Category Archives: Microbiology

Research – Control measures for Shiga toxin-producing Escherichia coli (STEC) associated with meat and dairy products

Posted on October 28, 2022 by | Leave a comment

FAO

Executive summary
Shiga toxin-producing Escherichia coli (STEC) are estimated to cause more than 1.2 million illnesses and 128 deaths globally each year. The previous work of FAO and WHO identified beef and other types of meats, dairy products and produce as significant risk factors for STEC infection. As such, at its 42nd Session, the Codex Alimentarius Commission (CAC) endorsed the Codex Committee on Food Hygiene’s (CCFH) recommendation for the development of guidelines for the control of STEC in beef, raw milk and cheese produced from raw milk, leafy greens and sprouts.

To facilitate this work, the CCFH requested that FAO and WHO Joint Expert Meeting on Microbiological Risk Assessment (JEMRA) provide scientific advice on the effectiveness and utility of control measures against STEC during primary production, processing and post-processing of raw meat, raw milk and raw milk cheeses.

During the meeting, the expert committee reviewed interventions for the control of STEC in cattle, raw beef and raw milk and raw milk cheese manufactured from cows’ milk, and also evaluated available evidence for other small ruminants (goat, sheep), swine and other animals (reindeer, yak, camelids, bison, buffalo and swine). The expert committee was tasked with scoring the degree of support for the effectiveness of interventions for the specific control of STEC as high, medium or low based on the evidence available within the scientific literature.

In meat production and processing systems, many approaches to support control of STEC are based on good agricultural practices (GAP) and/or good hygiene practice (GHP) that aim to generally reduce the spread of pathogens and are not specifically focused on STEC. On-farm, these include managing the hygienic conditions of housing, bedding and drinking water hygiene, appropriate animal density and biosecurity measures, effective sanitation of facilities and proper disposal of manure.

On-farm, several dietary and herd management strategies with varying levels of impact on STEC populations in beef and dairy animals have been explored. Evidence to support cattle demography

(Section 2.1.3), animal density

(Section 2.2.2), biosecurity

(Section 2.2.1), and environmental hygiene

(Section 2.2.3) were rated as having a medium or medium to high degree of support with regards to their ability to impact STEC. Interventions including feeding of forage versus concentrate rations, specific grain types

(Section 2.3.3), and the inclusion of citrus products and essential oils in feed

(Section 4.2.5) were supported at low to medium or medium degree of support, yet probiotics may be useful with administered to cattle, goats and sheep through feed

(Sections 2.3.4.1 and 6.1.1). Some vaccines have been shown to reduce faecal excretion of STEC O157:H7

(Section 2.4.1), but their efficacy is variable depending on the vaccine and the number of doses administered.
Long distance transport and the stress of interim unloading/loading have been shown to increase faecal excretion of STEC that can lead to cross-contamination between animals

(Section 2.6). Transport distances should be minimized in accordance with best practices for animal welfare, and the evidence related specifically to the control of STEC was supported at a low degree. A summary of primary production control
measures for STEC in cattle and their degree of support rating (high, medium, low), based on scientific evidence, is available in Annex 1.
Avoiding contamination of the carcass through contact with hides, gut contents or faeces during slaughter is an accepted management practice during meat processing, but evidence supporting the effectiveness and reliability of these
measures for the control of STEC was limited. Processing measures where evidence supported a high or medium to high rating for efficacy in STEC reduction included steam vacuuming of visible faecal contamination on carcasses (Section 3.3.4.3),
and the use of a hot potable water carcass wash, steam pasteurization followed by 24 h air chilling and combinations of these

(Section 3.4). The use of knife trimming to remove carcass tissue contaminated with faecal material is common and is supported by a medium confidence level in the evidence

(Section 3.3.4.2). Despite the commercial use of pre-chill carcass decontamination treatments using organic acids and other chemical agents, the confidence in the evidence was low in cattle and other small ruminants due to high variability in results

(Section 3.4.3). A summary of processing control measures for STEC in beef and their degree of support (high, medium, low), based on scientific evidence, is available in Annex 2.
The efficacy of available control measures for reducing or eliminating STEC on primal cuts, trim, cheek meats, and ground beef was widely varied. Yet, the use chemical antimicrobial dips

(Section 4.2) for primals and trims were supported at a low to medium level of confidence, and high-pressure processing (HPP)

(Section 4.1.6), gamma irradiation and electron beam sterilization (eBeam)

(Section 4.1.7) produced significant reductions of STEC in ground beef and in retail packs. A summary of post-processing control measures, and combinations of these, for STEC in beef and their degree of support (high, medium, low), based on scientific
evidence, is available in Annex 3.

Pork products and meat from wild game have occasionally been confirmed as vehicles of STEC transmission, but there are no interventions or practices during the processing of these animals that are specific for STEC. Meat from these species could be treated post-harvest in a similar fashion as beef to reduce STEC, but reports of the efficacy of these interventions are not available.
Contamination of milk with pathogens, including STEC, mainly occurs during milking or via milking equipment, milking personnel, and from the farm environment. Thus, factors affecting the carriage of STEC in live animals and those practices surrounding milking hygiene can reduce, but not assure the absence of contamination of raw milk.

The efficacy of the interventions against STEC during the production of raw milk and raw milk cheeses varied greatly depending on the animal origin of the raw milk, manufacturing practices, the scale of production, and the microbial load. Temperature control and hygiene during milking, storage and transportation can significantly affect the microbiological safety of raw milk prior to processing, packaging and sale of milk intended for drinking or for manufacturing of raw milk cheeses. Although these interventions can mitigate the growth of E. coli and other indicator organisms, the degree of support in the evidence for these interventions and the control of STEC ranged from low to medium

(Section 2.5). Apart from pasteurization, which is very effective, several technologies have been evaluated to mitigate the presence of STEC in raw milk. Bacteriophages specific to E. coli and STEC have shown some reductions in STEC during refrigeration storage of raw milk

(Section 5.1.5). The effect of adding bacteriophage to control E. coli during milk fermentation in the making of cheeses has also been examined with varying results depending on the STEC serovar. The degree of support in the evidence of bacteriophage to specifically control for STEC was evaluated as low

(Section 5.2.3). Gamma or eBeam irradiation are very effective at reducing bacterial levels in milk and on cheese surfaces, yet off-flavors are often reported. The degree of support for the evidence was rated as medium

(Section 5.3.2). A summary of processing and post-processing control measures for STEC in raw milk and raw milk cheese and their degree of support rating (high, medium, low), based on scientific evidence, is available in Annex 4.
The implementation of monitoring plans at the farm level to measure the impact of STEC prevalence is considered impractical, although sampling and testing of beef and raw milk products are a means to verify that food safety program are successful. Because STEC are often present only at low levels in foods, culture enrichment of food samples is a critical step in detecting STEC in meat, dairy and other foods. Since STEC testing is complex, the quantitative detection of non-type specific (NTS) E. coli has been proposed as an alternative hygienic indicator during processing and post-processing stages, although it is not an absolute estimate of STEC levels.

The use of molecular techniques, such as PCR, that target STEC virulence genes are highly sensitive and specific for STEC detection but presumptive results must be confirmed by traditional culture-based methods or by immunomagnetic
separation (IMS). Methods are needed that enable the efficient and specific isolation of STEC O157:H7 and non-O157 STEC.

The expert committee also discussed some of the limitations and gaps regarding the available data. In-plant scientific evaluations of interventions and treatments to control STEC throughout raw beef, raw milk and raw milk cheese production are
frequently prohibited due to health risks associated with the potential introduction of pathogens into the food supply and the cost associated with testing large number of samples required for detecting STEC in food matrices. Consequently, surrogate
bacteria, such as NTS E. coli, are used as substitutes and the results extrapolated, meaning that evidence of intervention effects specifically for STEC may not be available currently or in the future. Therefore, there is doubt and uncertainty as to
whether the detection and reduction levels observed in surrogate studies are truly representative of STEC or of commercial production and processing.

Many studies focused on the impact of an individual control measure at a specific stage in the food chain, rather than in the context a total food chain or of the safety of the food available to the consumer. Many food businesses have implemented
multiple control measures concurrently or sequentially on farms and in processing facilities, but the overall efficacy of multiple “hurdles” in the total chain remains difficult to quantify

It was recognized that with advances in analytical methods, including increasing use of molecular tools, the evaluation of evidence concerning some STEC control measures and interventions may need to be revised in the future.

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USA – Say No to Raw Dough!

Posted on October 28, 2022 by | Leave a comment

CDC

What You Need to Know

  • Don’t taste or eat raw (unbaked) dough or batter.
  • Don’t let children handle or play with raw dough, including play clay and dough for crafts.
  • Uncooked flour and raw eggs can contain germs that can make you sick if you taste raw dough.
  • Wash your hands, bowls, utensils, and countertops after handling raw flour, eggs, or dough.

Spending time with family while baking is a great way to celebrate special occasions. When making cookies, brownies, cakes, or bread, you might be tempted to taste a bite before it’s fully baked.

But you can get sick after eating or tasting raw (unbaked) dough or batter. Children can get sick from handling or eating raw dough used for crafts or play clay, too. Follow these safety tips to help you and your loved ones stay healthy when preparing and handling raw dough.

Raw Dough Can Contain Germs That Make You Sick

Flour doesn’t look like a raw food, but most flour is raw. That means it hasn’t been treated to kill germs that cause food poisoning, such as Escherichia coli (E. coli). These harmful germs can contaminate grain while it’s still in the field or flour while it’s being made. Steps like grinding grain and bleaching flour don’t kill harmful germs—and these germs can end up in flour or baking mixes you buy at the store. You can get sick if you eat unbaked dough or batter made with flour containing germs. Germs are killed only when food made with flour is baked or cooked.

CDC investigated outbreaks of E. coli infections linked to raw flour or cake mix in 20162019, and 2021. Some of these investigations led to recalls. Flour and baking mixes containing flour have long shelf lives, meaning they do not go bad quickly. It’s a good idea to check your pantry to see if you have any flour or baking mixes that have been recalled in recent years (search FDA’s recall listexternal icon). If you have any recalled flour or baking mixes, throw them away.

Raw eggs are another ingredient in dough and batter that can make you or your loved ones sick. Raw or lightly cooked eggs can contain Salmonella, a germ that causes food poisoning. Find out how to handle and cook eggs properly.

Some companies make edible cookie dough and brownie batter that you can find in stores. These products are made with heat-treated flour and pasteurized eggs or no eggs. Read the label carefully to make sure the dough is meant to be eaten without baking or cooking.

Stay Safe When Handling Flour and Other Raw Ingredients

Follow these practices to prevent food poisoning when you are baking and cooking with flour and other raw ingredients.

  • Do not taste or eat any raw dough or batter. This includes dough or batter for cookies, brownies, cakes, pie crusts, tortillas, pizza, biscuits, pancakes, or crafts made with raw flour, such as homemade play dough or holiday ornaments.
  • Do not let children play with or eat raw dough, including dough for crafts.
  • Bake raw dough, such as cookie dough, and batter, such as cake mix, before eating.
  • Follow the recipe or package directions for cooking or baking. Use the temperature and cooking time given in the recipe or directions.
  • Do not make milkshakes with products that contain raw flour, such as cake mix.
  • Do not use raw homemade cookie dough in ice cream.
    • Cookie dough ice cream sold in stores contains dough that has been treated to kill harmful germs.
  • Keep raw foods, such as flour and eggs, separate from ready-to-eat foods. Because flour is a powder, it can spread easily.
  • Follow label directions to refrigerate products containing raw dough or eggs until they are baked or cooked (for example, store-bought cookie dough).
  • Clean up thoroughly after handling flour, eggs, or raw dough.
    • Wash your hands with soap and water after handling flour, raw eggs, or any surfaces they have touched.
    • Wash bowls, utensils, countertops, and other surfaces with warm, soapy water.

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Posted in Decontamination Microbial, E.coli, Food Micro Blog, Food Microbiology, Food Microbiology Blog, Food Microbiology Research, Food Microbiology Testing, Food Safety, Food Safety Alert, Food Safety Management, food safety training, microbial contamination, Microbial growth, Microbiological Risk Assessment, Microbiology, Microbiology Investigations, Microbiology Risk, Salmonella

Listeria monocytogenes in ready-to-eat (RTE) foods: attribution, characterization and monitoring

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FAO

Executive summary
A virtual meeting of the Joint FAO/WHO Expert Meeting on Microbiological Risk Assessment (JEMRA) of Listeria monocytogenes (hereinafter referred to as “L. monocytogenes”) in ready-to-eat (RTE) foods: attribution, characterization and monitoring was held from 20 October to 6 November 2020.
The purpose of the meeting was to review recent data on L. monocytogenes and determine the need to modify, update, or develop new risk assessment models and tools for this pathogen. A public call for data and experts was issued to support this work. In addition, background documents on the various aspects related to the meeting were prepared ahead of time for consultation by the experts.
Prepared documents included the following:
1) assessment of past JEMRA documentation; “Risk assessment of Listeria monocytogenes in ready to eat foods: Interpretative summary (MRA4)” (FAO and WHO, 2004a) and “Risk assessment of Listeria monocytogenes in ready to eat foods: Technical report” (MRA5) (FAO and WHO, 2004b);
2) a review of current national L. monocytogenes surveillance programmes;
3) a review of current microbiological and laboratory methods for L. monocytogenes;
4) an update on the virulence markers for L. monocytogenes. The meeting participants reviewed the prepared summary documents and other information on outbreaks and disease attribution, virulence, population risk factors, advances in laboratory methods and surveillance.
The aforementioned risk assessment documents (MRA4, MRA5) (FAO and WHO, 2004a, 2004b) covered a cross-section of RTE foods (pasteurized milk, ice cream, cold smoked fish and fermented meats) linked to invasive listeriosis. Since the publication of these documents, outbreaks of listeriosis continue to occur across the globe associated with previously reported foods, but also with many previously unreported food vehicles, including fresh and minimally processed fruits and vegetables (e.g. frozen vegetables).
The expert group concluded that it would be wise to be more inclusive in future risk assessments and that a full farm-to-fork risk assessment be considered. L. monocytogenes can infect anyone; however, it continues to disproportionally affect certain highly susceptible populations. The expert group recommended that future risk assessments should review groupings of susceptible groups, based on physiological risks and other socio-economic factors.
New information has emerged on L. monocytogenes strain variants, which differ in their virulence and environmental tolerance. Based on a panel of specific genes, the expert group proposed a virulence ranking of L. monocytogenes relevant

to invasive listeriosis.
The expert group concluded that the development and implementation of effective surveillance systems are critical in addressing the control of L. monocytogenes. The use of approved standardized laboratory methods that culture and isolate strains should be the foundation so that human, food and environmental isolates can be further characterized and inventoried.
In conclusion, the expert group identified several critical gaps in the current FAO/WHO risk assessment model and collectively agreed that updating the model would be valuable for informing risk analysis strategies, including in low- and middle-income countries (LMICs). The experts prepared short examples from literature (Annex 1) to demonstrate and highlight several key principles that should be considered in the risk assessment for L. monocytogenes.

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Research – England and Wales see Listeria infection decline

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Food Safety News

The number of Listeria infections fell in 2020 in England and Wales, according to recently released data.

In total, 124 cases of listeriosis were reported in England and Wales in 2020, which is the lowest amount in several years. In 2019, 144 cases were recorded.

There were two outbreaks in England. One was a national epidemic with four cases associated with smoked salmon. Two people died. The other caused two illnesses from 2018 to 2020 and was linked to prepacked sandwiches served in hospitals.

Surveillance of listeriosis in England and Wales is coordinated by the Gastrointestinal Infections and Food Safety (One Health) Division at the UK Health Security Agency (UKHSA). New cases are reported by local clinical laboratories, and health protection teams and by the referral of Listeria monocytogenes isolates to the Gastrointestinal Bacteria Reference Unit (GBRU) for whole genome sequencing (WGS).

Incidence rates were highest in people aged 80 years and older.

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Posted in Decontamination Microbial, Food Illness, Food Micro Blog, Food Microbiology, Food Microbiology Blog, Food Microbiology Testing, Foodborne Illness, Foodborne Illness Death, Illness, Listeria, Listeria monocytogenes, microbial contamination, Microbial growth, Microbiological Risk Assessment, Microbiology, Microbiology Investigations, Microbiology Risk

RASFF Alert – Animal Feed – Aflatoxin B1- Peanut Kernels

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RASFF

Maximum level exceedance of aflatoxin B1 in peanut kernels from Argentina in Germany

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RASFF Alert – Animal Feed -Salmonella – Soya Bean Extraction Meal

Posted on October 28, 2022 by | Leave a comment

RASFF

Salmonella spp. in soybean extraction meal from Germany in Poland

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Posted in Animal Feed, Animal Feed Salmonella, Animal Feed Testing, Food Micro Blog, Food Microbiology, Food Microbiology Blog, Food Microbiology Testing, microbial contamination, Microbial growth, Microbiological Risk Assessment, Microbiology, Microbiology Investigations, Microbiology Risk, RASFF

USA – 30 cases of Salmonella infection reported in Tahoka

Posted on October 27, 2022 by | Leave a comment

KCBD

TAHOKA, Texas (KCBD) – Thirty cases of Salmonella have been reported in Tahoka as of Oct. 25, 2022, according to Lynn County Judge Mike Braddock. Officials believe they’re all related and could have come from a community fundraiser.

Judge Braddock and the Emergency Management Coordinator for Lynn County believe the bacteria could be from a K9 fundraiser held on Oct. 16, 2022, however, they’re still investigating.

Officials say they do not believe the bacteria is from a restaurant.

During the investigation into the cause, the City of Tahoka tested the water to rule out the possibility the bacteria was in the water system.

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Posted in food bourne outbreak, Food Illness, Food Micro Blog, Food Microbiology, Food Microbiology Blog, Food Microbiology Testing, Foodborne Illness, foodborne outbreak, foodbourne outbreak, Illness, microbial contamination, Microbial growth, Microbiological Risk Assessment, Microbiology, Microbiology Investigations, Microbiology Risk, outbreak

USA – Core Outbreak Table – Investigations of Foodborne Illness Outbreaks

Posted on October 27, 2022 by | Leave a comment

FDA

What’s New

  • A new outbreak of E. coli O157:H7 (reference #1121) in a not yet identified product has been added to the table and traceback has been initiated.
  • For the outbreak of Salmonella Litchfield in seafood, (reference #1105), FDA issued an Outbreak Advisory on 10/19/2022.
  • Based on CDC’s epidemiological investigation of two large multistate outbreaks of Cyclospora cayetanensis (reference #1080 and #1084), ill people reported eating a variety of leafy greens before becoming sick. For both investigations, CDC, FDA, and state and local partners conducted epidemiologic and traceback investigations and collected and analyzed product and environmental samples. All samples collected were reported as negative for Cyclospora. Due to the lack of additional detail in the epidemiological data and the absence of supporting evidence collected from traceback and sample collection, FDA could not identify a specific product as the source of either outbreak.
  • For the outbreak of Salmonella Senftenberg (reference #1087) in a not identified product, one additional case was reported, the outbreak has ended, and FDA’s investigation has closed.
  • For the adverse illness event series in frozen food (reference #1076), the outbreak has ended, and the FDA investigation has closed.

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UK – Listeriosis in England and Wales: summary for 2020

Posted on October 26, 2022 by | Leave a comment

Gov UK

Main points for 2020

This report summarises the number, demographics and clinical outcomes of confirmed cases of listeriosis in England and Wales in 2020:

A total 124 cases of listeriosis were reported in England and Wales.

Incidence rates of listeriosis were highest in people aged 80 years and over.

Overall, the crude incidence of listeriosis was lower in men than women, but reported cases among men aged 60 to 69 were 4 times higher than in women aged 60 to 69.

Pregnancy associated infections accounted for a fifth of all reported cases and, a 34.8% of pregnancy-associated cases resulted in stillbirth or miscarriage.

Among non-pregnancy associated cases of listeriosis, death was reported for 29 cases (29.3%), of whom 17 (17.2%) were known to have listeriosis recorded as a cause of death on the death certificate.

Incidence of listeriosis varied geographically, with the lowest incidence in the North West (0.15 per 100,000 population) and the highest in the East Midlands (0.27 per 100,0000 population).

There were 2 listeriosis outbreaks investigated in England, including a national outbreak associated with smoked salmon.

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Australia – Outbreak of gastro at Canberra doughnut shop believed to be caused by sick worker and poor hand hygiene practices – Norovirus

Posted on October 26, 2022 by | Leave a comment

ABC News

The investigation found the illness was caused by the spread of norovirus, a virus that often causes gastro and is spread through direct contact with an infected person or ingestion of faeces or vomit particles from an infected person.

It found no reports of gastro symptoms from customers in the store, making it unlikely a sick patron was the cause of the outbreak, and also noted food handlers on site did not provide stool samples for testing.

The report stated there was evidence collected on-site “suggestive of faecal contamination”, and the spread of the virus was most likely a result of a worker carrying the virus.

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