Thermal inactivation of Listeria monocytogenes and Salmonella was evaluated on peas, spinach, broccoli, potatoes, and carrots that were treated with hot water and steam. One gram-positive bacterium, L. monocytogenes, and one gram-negative bacterium, Salmonella, were selected as pertinent human pathogens for evaluation. Samples were inoculated with a composite of five strains each of L. monocytogenes and Salmonella to achieve approximately 10 to 10 CFU/g. Inoculated samples were treated with hot water at 85 and 87.8°C and with steam at 85 and 96.7°C for up to 3.5 min. A greater than 5-log reduction of L. monocytogenes and Salmonella was achieved on all products within 0.5 min by hot water blanching at 85 and 87.8°C. Steam blanching at 85°C reduced Salmonella populations by greater than 5 log on spinach and peas within 2 min and on carrots and broccoli within 3.5 min. Populations of Salmonella were reduced by more than 5 log within 1 min on carrot, spinach, and broccoli and within 2 min on peas by steam blanching at 96.7°C. Steam blanching at 85°C reduced L. monocytogenes populations by more than 5 log on carrots and spinach within 2 min and on broccoli and peas within 3.5 min. L. monocytogenes populations were reduced more than 5 log within 1 min on carrot, spinach, peas and broccoli by steam blanching at 96.7°C. Longer treatment times and higher temperatures were required for steam-blanched samples than for samples blanched with hot water. Results suggest that hot water and steam blanching practices commonly used by the frozen vegetable industry will achieve the desired 5-log lethality of L. monocytogenes and Salmonella and will enhance microbiological safety prior to freezing.
Escherichia coli O157:H7 and non-O157:H7 survival due to induced acid tolerance or shock responses when exposed to lactic acid over time was studied. Induced acid tolerance or shock responses could allow pathogens, like E. coli O157:H7, to survive acidic conditions in foods during storage. Escherichia coli O157:H7 isolates 932 and E009 and a non-Ol57:H7 strain, 23716, were grown to stationary phase at 32°C and exposed to one of two treatments: acid shock or acid adaption. Acid-shocked cells were exposed to lactic acid at pH 3.5 or 4.0. Acid-adapted cells were exposed to pH 5.5 for an adaptation period and then exposed to an acid challenge of pH 3.5 or 4.0. Samples were incubated at either 25 or 32°C and survival of the isolates at 0, 3, 24, 48, 72, and 168 h (7 days), 336 h (14 days), and 504 h (21 days) was determined. All three isolates survived longer with larger populations at pH 4.0 and 25°C compared to the other treatments. In cases where a difference was observed in the two responses, acid-shocked cells had a higher survival rate (typically less than 2 logs) than acid-adapted cells in most cases. Isolate differences were observed at the two pH and temperature levels. Isolate 932 was the most resistant to the acidic conditions during the incubation period, E009 intermediate, and strain 23716 was the most sensitive.
The survival of Escherichia coli O157:H7 and non-O157:H7 due to an enhanced acid tolerance response (ATR), and enhanced acid shock response (ASR), or the stationary phase protective system when exposed to lactic acid and the resulting cross protection against increased concentration of sodium chloride and sodium lactate was studied. Escherichia coli O157:H7 isolates (1932 and 009) and a non-O157:H7 strain (ATCC 23716) were grown to stationary phase at 32 degrees C and O157:H7 to one of two treatments in an attempt to either acid shock or acid adapt the survivors. Acid shocked cells were exposed to lactic acid at pH 4.0. Acid-adapted cells were first exposed to a pH of 5.5 and then an acid challenge of pH 4.0. Sodium lactate (10%, 20%, or 30%) or sodium chloride (5%, 10%, or 15%) were added to a minimal glucose medium after the acidification treatment. When acid shocked and acid adapted isolate 932 and strain ATCC 23716 tolerated the elevated levels of sodium lactate, and the strain ATCC 23716 tolerated the elevated levels of sodium chloride. Acid adaption allowed isolate 932 to tolerate higher levels of sodium chloride; however, the acid shocking did not provide the same protection. Neither of the acid treatment provided increased tolerance to sodium chloride for isolate E009. Evidence of cross protection against acid and sodium chloride or acid and sodium lactate in E. coli O157:H7 could point to a need for further evaluation of whether these combinations of preservation means are sufficient to control this pathogen.
Rainbow trout (Oncorhynchus mykiss) were inoculated with 3 to 4 1og10 spores per g of fish of a mixed pool of four strains of Clostridium botulinum type E (Beluga, Minnesota, G21-5, and 070). The trout were vacuum-skin packaged with either oxygen-barrier or oxygen-permeable films. Trout packaged with oxygen-permeable film were stored at 4°C for 21 days, while trout packaged with oxygen-barrier film were stored either at 4°C for 21 days or at 10°C for 15 days. Storage at 10°C was used to simulate commercial temperature abuse. Clostridium botulinum outgrowth was determined by a most probable-number (MPN) method using (tryptone peptone yeast extract glucose trypsin) anaerobic broth. Toxin production was evaluated using a mouse bioassay. Psychrotrophic and anaerobic populations increased with time regardless of packaging type. After 6 days at l0°C, botulinum toxin was detected in the packaged trout; however, the fish was noticeably spoiled before that time. No botulinum toxin was detected in trout packaged with either barrier or permeable films and stored at 4°C for 21 days, although the product was considered spoiled by day 12.
The aim of this investigation was to determine if a risk of Clostridium botulinum growth and toxin production existed in four different packaged crabmeat products. Freshly picked blue crab meat was inoculated with 10(3) to 10(4) spores per g of a mixed pool of four strains of C. botulinum type E (Beluga, Minnesota, G21-5, and 070). The lump crabmeat was packaged in four different packaging containers: (i) 12-oz copolymer polyethylene cups currently used by most crab processors; (ii) 12-oz copolymer polyethylene cups with heat-shrink, tamper-evident low-density polypropylene seals; (iii) 8-oz copolymer polyethylene cups with easy-open aluminum ends: and (iv) 8-oz copolymer polypropylene cups with integral tamper-evident pull-tabs. The packages were stored at either 4 degrees C for 21 days or 10 degrees C for 15 days. Storage at 10 degrees C was used to simulate temperature abuse. The mouse bioassay was used to detect the presence of C. botulinum toxin. Psychotrophic and anaerobic populations were enumerated and were found to increase with time regardless of packaging type. No botulinum toxin was detected in any of the four packaging types stored at 4 degrees C or 10 degrees C throughout the entire storage period.
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