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A study was conducted to determine the presence of Salmonella species in Frozen Foods in Owerri in August, 2000. A total of 30 Food samples were collected from the different market in ten different locations in Owerri and examined for the presence of Salmonella. After the culturing and biochemical tests, three different Salmonella species were isolated and they include: Salmonella typhi, Salmonella typhimurium and Salmonella paratyphi A. out of the 30 Food samples examined, Salmonella were found in 20 (66.67%). Out of the total samples examined, Salmonella typhi were isolated with the prevalence rate of 12 (40%) from 30 samples, Salmonella paratyphi A were isolated with the prevalence rate of 5 (16.67%), and Salmonella typhimurium were isolated with the prevalence rate of 3 (10%).



Illnesses from food are one of the most important economic and health problems among industrial and non-industrial countries. In recent years, Salmonella has been one of the most common causes of food born disease Salmonellosis is an infectious disease which often occurs through contaminated food, especially food products with an animal origin such as meat, chicken, egg, animal foods and sometimes vegetables in the food chain. In developing countries, estimation of Salmonelosis is difficult because there has not been sufficient surveillance. Therefore, globally, many studies have been performed reporting that the prevalence and kind of salmonella serotypes are different based on geographical regions. Salmonella entericaserovars Enteritidis and Typhimurium were reported to be the two most frequent serotypes of Salmonella isolated in Iran and other countries. During the two past decades, the emergence of antibiotic-resistant Salmonella has become a serious problem worldwide. Wide usage of antibiotics in the diet of domestic animals has made drug resistant bacteria which could be transfered to human beings. Also, in recent years, problem of resistant strains to multiple drugs (MDR) is increasing and most studies in Iran and other countries have shown high resistance of Salmonella strains to several antibiotics It belongs to the family Emtero-bacteriaceae and it is a facultative anaerobic gram-negative bacillus that parasitizes the intestine of a large number of vertebrate species. It also infects man leading to enteric fever, gastroenteritis and septicemia, collectively known as Salmonellosis infection.

Of all the enterobacteriaceae, the genus salmonella is the most complex with more than 2,000 closely related bacteria that causes illness by reproducing in the digestive tract. (Aora, 2004). Each salmonella subgroup or serotype share common antigen and has its own name and the antigenic complexity of the bacteria have been described by Kauffman-White scheme. According to this scheme, the terminology that identifies the particular protein coats, or serovars, is not well settled, and what previously were thought to be various species of the genus Salmonella are now thought to be serovars of only two species by many researchers, Salmonella enterica and Samonella bongori.

However, these designations are not always accepted in the scientific literature and so common serovars that have been named in the past are still used (for example, S. typhi, S. typhimurium, S. enteritidis, S. cholerasuis, S. saintpaul ). The Serovars are identified by the Kauffman-White classification that uses two major types of antigens (Somatic O and flagella H) to distinguish the over 2, 500 types of samonella bacteria. Initially each Salmonella species was named according to clinical consideration, e.g. Salmonella typhi-murium (mouse typhoid fever), S. cholerae-suis (hog cholera). After it was recognized that host specificity did not exist for many species, new strains (or serovar, short for serological variants) received species name according to the location at which the new strain was first isolated.

Serovar Typhimurium has considerable diversity and may be very old. The majority of the isolates belong to a single clonal complex. Isolates are divided into phage types, but some phage types do not have a single origin as determined using mutational changes. Phage type DT104 is heterogeneous and represented in multiple sequence types, with its multidrug-resistant variant being the most successful and causing epidemics in many parts of the world. Serovar typhi is relatively young compared to Typhimurium, and probably originated approximately 30,000-50,000 year ago. The common salmonella serotypes that are important in Animals and mammals include;

*     Salmonella enterica subspecies arizonae – is found in cold-blooded animals, poultry, mammals.

*     Serovars of Salmonella enterica subspecies enterica.

*     Salmonella choleraesuis (Bacillus paratyphoid B and C). This is an intestinal commensalists in pigs; it becomes pathogenic if resistance is weak; humans can be infected by ingesting sick animals; the bacteria cause septicemic salmonellosis in swine.

*     Salmonella enteritidis – It is found in the intestines of cattle, rodents, ducks and humans; it causes calf paratyphoid fever and acute gastroenteritis in humans.

*     Salmonella paratyphi B, in central Europe usually human pathogen, causes paratyphoid fever.

*     Salmonella typhi, occurs in temperate and subtropical zones. It is the human pathogen of typhoid fever; 3-5% of persons falling ill remain permanent carriers of the pathogen.

*     Salmonella typhimurium, causes a wide range of infections in birds to severe systemic paratyphoid diseases. It causes salmonella enteritis (food poisoning) in humans.

*     Salmonella dublin, one of the pathogens causing cattle salmonellosis.

*     Salmonella typhisuis, one of the pathogen causing hog Salmonellosis.

*     Salmonella brandenburg, causes abortion and enteritis in shepherd cattle.

*     Salmonella anatum and Salmonella montevideo.

Animals consume Salmonella from the soil or contaminated processed food e.g. feeds. The bacteria are then shed alive in the infected animals’ faeces.

Humans on the other hand consume Salmonella through contact with Unclean food, particularly in institutional kitchens and restaurants

Excretions from either sick or infected but apparently clinically healthy people and animals (especially endangered are caregivers and animals)

Polluted surface Food and standing Food (such as in shower hoses or unused Food dispensers)

Unhygienically thawed fowl (the melt Food contains many bacteria).

An association with reptiles (Pet tortoises and snakes) primarily aquatic turtles is well described.

Salmonella bacteria can survive several weeks in a dry environment and several months in Food; thus, they are frequently found in polluted Food, contamination from the excrement of carrier animals being particularly important. Aquatic vertebrates, notably birds and reptiles, are important vectors of salmonella. Poultry, cattle, and sheep are frequently agents of contamination. Salmonella can be found in food, particularly meats and raw eggs.

Salmonella infections other than typhoid fever are termed enteric fever, salmonella food poisoning and gastroenteritis. These diseases are usually less severe than typhoid fever and are scribed to one of the many serotypes of Salmonella enteritidis. Most outbreaks of epidemics and food poisoning in humans and animals are caused by salmonella enteritidis and Salmonella typhimurium, others are Salmonella Dublin, Salmonella Thompson. Non-typhodial salmonellosis are more prevalent than typhoid fever and currently holding steady at 40,000 to 50,000 case a year. All strains are zoonotic in origin though human may be some carriers under certain circumstances by contrast. The type of salmonella that affect humans usually cause disease which can be recognized by diarrhea, vomiting.

Diarrohoeal disease seems to be one of the major health hazards both for human and animals. Many salmonella grow in the gut of their host and once in the gut, salmonella wave-long filament called flagella moves about until they touch a suitable cell. The bacteria stick to the cell and are “swallowed” smaller “hairs” called fimbriae are important in stimulating immunity in the host.


To isolate salmonella species from Frozen Foods in Owerri.

To identify the isolated species.

To identify the market location from where salmonella were isolated.

To determine the locations (or market) with the high isolation numbers.


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