Category Archives: Animal Feed Testing

This publication presents data on Salmonella reports from livestock species in Great Britain (England, Wales and Scotland) collected and collated by the Animal and Plant Health Agency (APHA) during 2021 and also provides data from previous years for comparative purposes.

The data in the first 12 chapters cover reports of Salmonella in animals, with separate chapters for the main livestock species, reports of Salmonella in dogs, reports of Salmonella in wildlife and reports of Salmonella in animal feeding stuffs.

The 13th chapter covers antimicrobial resistance data for Salmonella (England and Wales only).Since 1993, the date of a Salmonella incident has been recorded as the date it was reported to an Officer of the Minister. Under the present system, any Salmonella reports that are confirmed or identified after the publication of the annual report will be incorporated into the revised tables that appear in the following year’s publication. This may result in the number of incidents and/ or isolations differing from that previously given for a particular year.

The most recent version of the report should therefore always be used when comparing data from year to year. Revisions in the way that data have been compiled and presented since 1993 mean that, with the exception of the tables on Salmonella in animal feeding stuffs, data in this report cannot be compared directly with information published prior to 1993. A more detailed comparison can be generated, if required, for any Salmonella serovar, or phage type in the case of S.Enteritidis and S. Typhimurium. Requests for such data should be made to the Department of Epidemiological Sciences, APHA Weybridge who will be happy to assist with requests at Foodbornezoonoses@apha.gov.uk. Care should be taken when comparing data from one year to another as an increase or decrease in the number of isolations and incidents does not necessarily indicate a similar change in prevalence. This is because the total number of samples examined and their distribution are often not known.

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Posted in Animal by Products, Animal Feed, Animal Feed Salmonella, Animal Feed Testing, Food Micro Blog, Food Microbiology, Food Microbiology Blog, Food Microbiology Research, Food Microbiology Testing, microbial contamination, Microbiological Risk Assessment, Microbiology, Microbiology Investigations, Microbiology Risk, Pet Food, Pet Food Salmonella, Pet Food Testing, Research

RASFF Alerts – Animal Feed – Enterobacteriaceae – Dog Chews

Posted on September 23, 2022 by KSW | Leave a comment

RASFF

Too high count of Enterobacteriaceae in dog chew from Turkey in Germany

RASFF

Enterobacteriaceae in dog chews from Turkey in Germany

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Posted in Animal Feed, Animal Feed Testing, Food Micro Blog, Food Microbiology Blog, microbial contamination, Microbiological Risk Assessment, Microbiology, Microbiology Investigations, Microbiology Risk, Pet Food, Pet Food Enterobacteriaceae, Pet Food Testing, RASFF

RASFF Alerts – Animal Feed – Salmonella – ABPO – Pet Food – Fenugreek Seed Powder – Rapeseed Meal

Posted on September 23, 2022 by KSW | Leave a comment

RASFF

Presence of Salmonella Isangi in animal by product to be used as feed material from Germany in Italy

RASFF

Salmonella in pet food from Netherlands in Belgium

RASFF

Salmonella Weltevreden in fenugreek seed powder in France and Finland

RASFF

Salmonella Tennessee in rapeseed meal from Germany in Finland

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Posted in Animal by Products, Animal Feed, Animal Feed Salmonella, Animal Feed Testing, Pet Food, Pet Food Salmonella, Pet Food Testing, RASFF, Salmonella

Research – Prevalence and Characterization of Shiga Toxin Producing Escherichia coli Isolated from Animal Feed in Croatia

Posted on September 19, 2022 by KSW | Leave a comment

MDPI

A survey on prevalence and number of Shiga toxin-producing Escherichia (E.) coli (STEC) in animal feed was carried out over a period of nine years in the Republic of Croatia. A total of 1688 feed samples were collected from feed factories and poultry farms. Analysis included two standard procedures: sample enrichment and (a) immunomagnetic separation and plating on two selective media; or (b) plating on two selective media. Confirmation of STEC included morphological examination, biochemical tests, serotyping, and polymerase chain reaction. Morphological and biochemical characterization revealed 629 E. coli strains. Further serological screening method revealed 78 STEC and EPEC serotypes, while only 27 strains were confirmed as STEC with PCR. All positive samples (1.6%) originated from poultry farms and contained combination of virulence genes: eaeA, stx1, and/or stx2. Since the presence of stx (especially stx2) and eae are identified as risk factors for development of severe diseases in humans, results of this survey indicate that avian sources of STEC infections might be one of those “undefined sources” of human illnesses. Further research is necessary for evaluation of risks posed by contaminated feed, poultry, and environment.

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Posted in Animal Feed, Animal Feed Testing, eae, eaeA, Food Micro Blog, Food Microbiology, Food Microbiology Blog, Food Microbiology Research, Food Microbiology Testing, microbial contamination, Microbiological Risk Assessment, Microbiology, Microbiology Investigations, Microbiology Risk, Research, STEC, STEC E.coli, STX 1, STX 2

RASFF Alerts – Animal Feed – Salmonella – Feather Meal – Soy Flour – Soya Bean Meal

Posted on September 16, 2022 by KSW | Leave a comment

RASFF

Salmonella in feather meal from Russia in Poland and Hungary

RASFF

Salmonella Senftenberg in soy flour from Hungary, via the Netherlands in Italy, Slovenia and Belgium

RASFF

Salmonella Yoruba in Soya bean meal from NL in Finland

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

Research – Underreported Human Exposure to Mycotoxins: The Case of South Africa

Posted on September 11, 2022 by KSW | Leave a comment

MDPI

South Africa (SA) is a leading exporter of maize in Africa. The commercial maize farming sector contributes to about 85% of the overall maize produced. More than 33% of South Africa’s population live in rural settlements, and their livelihoods depend entirely on subsistence farming. The subsistence farming system promotes fungal growth and mycotoxin production. This review aims to investigate the exposure levels of the rural population of South Africa to dietary mycotoxins contrary to several reports issued concerning the safety of South African maize. A systematic search was conducted using Google Scholar. Maize is a staple food in South Africa and consumption rates in rural and urban communities are different, for instance, intake may be 1–2 kg/person/day and 400 g/person/day, respectively. Commercial and subsistence maize farming techniques are different. There exist differences influencing the composition of mycotoxins in food commodities from both sectors. Depending on the levels of contamination, dietary exposure of South Africans to mycotoxins is evident in the high levels of fumonisins (FBs) that have been detected in SA home-grown maize. Other potential sources of exposure to mycotoxins, such as carryover effects from animal products and processed foods, were reviewed. The combined effects between FBs and aflatoxins (AFs) have been reported in humans/animals and should not be ignored, as sporadic breakouts of aflatoxicosis have been reported in South Africa. These reports are not a true representation of the entire country as reports from the subsistence-farming rural communities show high incidence of maize contaminated with both AFs and FBs. While commercial farmers and exporters have all the resources needed to perform laboratory analyses of maize products, the greater challenge in combatting mycotoxin exposure is encountered in rural communities with predominantly subsistence farming systems, where conventional food surveillance is lacking.