VPH 123 Meat-borne Diseases PDF

Summary

This document provides an overview of meat-borne diseases, focusing on poultry diseases. The document details various pathogens associated with poultry meat, such as Salmonella, Campylobacter, and Staphylococcus aureus. It also discusses preventative measures to reduce microbial load during different stages of processing.

Full Transcript

VPH 123
Meat-borne Diseases

Ernesto C. Balolong Jr., DVM MSc CBO
Assistant Professor, CVM-DVPS
[email protected]
Key Diseases from Poultry
poultry meat - causally involved in a large number of human gastro-intestinal
infections
may be acquired by the birds during the hatching and growing periods, and are
mostly carried asymptomatically
contamination of poultry meat – production conditions at the farm, transport
conditions of live animals, scalding and plucking procedures and, to a large degree,
on the evisceration techniques

Salmonella spp. Aeromonas Spp.
Campylobacter Spp. Yersinia
Clostridium perfringens and C. botulinum Escherichia coli
Staphylococcus aureus Mycobacterium avium
Listeria monocytogenes
1. Salmonella spp.

gastro- enteritis cases have been associated with the consumption of
poultry meat contaminated with S. Typhimurium and S. Enteritidis
 infection happens during the breeding phase, hatching and rearing
bacteria concentrate in the intestine, excreted for varying periods esp. during
stress situations
establish themselves preferentially in the appendices, can reach numbers of
up to 108 cfu/g of intestinal contents
low infective dose especially in young chicken
over-crowded stables and unsatisfactory cleaning and disinfection measures
facilitate spreading of the pathogens by cross-contamination
Although the occurrence of Salmonella in poultry has been alarming in recent
years, contamination of poultry meat and meat products was not found to be
on a high level
considerable dissemination of the organisms during
subsequent processing at the abattoir
2. Campylobacter Spp.

Campylobacter (C.) jejuni - increasingly been implicated in human enteritis
associated with poultry meat consumption
serotypes present in poultry included those associated with human enteritis
105 up to more than 106cfu/g of intestinal contents
horizontal entry sources, e.g. transportation cages which are insufficiently cleaned
and disinfected, contaminated as, infected wild birds and even man
due to cross-contamination, one Campylobacter-positive flock may cause
contamination of subsequent negative flocks in the course of the slaughter process.
bacteria were found in poultry meat and edible by-products (liver, stomach) in
amounts of 102cfu/g, occasionally > 105cfu/g --- Low infective dose (500 bacterial
counts) may be sufficient to induce an infection in man
improper cooking of poultry meat and slaughter by-products allow infection
3. Clostridium perfringens and C. botulinum
present in soil, dust and the gastro-intestinal tract of many warm-blooded animals,
including chickens and turkeys with > 105 cfu/g in feces
Clostridium (C.) perfringens type A strains are involved in human food poisoning
Type A strains may be haemolytic, with relatively heat- sensitive spores. Other types
are non-haemolytic, but their spores are highly heat- resistant. Such strains are able
to survive normal cooking procedures
If cooked meat is held under conditions which favour growth of clostridia, they
multiply rapidly to hazardous levels. Mean generation times of 10-12 min were
recorded by Mead
unlike many other foods, poultry meat is able to support spore-formation of C.
perfringens, especially leg muscle which has a pH value of approx. 6.5.
Clostridium botulinum appears to be relatively uncommon on poultry meat
Poultry meat may become contaminated with C. botulinum from different sources.
e.g. ingredients such as spices, which often contain a variety of sporing bacteria.
4. Staphylococcus aureus

are often carried by live poultry, both on the skin and in the nasopharynx
Many strains of S. aureus isolated from chickens and turkeys were not capable of
producing enterotoxin, for toxin-producing strains, types C and D are the most
common
Food poisoning from S. aureus is usually attributed to the mishandling of cooked food
e.g. by an infected individual and subsequent temperature abuse
visceration and water immersion chilling as well as plucking, a 100-fold or even greater
increase of the levels of S. aureus on the birds is possible
S. aureus appears to be capable of colonising the rubber finger of defeathering
machine, with atmosphere during defeathering is warm and moist and the presence of
organic material may serve as a source of nutrients
5. Listeria monocytogenes

found worldwide in poultry, with Wild rodents but also wild birds as the reservoir for
pathogenic strains of Listeria\
Listeria can be detected on tools, equipment and surfaces of machinery, in scalding
and chilling water and in sewage
once introduced into a processing plant can persist a long time and are very resistant
to cleaning and disinfection.
insufficiently cooked poultry meat still is considered as one of the main sources of
foodborne infections by Listeria
6. Aeromonas Spp

sporadic cases of illness in man in connection with the consumption of poultry meat
In most of these outbreaks, Aeromonas strains capable of producing enterotoxin
were isolated
Aeromonas could frequently be detected on poultry skin either before or after
evisceration
also detected on edible by-products (gizzards, hearts) and in water.
able to grow at 4°C.
Cold-stored raw poultry meat near the best-by date is a possible source for the
contamination of other food with Aeromonas.
7. Yersinia

Strains of Y. enterocolitica were frequently found in the intestinal contents of poultry
which, however, were not pathogenic

Certain serotypes of Y. enterocolitica, however, which are not pathogenetic for poultry,
cause gastrointestinal complications in man, i.e. septicemia, arthritis, etc
8. Escherichia coli

Escherichia (E.) coli, which is part of the intestinal flora, could also be detected in
poultry meat in the course of the evisceration process.

A number of strains pathogenic for poultry are known which, however, are of no
particular relevance to man.

human cases caused by E. coli 0 157:H7 from poultry have so far not been reported.

Artificial infection of poultry with strains pathogenic for humans (109 E. coli
0157:H7) did not result in clinical symptoms in these birds, although excretion of
these E. coli strains by the animals was detected for a period of up to 90 days
9. Mycobacterium avium

Avian tuberculosis has hardly been detected in broilers and laying hens under
intensive husbandry, but must still be reckoned with in poultry from small farm
flocks
Recommended measures

the overall microbial load should be simultaneously reduced
microbial growth should be controlled by clean practices, washing of carcasses and
keeping the product chilled or frozen.
microbial contamination at the processing stage several hygienic control points
should be monitored i.e. the scalding tank, the defeathering and the plucking
machine.
During the evisceration process, hygienic tools and continuous water spraying of the
machines should be used to avoid any accumulation of debris on the carcasses.
After final washing, the warm carcasses should chilled promptly to prevent growth of
mesophilic pathogens and to limit multiplication of psychrotrophs.
Key Diseases from Poultry

Salmonella spp. Aeromonas Spp.
Campylobacter Spp. Yersinia
Clostridium perfringens and C. botulinum Escherichia coli
Staphylococcus aureus Mycobacterium avium
Listeria monocytogenes
Key Diseases from Pork

The level of exposure of consumers to microbiological hazards in fresh pork is unlikely to
be reduced significantly by an end- product control only.

contamination of pork and pork products by pathogenic bacteria have often been
epidemiologically linked to food borne illness in humans

Properly structured HACCP-like systems, applied from farm to fork, offer the best
approach available.

Salmonella spp., Campylobacter spp., Yersinia enterocolitica and Listeria monocytogenes.
Teania solium, Trichinella sp.
SELF JF et al. Outbreaks attributed to pork in the United States, 1998–2015 Epidemiol. Infect. (2017), 145, 2980–2990
 Characteristics of outbreaks attributed to pork,
Foodborne Diseases Outbreak Surveillance System, 1998– 2015

SELF JF et al. Outbreaks attributed to pork in the United States, 1998–2015 Epidemiol. Infect. (2017), 145, 2980–2990
 Characteristics of outbreaks attributed to pork,
Foodborne Diseases Outbreak Surveillance System, 1998– 2015

SELF JF et al. Outbreaks attributed to pork in the United States, 1998–2015 Epidemiol. Infect. (2017), 145, 2980–2990
Foodborne Disease Outbreaks in the Philippines (2005–2018)

Azanza MP et al. Foodborne Disease Outbreaks in the Philippines (2005–2018). Philippine Journal of Science. 148 (2): 317-336, June 2019
Foodborne Disease Outbreaks in the Philippines (2005–2018)

Azanza MP et al. Foodborne Disease Outbreaks in the Philippines (2005–2018). Philippine Journal of Science. 148 (2): 317-336, June 2019
 Characteristics of outbreaks attributed to pork,
Foodborne Diseases Outbreak Surveillance System, 1998– 2015

SELF JF et al. Outbreaks attributed to pork in the United States, 1998–2015 Epidemiol. Infect. (2017), 145, 2980–2990
Survey by the Philippine College of Veterinary Epidemiologists during the 25th PPC
Recommended Measures to reduce microbial load:

Pre-harvest level
All-in/all-out production, Strict sectioning
Close pen separations/ preventing snout contact between pens
Weaning to a clean environment, disinfection of compartments between batches
Strategy for managing sick pigs
Hygienic lock facilities
Fermented wet feed
Closed feed storage
Acidification of feedstuffs and/or drinking water
A minimum number of suppliers
Pest and fly control
Transport and lairage level
Deliver batches from a herd directly to the slaughterhouse by separate trucks
Avoid mixing up of batches
Prevent stress of the pigs
Thorough cleaning and disinfection of trucks between each transport
Strict separation of batches especially pigs from Salmonella-negative herds
Keep pigs in smaller groups
Clean the lairage between batches
Reduce lairage time to an absolute minimum
Ensure a thorough cleaning and disinfection of the lairage at the end of the
slaughter day
Feed withdrawal
Abattoir level
Separate slaughtering of batches of pigs from Salmonella-negative and
Salmonella- infected herds
Special hygiene practices during slaughter of pigs from high risk herds
Sufficiently high scalding temperature
Sufficient singeing of all parts of the carcass
Appropriate cleaning and disinfection of slaughterhouse equipment
General good hygienic practices
Application of bung bag or similar device during slaughter
REFERENCES:
FAO. 2021. Backyard farming and slaughtering – Keeping tradition safe. Food safety technical toolkit
for Asia and the Pacific No. 2. Bangkok.

Self JF et al. Outbreaks attributed to pork in the United States, 1998–2015 Epidemiol. Infect. (2017),
145, 2980–2990

Azanza MP et al. Foodborne Disease in the Philippines (2005–2018). Philippine Journal of Science.
148 (2): 317-336, June 2019

Smulders F and Collins J (eds). Food safety assurance and veterinary public health (volume 2):
Assurance during food processing. Wageningen Academic Publishers. 2004.

Good Animal Husbandry Practices for Swine (PNS/BAFS 267:2019).