spores, respectively. Nitrite-induced germination occurred with higher sodium nitrite concentrations.     

Nitrite-induced germination of putefactive anaerobe 3679h spores

Sodium nitrite alone has been shown to stimulate germination of PA 3679h spores. The process was accelerated by using increased concentrations of sodium nitrite, a low pH, and a high temperature of incubation. At low concentrations of nitrite (0.01 to 0.2%), the delay of 36 to 48 hr occurred before germination commenced at 37 C. However, with 3.45% nitrite at 45 C and pH 6.0, most of the spores germinated within 1 hr. At pH 7.0, the germination rate decreased markedly, and at pH 8.0 it was nil. The greatest acceleration in germination rate occurred near 60 C. Hydroxylamine was completely inhibitory to nitrite-induced germination. Sodium nitrite, in turn, inhibited germination by l-alanine, the degree of inhibition being influenced by nitrite concentration and pH.     

Increased susceptibility of injured spores of Bacillus subtilis to cationic and other stressing agents

Sublethally heated spores of Bacillus subtilis NCTC 8236 were susceptible to posttreatment concentrations in agar of polymyxin B sulphate, sodium hydroxide, cetylpyridinium chloride and sodium lauryl sulphate that did not prevent colony formation to untreated spores. The non-ionic surfactants polysorbates 20 and 80 were not inhibitory when used at high concentrations against both heated and unheated spores. The method has been developed for detecting sublethal injury in biocide-exposed spores, since iodine-treated spores became highly susceptible to polymyxin contained in recovery agar.     

A rapid method for the determination of bacterial fatty acid composition

Heat treatment of spores of non-proteolytic strains of Clostridium botulinum at 75–90°C, and enumeration of survivors on a nutrient medium containing lysozyme gave biphasic survival curves. A majority of spores were inactivated rapidly by heating, and the apparent heat-resistance of these spores was similar to that observed by enumeration on medium without lysozyme. A minority of spores showed much greater heat-resistance, due to the fact that the spore coat was permeable to lysozyme, which diffused into the spore from the medium and replaced the heat-inactivated germination system. The proportion of heated spores permeable to lysozyme was between 0.2 and 1.4% for spores of strains 17B (type B) and Beluga (type E), but was about 20% for spores of strain Foster B96 (type E). After treatment of heated spores with alkaline thioglycolate, all were permeable to lysozyme. D-values for heated spores that were permeable to lysozyme (naturally and after treatment with thioglycolate) were: for strain 17B, D₈₅°C, 100 min; D₉₀°C, 18.7 min; D₉₅°C, 4.4 min; for strain Beluga, D₈₅°C, 46 min; D₉₀°C, 11.8 min; D₉₅°C, 2.8 min. The z-values for these spores of strains 17B and Beluga were 7.6°C and 8.3°C.     

Nitrite-induced Germination of Putrefactive Anaerobe 3679h Spores

Sodium nitrite alone has been shown to stimulate germination of PA 3679h spores. The process was accelerated by using increased concentrations of sodium nitrite, a low pH, and a high temperature of incubation. At low concentrations of nitrite (0.01 to 0.2%), the delay of 36 to 48 hr occurred before germination commenced at 37 C. However, with 3.45% nitrite at 45 C and pH 6.0, most of the spores germinated within 1 hr. At pH 7.0, the germination rate decreased markedly, and at pH 8.0 it was nil. The greatest acceleration in germination rate occurred near 60 C. Hydroxylamine was completely inhibitory to nitrite-induced germination. Sodium nitrite, in turn, inhibited germination by l-alanine, the degree of inhibition being influenced by nitrite concentration and pH.     

Effect of Lysozyme on the Recovery of Heated Clostridium botulinum Spores

Lysozyme in the recovery medium increased the recovery of heated spores, thereby raising the measured heat resistance of type E Clostridium botulinum spores about 1,800-fold and type A spores up to 3-fold.     

Mechanism of chemical manipulation of the heat resistance of Clostridium perfringens spores

The mechanism(s) of chemical manipulation of the heat resistance of Clostridium perfringens type A spores was studied. Spores were converted to various ionic forms by base-exchange technique and these spores were heated at 95°C. Of the four ionic forms, i.e. Ca²⁺, Na⁺, H⁺ and native, only hydrogen spores appeared to have been rapidly inactivated at this temperature, when survivors were enumerated on the ordinary plating medium. However, the recovery of the survivors was improved when the plating medium was supplemented with lysozyme, and more dramatically when the heated spores were pretreated with alkali followed by plating in the medium containing lysozyme. In contrast to crucial damage to germination, in particular to spore lytic enzyme, no appreciable amount of DPA was released from the heat-damaged H-spores. These results suggest that a germination system is involved in the thermal inactivation of the ionic forms of spores, and that exchangeable cation load plays a role in protection from thermal damage of the germination system within the spore. An enhancement of thermal stability of spore lytic enzyme in the presence of a high concentration of NaCl was consistent with the hypothesis.     

Sporulation, Heat Resistance, and Biological Properties of Clostridium perfringens

A sporulation medium for 134 Clostridium perfringens strains, including types A, B, C, D, E, and F, was devised according to Grelet's observation that sporulation occurred when cultural environment became limited in any nutritional requirement indispensable for the growth of the organism. Sporulation took place most prominently when 10% cooked-meat broth (pH 7.2) containing 3% Proteose Peptone and 1% glucose was used for the preculture and 2% Poli Peptone medium (pH 7.8) was used for the subculture medium. Sometimes, terminal spores could be observed. A correlation between sporulation and heat resistance was examined by use of C. perfringens strains isolated from samples heated at different temperatures. Almost all strains isolated from unheated samples and from those heated at lower temperatures gave rise to spores in our sporulation medium, but the spores were weakly heat-resistant, whereas strains isolated from samples heated at 100 C for 60 min were highly heat-resistant but sporulated poorly. A majority of these heat-resistant strains were non-gelatinolytic and definitely salicin-fermenting.     

Relationship between Heat Activation and Percentage Colony Formation for Bacillus stearothermophilus Spores: Effects of Storage and pH of the Recovery Medium

Colony counts of unheated spores were higher in a medium at pH 5·9 than in media of higher pH. The pattern was reversed as the spores were heated. Slide germination studies showed that about 8% or less of unheated spores germinated in slide culture. Optimal heat activation resulted in about 50% germination. The colony counts of heat activated spores dropped significantly upon storage for 9 months, but those of unheated spores did not.     

Sporulation of Clostridium perfringens (welchii) in Four Laboratory Media

S ummary . Sporulation of 7 strains of Clostridium perfringens ( welchii ) was investigated in 4 laboratory media. A method to induce rapid and simultaneous sporulation was attempted which involved obtaining a purely vegetative culture to inoculate the test media. Heat resistance of spores produced in the individual media by each of 4 selected strains was investigated. The clean spores for the heating tests were obtained by a special procedure which included chilling to 6° for a minimum of 1 week immediately following the usual incubation period, then centrifuging, resuspending to volume in 0.85% NaCl solution and pasteurizing at 75° for 20 min before subjecting to the heating tests. Morphology of each strain was studied using stained microscopic preparations from the 24 h sporulating cultures.
In the Ellner medium spore counts approaching 10⁷/ml were recorded and this medium appeared to be the most efficient when judged in terms of numbers of spores produced. In other media the counts were in the range 10⁴-10⁵ spores/ml. Cooked meat medium yielded slightly higher spore counts than did either SEC broth or modified Wagenaar & Dack medium, the latter contained in a dialysis sac apparatus. A period of chilling to 6° for a minimum of 1 week following incubation enhanced maturation in all cultures except those grown in SEC broth for 24 h or 15 days and those grown 15 days in the modified Wagenaar & Dack medium.
Considerable heat resistance, expressed as percentage spore survival, was recorded for spores of 4 strains when heated at 80°, and heat resistance generally increased with lengthening of incubation time for the culture. Survival of spores heated at 100° for 10 min was usually less than 0.01% but spores in SEC broth after 15 days showed a somewhat greater heat resistance than the others. In no instance did total destruction of spores occur at 100°.