Salmonellosis

13/07/2022

Enteric infections due to Salmonella bacteria are generally referred to by the term ‘salmonellosis’ when they are due to Salmonella species other than Salmonella typhi and Salmonella paratyphi.
Various animals (especially poultry, pigs, cattle, and reptiles) can be reservoirs for Salmonella, and humans generally become infected by eating poorly cooked, contaminated food. The incubation period and the symptoms depend on the amount of bacteria present in the food, the immune status of the person and the type of Salmonella.
In general, 12 to 36 hours after the consumption of contaminated food, a clinical picture characterised by fever, diarrhoea, abdominal pain, nausea and vomiting may appear. Symptoms usually last for a few days. Due to the effects of dehydration, hospital admission may sometimes be required. In the elderly and otherwise weak patients death sometimes occurs. Elderly patients are also more prone to developing severe blood infection. In addition, post-infectious complications, such as reactive joint inflammation occur in about 10% of the cases.
Diarrhoea-causing Salmonellae are present worldwide. Prophylactic measures are aimed at all stages of food supply, from production to distribution and consumption.

07/07/2022

07/07/2022

07/07/2022

Complications of Salmonella Infection
In approximately 5% of nontyphoidal Salmonella infections, patients develop bacteremia. In a small proportion of those cases, the bacteria can cause a focal infection, where it becomes localized in a tissue and causes an abscess, arthritis, endocarditis, or other severe illness. Infants, the elderly, and immune-compromised persons are at greater risk for bacteremia or invasive disease. Additionally, infection caused by antimicrobial-resistant nontyphoidal Salmonella serotypes appears to be more likely to cause bloodstream infections.
Overall, approximately 20% of cases each year require hospitalization, 5% of cases have an invasive infection, and 0.5% die. Infections in infants and in people 65 years of age or older are much more likely to require hospitalization or result in death. There is evidence that Salmonella infections increase the risk of developing digestive disorders, including gastroesophageal influx disease and irritable bowel syndrome (IBS). In a retrospective matched case control study of military medical records, Porter et al. analyzed the increased risk of chronic gastrointestinal sequelae following infection with four foodborne pathogens including Salmonella.
Although most persons who become ill with diarrhea caused by Salmonella recover without any further problems, a small number of persons develop a complication often referred to as reactive arthritis. The terminology used to describe this type of complication has changed over time. The term “Reiter Syndrome” was used for many years, but has now fallen into disfavor. The precise proportion of persons that develop reactive arthritis following a Salmonella infection is unknown, with estimates ranging from 2 to 15%. Symptoms of reactive arthritis include inflammation (swelling, redness, heat, and pain) of the joints, genitourinary tract (reproductive and urinary organs), or eyes.
More specifically, symptoms of reactive arthritis include pain and swelling in the knees, ankles, feet, and heels. Less frequently, the upper extremities may be affected, including the wrists, elbows, and fingers. Tendonitis (inflammation of the tendons) or enthesitis (inflammation where tendons attach to the bone) can occur. Other symptoms may include prostatitis, cervicitis, urethritis (inflammation of the prostate gland, cervix, or urethra), conjunctivitis (inflammation of the membrane lining the eyelid), or uveitis (inflammation of the inner eye). Ulcers and skin rashes are less common. Symptoms can range from mild to severe.
Reactive arthritis typically occurs anywhere from three days to six weeks after the antecedent infection and may involve one or more joints, though usually six or fewer. Although most cases recover within a few months, some continue to experience complications for years. Treatment focuses on relieving the symptoms.
There are a lot of gaps in our knowledge surrounding this complication. Since there is no specific test for reactive arthritis, doctors rely on signs and symptoms of the patient to make the diagnosis. However, there are no clearly defined criteria or set of symptoms used to diagnose this condition. The role of genetics is also unclear. It is thought that the presence of a gene called human leukocyte antigen, namely HLA-B27, predisposes a person to develop reactive arthritis, along with other autoimmune diseases; however, several studies have shown that many persons that develop reactive arthritis lack this genetic factor.

07/07/2022

Treatment with antibiotics before collecting a specimen for testing can affect bacterial growth in culture and lead to a negative test result even when Salmonella causes the infection. Thus, it is important to collect a specimen for laboratory testing before antibiotics are given.
Culturing of organisms such as Salmonella has been the mainstay of diagnostic testing conducted at clinical laboratories. Isolates obtained from culture are forwarded from clinical laboratories to public health laboratories, where additional testing is performed, including serotyping, antimicrobial susceptibility, and genetic testing. Results of these additional tests allow epidemiologists to monitor trends and detect outbreaks
Increasingly, hospitals and clinical laboratories are using culture-independent diagnostic tests (CIDTs) rather than culture-based testing to detect enteric pathogens such as Salmonella. Commonly used CIDT testing methods include testing by polymerase chain reaction (PCR) and enzyme immunoassay (EIA) testing. CIDTs have a rapid turnaround time, can detect multiple pathogens in one test, and cost less than traditional testing procedures such as culture, which often require specialized media and years of training. Clinicians are thus able to identify and provide appropriate treatment in a shorter amount of time.
However, a CIDT-identified positive specimen of Salmonella might not be available for the serotyping and advanced genetic characterization that is used to identify disease clusters and outbreaks. For these activities, a culture-derived isolate is required. Clinical laboratories must then submit CIDT-identified specimens to a public health laboratory, which attempts to replicate clinical laboratory results and recover culture-derived isolates. In one study conducted at the Tennessee Department of Health Public Health Laboratory, isolates were recovered in only 72% of CIDT-identified positive Salmonella specimens. This has important implications for disease surveillance and outbreak detection, particularly since timely reporting of foodborne diseases is necessary to identify persons at risk for exposure and to prevent additional cases in outbreak settings.
There are multiple steps between the onset of a foodborne illness and its investigation by a public health agency, which have the potential to delay recognition of outbreaks caused by reportable enteric diseases. As pointed out by Craig Hedberg et al. in their study published in Emerging Infectious Diseases:
One important way to speed the detection of outbreaks is to encourage clinicians to immediately notify health departments when they suspect a patient is part of an outbreak. Since many outbreaks caused by E. coli O157:H7 and Salmonella spp. last multiple days, physician reporting concurrent with stool collection may provide opportunities for a public health intervention that could prevent outbreak-associated cases.
Several studies have recommended some strategies to increase the rate of positive stool culture: (1) not performing routine cultures in patients who experience the onset of diarrhea three or more days after admission to the hospital, (2) not using multiple specimens (but, instead, using one appropriate specimen), (3) not culturing by smears of re**al swabs, and (4) eliminating stool specimens taken from patients that were treated with antibiotics prior to providing a specimen.

07/07/2022

How is Salmonella Infection Diagnosed?
Salmonella bacteria can be detected by stool culture. In cases of bacteremia or invasive illness, the bacteria can also be cultured from blood, urine, or, on rare occasions, from other body tissues. A f***l, blood, or other sample is placed in nutrient broth or on agar and incubated for up to 2-3 days. After that time, a trained microbiologist can identify the bacteria, if present, and confirm its identity by looking at biochemical reactions. Typically, this test is conducted at a hospital or clinical laboratory. Isolates obtained from culture are forwarded from clinical laboratories to public health laboratories.

07/07/2022

Salmonella is 1 of 4 key global causes of diarrhoeal diseases.
Most cases of salmonellosis are mild; however, sometimes it can be life-threatening. The severity of the disease depends on host factors and the serotype of Salmonella.
Antimicrobial resistance is a global public health concern and Salmonella is one of the microorganisms in which some resistant serotypes have emerged, affecting the food chain.
Basic food hygiene practices, such as "cook thoroughly", are recommended as a preventive measure against salmonellosis.
The burden of foodborne diseases is substantial: every year almost 1 in 10 people fall ill and 33 million of healthy life years are lost. Foodborne diseases can be severe, especially for young children. Diarrhoeal diseases are the most common illnesses resulting from unsafe food, 550 million people falling ill each year, including 220 million children under the age of 5 years. Salmonella is 1 of the 4 key global causes of diarrhoeal diseases.
Salmonella is a gram negative rods genus belonging to the Enterobacteriaceae family. Within 2 species, Salmonella bongori and Salmonella enterica, over 2500 different serotypes or serovars have been identified to date. Salmonella is a ubiquitous and hardy bacteria that can survive several weeks in a dry environment and several months in water.
While all serotypes can cause disease in humans, a few are host-specific and can reside in only one or a few animal species: for example, Salmonella enterica serotype Dublin in cattle and Salmonella enterica serotype Choleraesuis in pigs. When these particular serotypes cause disease in humans, it is often invasive and can be life-threatening. Most serotypes, however, are present in a wide range of hosts. Typically, such serotypes cause gastroenteritis, which is often uncomplicated and does not need treatment, but disease can be severe in the young, the elderly, and patients with weakened immunity. This group features Salmonella enterica serotype Enteritidis and Salmonella enterica serotype Typhimurium, the two most important serotypes of Salmonella transmitted from animals to humans in most parts of the world.
The disease
Salmonellosis is a disease caused by the bacteria Salmonella. It is usually characterized by acute onset of fever, abdominal pain, diarrhoea, nausea and sometimes vomiting.
The onset of disease symptoms occurs 6–72 hours (usually 12–36 hours) after ingestion of Salmonella, and illness lasts 2–7 days.
Symptoms of salmonellosis are relatively mild and patients will make a recovery without specific treatment in most cases. However, in some cases, particularly in children and elderly patients, the associated dehydration can become severe and life-threatening.
Although large Salmonella outbreaks usually attract media attention, 60–80% of all salmonellosis cases are not recognized as part of a known outbreak and are classified as sporadic cases, or are not diagnosed as such at all.
Sources and transmission
Salmonella bacteria are widely distributed in domestic and wild animals. They are prevalent in food animals such as poultry, pigs, and cattle; and in pets, including cats, dogs, birds, and reptiles such as turtles.
Salmonella can pass through the entire food chain from animal feed, primary production, and all the way to households or food-service establishments and institutions.
Salmonellosis in humans is generally contracted through the consumption of contaminated food of animal origin (mainly eggs, meat, poultry, and milk), although other foods, including green vegetables contaminated by manure, have been implicated in its transmission.
Person-to-person transmission can also occur through the faecal-oral route.
Human cases also occur where individuals have contact with infected animals, including pets. These infected animals often do not show signs of disease.
Treatment
Treatment in severe cases is electrolyte replacement (to provide electrolytes, such as sodium, potassium and chloride ions, lost through vomiting and diarrhoea) and rehydration.

Routine antimicrobial therapy is not recommended for mild or moderate cases in healthy individuals. This is because antimicrobials may not completely eliminate the bacteria and may select for resistant strains, which subsequently can lead to the drug becoming ineffective. However, health risk groups such as infants, the elderly, and immunocompromised patients may need to receive antimicrobial therapy. Antimicrobials are also administered if the infection spreads from the intestine to other body parts. Because of the global increase of antimicrobial resistance, treatment guidelines should be reviewed on a regular basis taking into account the resistance pattern of the bacteria based on the local surveillance system.

20/06/2022

Enteric fever (also known as typhoid and paratyphoid) is an illness caused by the bacteria Salmonella enterica subspecies enterica serovar Typhi (typhoid) or serovars Paratyphi A, B or C (paratyphoid). Typhoid fever is a serious disease and can be life-threatening unless treated promptly with antibiotics. The disease may last several weeks and convalescence takes some time. In the literature, paratyphoid is considered to be typically milder than typhoid and of shorter duration
The bacteria that cause typhoid and paratyphoid only occur in humans. Humans acquire infection through eating food or drinking water that has been contaminated with infected faeces or through direct faecal-oral transmission. Transmission occurs following the ingestion of food or water that has been heavily contaminated (10 or more organisms may be required to cause illness) by the bacterium S. Typhi or S. Paratyphi. In the UK, most cases of typhoid and paratyphoid are acquired abroad in countries and regions of the world where hygiene or sanitation is poor.
This report summarises the epidemiology of laboratory-confirmed cases of S. Typhi and S. Paratyphi reported in England, Wales and Northern Ireland (EWNI) in 2018. It includes both reference laboratory and enhanced enteric fever surveillance
Confirmed symptomatic cases of S. Typhi and S. Paratyphi in England, Wales and Northern Ireland are diagnosed by the UK Health Security Agency, then Public Health England, Salmonella Reference Service (SRS), within the Gastrointestinal Bacteria Reference Unit (GBRU) ¥. Data for laboratory-confirmed cases from 2007 onwards was extracted from the reference laboratory database using ‘date received by the laboratory’. All S. Typhi and S. Paratyphi isolates referred to the SRS undergo identification using whole genome sequencing (WGS) and single nucleotide polymorphism (SNP) typingEpidemiological information was obtained from enhanced enteric fever surveillance. Cases are occasionally tested multiple times for confirmation and to check the infection has cleared, therefore data has been deduplicated so that only one laboratory report for each case is counted.
Confirmed asymptomatic, probable and possible cases are analysed separately at the end of this report.
All data was analysed using Excel (Version 1808, Microsoft) and Stata (Version 15, StataCorp).
¥ As we only collect data from the UKHSA Salmonella Reference Service, local reports of cases of enteric fever may differ for Wales and Northern Ireland.
General trend
In 2018, 349 laboratory-confirmed symptomatic cases of S. Typhi and S. Paratyphi were reported by the UKHSA SRS in EWNI, an increase of 14% when compared to the 306 cases reported in 2017 This is the largest annual increase observed since 2001. Cases of S. Typhi and S. Paratyphi decreased by an average of 7% year on year from 2011 to 2017 (range -26% to +4%) before increasing in 2018. In 2018, 59% of cases were caused by S. Typhi and 41% by S. Paratyphi A and B . There were no cases of S. Paratyphi C reported in 2018.