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Salmonella in the pork production chain and its impact on human health in the European Union

Published online by Cambridge University Press:  28 February 2017

S. BONARDI Open the ORCID record for S. BONARDI [Opens in a new window]
S. BONARDI*
Affiliation:
Department of Veterinary Science, Unit of Food Inspection, University of Parma, Via del Taglio 10, 43126 Parma, Italy
*
*Author for correspondence: S. Bonardi, Department of Veterinary Science, Unit of Food Inspection, University of Parma, Via del Taglio, 10, 43126, Parma, Italy. (Email: silvia.bonardi@unipr.it)
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Summary

Salmonella spp. comprise the second most common food-borne pathogens in the European Union (EU). The role of pigs as carriers of Salmonella has been intensively studied both on farm and at slaughter. Salmonella infection in pigs may cause fever, diarrhoea, prostration and mortality. However, most infected pigs remain healthy carriers, and those infected at the end of the fattening period could pose a threat to human health. Contamination of pig carcasses can occur on the slaughter line, and it is linked to cross-contamination from other carcasses and the presence of Salmonella in the environment. Therefore, Salmonella serovars present on pig carcasses can be different from those detected in the same bathes on the farm. In recent years, S. Typhimurium, S. Derby and S. serotype 4,[5],12:i:- (a monophasic variant of S. Typhimurium) have been the most common serovars to be detected in pigs in EU countries, but S. Rissen, S. Infantis, S. Enteritidis and S. Brandenburg have also been reported. In humans, several cases of salmonellosis have been linked to the consumption of raw or undercooked pork and pork products. Among the main serovars of porcine origin detected in confirmed human cases, S. Typhimurium, the monophasic variant S. 4,[5],12:i:- and S. Derby are certainly the most important.

Keywords

Humanspigpig carcassSalmonella entericaslaughterhouse
Type
Original Papers
Information
Epidemiology & Infection , Volume 145 , Issue 8 , June 2017 , pp. 1513 - 1526
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Copyright
Copyright © Cambridge University Press 2017 

INTRODUCTION

Salmonella enterica is one of the most common and widely distributed food-borne pathogens in the European Union (EU) [Reference Pires, de Knegt and Hald1], and is considered one of the leading causes of gastroenteritis and bacteraemia in humans worldwide [Reference Hendriksen2]. The most recent European Food Safety Authority (EFSA) and European Centre for Disease Prevention and Control (ECDC) report on zoonoses and zoonotic agents in the EU was published in 2015. This document presented the results of zoonoses monitoring activities carried out during 2014 in 32 European countries (28 member states and four non-member states). Human salmonellosis ranked second after campylobacteriosis with 88 715 confirmed cases and an EU notification rate of 23·4 cases per 100 000 population. After the declining trend observed in previous years, salmonellosis presented a 15·3% increase in the notification rate in 2014, compared with 2013 (20·3 cases per 100 000 population) [3].

Human salmonellosis is caused by both host-restricted (S. Typhi and S. Paratyphi A) and ubiquitous serovars, but only the former are responsible for the systemic life-threatening form of salmonellosis, referred to as typhoid fever [Reference Su and Chiu4]. Non-typhoid Salmonella infection is mainly characterised by gastroenteritis, with acute onset of fever, nausea, vomiting, abdominal cramps and diarrhoea; however, immunocompromised individuals may suffer from recurrent or prolonged Salmonella infections [Reference Chen5], whereas HIV patients and children could be affected by infections in the bloodstream, leading to death [Reference Deen6].

SALMONELLA IN THE PORK PRODUCTION CHAIN

Salmonellosis in pigs

Host adaptation of Salmonella serovars is of greatest importance in determining the clinical features and outcome of the infection. Apart from host-restricted serovars that are able to cause a typhoid-like disease in a single host species (e.g. S. Typhi and S. Paratyphi A in humans, and S. Typhisuis in pigs), other serovars, referred to as host-adapted serovars, are associated with one host species, but are also able to cause illness in other hosts (e.g. S. Choleraesuis in pigs and S. Dublin in cattle) [Reference Uzzau7]. S. Choleraesuis and S. Dublin generally cause severe systemic disease in pigs and cattle, respectively, but occasionally can be responsible for disease in other mammalian hosts, including humans [Reference Uzzau7]. In contrast, ubiquitous Salmonella serovars are the unrestricted serovars that are capable of causing systemic disease in a wide range of host animals, but more frequently cause a self-limiting gastroenteritis in a broad range of species. Examples of unrestricted serovars include S. Typhimurium and S. Enteritidis [Reference Uzzau7].

Infections with S. Typhisuis and S. Choleraesuis serovars in pigs usually result in swine paratyphoid, a severe systemic disease that is often fatal and characterised by fever, shivering, diarrhoea, respiratory distress and depression [Reference Wilcock, Schwartz, Leman, Straw, Mengeling, D'Allaire and Taylor8, Reference Gray9]. Infected pigs exhibit clinical signs within 36–48 h after infection, and shed S. Choleraesuis in their faeces within 24 h of exposure. After experimental inoculation, shedding of the microorganism can vary between 103 and 106 colony-forming unit (CFU)/g of faeces. However, in natural infections, pigs might be exposed to lower levels of S. Choleraesuis (as low as 4 × 102 CFU/g of faeces) that can still be responsible for high morbidity and severe outbreaks of swine paratyphoid within a relatively short period. Transmission of S. Choleraesuis can thus be very efficient on the farm, during transport and in lairage before slaughter [Reference Gray9]. S. Choleraesuis, including variant Kunzendorf, was the predominant serovar isolated from pigs worldwide, over the past century (especially during the 1950s and 1960s). However, during the late 1990s and early 2000s, it was rarely detected in the EU countries [Reference Fedorka-Cray, Gray, Wray, Wray and Wray10, Reference Davies11]. S. Choleraesuis var. Kunzendorf reappeared in Danish herds from 2012 to 2013, causing multiple outbreaks that were characterised by high mortality (20–30%) among 7–50 kg pigs [Reference Pedersen12].

Although infections in pigs by ubiquitous Salmonella serovars could result in enteric and even fatal disease, infected animals frequently and asymptomatically carry these serovars in the tonsils, gut and gut-associated lymphoid tissue [Reference Fedorka-Cray, Gray, Wray, Wray and Wray10]. In EU countries, non-typhoidal Salmonella infections in pigs are related mostly to S. Typhimurium and its monophasic variant (antigenic formula 1,4,[5],12:i:-; 4,[5],12:i:-; or 4,12:i:-), S. Derby and S. Infantis [3, Reference Nollet13Reference Nathues15]. Other frequently reported serovars in pigs include Rissen, Panama, Goldcoast, Agona, Brandenburg, London, Anatum, Manhattan, Enteritidis and Bovismorbificans [3, Reference Wales16, Reference García-Fierro17].

Transmission of Salmonella between pigs occurs mainly via the faecal–oral route [Reference Boyen18], although some studies have demonstrated that the upper respiratory tract and lungs could be portals of entry as well [Reference Fedorka-Cray19]. A comparison between the prevalence of infection in pigs on the farm and in the abattoir revealed that prevalence on the farm often seems lower, partly because of the existence of latent, undetectable Salmonella carriers [Reference Hurd20]. These latent carriers may begin to shed Salmonella only after leaving the farm, a process that might be triggered by stress factors linked to group housing, transportation and holding pens at the slaughterhouse, as the physiological changes associated with stress could promote recrudescence in latent carriers, or increase the susceptibility of non-carriers to new infections [Reference Hurd21].

Salmonella in pig farms (pre-harvest stage)

The ‘pre-harvest stage’ refers to that part of the food chain that includes the holding period of pigs on the farm until their departure and loading for transportation to the slaughterhouse [22]. During this period, pigs could become infected with Salmonella and show clinical signs, or they could become asymptomatic carriers and excrete the pathogen in faeces, or harbour it in several tissues, such as the digestive tract, closely associated lymph nodes or the tonsils [Reference Côté23].

Among the clinically affected pigs, most are of the weaning or post-weaning age, and the fattening pigs (body weight from 65 to 100 kg, and over) are generally asymptomatic carriers of unrestricted Salmonella serovars. The carrier status of pigs could be determined by the analysis of faecal cultures, obtained for example, via the collection of faeces with rectal swabs from randomly selected pigs during the fattening period [Reference Visscher24]. The most frequently detected serovars in pigs on farms in the EU are S. Typhimurium monophasic variant, S. Typhimurium and S. Derby [Reference Nollet13, Reference Visscher24, Reference Merialdi25Reference Denis27]. In 2014, the most common Salmonella serovars isolated from pigs in the EU were S. Typhimurium (50·3%), S. Derby (17·5%), S. enterica 1, 4,[5],12:i:- (8·4%), S. Typhimurium var. Copenhagen (4·4%), S. London (2·1%), S. Infantis (1·7%), S. Muenchen (1·6%), S. Rissen (1·5%), and S. Livingstone (1·2%) [3]. S. Typhimurium has been the predominant serotype detected within the last few years, accounting for as much as 72·8% of isolates in 2012. Since S. Typhimurium had been reported in 9 out of 10 member states in 2014, and was commonly reported in the baseline surveys of slaughter pigs and breeding pigs in 2006/2007 and 2009, respectively, its distribution across the EU can be assumed to be relatively wide [28, 29]. The prevalence of isolates of monophasic strains of S. Typhimurium has shown no considerable change over the last few years, ranging between 8·4% of all isolates in 2014, and 14% in 2013. Within recent years, Poland, Malta, the UK and Italy accounted for a large proportion of pig isolates of the monophasic S. Typhimurium (reported antigenic formulae 1,4,5,12:i:- and 1,4,1,2:i:-) [3].

With respect to the prevalence on positive farms, the EU baseline study performed in 2008 reported an average of 33·3% herds that tested positive for Salmonella, with a wide range among member states (0·0–55·7%). The most recent report on zoonoses and zoonotic agents in the EU, reported a 10·1% herd prevalence of Salmonella among nine countries in 2014 [3]. However, a comparison between the on-farm and abattoir prevalence of infection in pigs revealed that the on-farm prevalence is often underestimated. In Germany, the on-farm prevalence of infection in pigs, based on faecal analysis, was 5·58%; however, the caecal contents of 24·9% of slaughtered pigs were found to be Salmonella positive [Reference Visscher24]. In a study by Hurd et al. [Reference Hurd20], the abattoir prevalence of Salmonella in pigs was 39·9%, as opposed to an on-farm prevalence of 5·3%, a disparity that was probably due to the sample type (1 g faecal swabs on farm vs. 10 g caecal contents after necropsy). The sensitivity of faecal samples collected on farm was particularly poor for pigs infected in the lymph nodes (0% on farm, 12·2% at abattoir). The sensitivity of faecal culture increases only twofold with a 10 g sample, as compared with a 1 g sample; thus, low faecal volume might partially explain the low sensitivity of samples collected from live pigs on farm [Reference Funk, Davies and Nichols30]. Indeed, other factors might contribute to this discrepancy, such as the incidence of recent infections during transportation or slaughter [Reference Hurd21]. Otherwise, the presence of latent undetectable carriers among infected pigs is a common characteristic in the epidemiology of Salmonella [Reference Hurd20]. Moreover, intermittent shedding by pigs is a common feature that can interfere with monitoring and research programmes on Salmonella infection and the determination of health status in animals [Reference Pires, Funk and Bolin31].

Prevalence can vary at the farm level, depending on various factors, such as feeding practices, including the degree to which the feed is ground, and the pH and type of feed; management procedures, such as continuous or all-in/all-out production system; different types of herds (farrow-to-finish herds or fattening herds); size of the herd; as well the level of hygiene and general health status of the pigs. The provision of safe feed is the first step in ensuring safe food, especially in a ‘farm-to-fork’ concept [Reference Sauli32]. Therefore, pig feed should be Salmonella-free to guarantee a safer pork chain.

Wet feed has been demonstrated to reduce the risk of Salmonella infection, in comparison to pelleted feed, probably because of a fermentation step and consequent growth of lactic acid bacteria and yeasts [Reference Prohászka33]. The large amounts of organic acids produced, thus exert a protective effect, in a similar manner to the addition of organic acids to water [Reference Van der Wolf34] and feed [Reference Van Winsen35]. In contrast, pelleted feed is considered one of the most consistently reported risk factors for Salmonella shedding in pigs [Reference Wilkins36]. In addition, feed particle size can affect the prevalence of Salmonella isolated from the gastrointestinal tract of pigs. In comparison to finely ground feed (<0·20–1·00 mm), coarsely ground feed (2·00– >3·15 mm) reduces the prevalence of Salmonella, by enhancing the fermentation of starch in the gut [Reference Visscher37].

Regarding the influence of pH, values of 4·5 or lower effectively inhibit Salmonella both in the feed and in the gastrointestinal tract of pigs. Fermented liquid feed can yield such values, and improves the performance of sucklings, weaners and grower-finishers. Feeding pigs fermented liquid feed prevents the growth and proliferation of pathogens, such as Escherichia coli and Salmonella, in the gut by reducing the pH in the stomach [Reference Missotten38]. This is particularly important, because Salmonella has been detected in pig feed. In 2014, for example, some member states of the EU reported various serovars, including S. Typhimurium, S. Enteritidis, S. Give, S. Agona, S. Anatum and S. Mbandaka in the feed of pigs [3]. However, despite several studies on various interventions in feeding practices, there remains a lack of strong evidence of the effects between any association (acidification of liquid or pelletised feed vs. mash; coarse vs. finely ground feed; wet vs. dry feed, etc.) in reducing the prevalence of Salmonella on farm. Indeed, researchers do not consistently support the association between non-pelleted feed and a reduction in the prevalence of Salmonella in pigs [Reference O'Connor39].

The all-in/all-out management system reportedly has a protective effect against Salmonella infection [Reference Lo Fo Wong40], particularly when practised by the entire barn more than by single rooms [Reference García-Feliz41]. The protective effect has also been observed when animals from different age groups are housed separately [Reference Gotter42]. Contact with other species, as dogs and cats, can introduce the microorganism on farms, thereby increasing the risk of Salmonella infection [Reference Gotter42]. Management practices also encompass the design of pen walls (solid, spindles or combination) and type of floor (fully slatted floors vs. <50% slatted floors can significantly reduce the prevalence of Salmonella) [Reference Nollet13]. Nose-to-nose contact between pens is an important risk factor, as pens that allow direct contact among pigs are more likely to be Salmonella positive than those without such contact [Reference Wilkins36]. Poor pen cleaning and disinfection, and poor biosecurity measures are also important risk factors for the persistence of Salmonella at the farm level [Reference Fosse, Seegers and Magras43]. Cleaning by pressure washing with water, disinfection with chemicals and effective rodent control programmes are effective hygienic measures that should be adopted on farms [Reference García-Feliz41]. Nevertheless, the resistance of Salmonella to some disinfectants, such as glutaraldehyde, formaldehyde and hydroxide peroxide at a concentration of 1·0%, make their use ineffective in field conditions, when it is protected by the development of a biofilm [Reference Marin, Hernandiz and Lainez44].

The prevalence of Salmonella shedding in pigs is higher in finishing farms (open farms) than in farrow-to-finish farms (closed farms) [Reference Rajić45]. A Belgian study demonstrated that finishing farms were two times more likely to have Salmonella shedders than farrow-to-finish farms, with positive rates of 10·3% and 5·4%, respectively (mean within-herd prevalence of 7·8%) [Reference Rasschaert46]. Other authors have observed similar findings [Reference Rajić45]. One possible explanation is that pigs raised in fattening farms originate from the piggery units of other farms. Upon arrival, they are frequently mixed with piglets of different origin, thus sharing the various health conditions of each (including Salmonella infection). Furthermore, transportation from piggeries to the finishing farms could be a stressful event that promotes the shedding of Salmonella by carrier animals, and the spread of infection throughout the barns [Reference Rasschaert46].

In farrow-to-finish herds, where sows maintain the infection and excrete Salmonella particularly after weaning [Reference Nollet47], prevalence might be influenced by herd size. Dors et al. [Reference Dors48] observed that prevalence in herds with more than 200 shedding sows was higher than in smaller herds. Furthermore, the size of finishing herds could increase the risk of development of the Salmonella carrier status in pigs, as this is usually higher in units that slaughter more than 3500 pigs per year [Reference García-Feliz41].

Salmonella during transportation and holding (the harvest stage)

The harvest stage refers to the part of the food chain that includes transportation of the animals from the farm, the lairage period, the slaughtering process and the cooling of carcasses [22].

During this stage, asymptomatic pigs could begin to shed Salmonella after having left the farm, owing to stress factors that are linked to group housing, transportation and holding at the slaughterhouse. Transportation significantly increases Salmonella shedding, thus, shedders become an important source of Salmonella to other pigs that are being transported [Reference Hurd21, Reference Rostagno, Eicher and Lay49]. Stress can be caused by rough handling of the pigs at the time of loading and unloading, high stocking density during transport, long duration of transport, poor driver skills, adverse weather conditions and feed withdrawal. A relatively long feed withdrawal period, which is usually 12–18 h before transport, could be associated with changes in the gut microbiota, and elevated levels of Salmonella in the faeces [Reference Martín-Peláez50].

Another factor that could influence the prevalence of infection among pigs at slaughter is the lairage duration. A positive relationship exists between the time spent at lairage and the frequency of Salmonella detection in the lymph nodes, probably due to increased opportunity for invasion of the mesenteric lymph nodes (MLN) under conditions of prolonged stress. Pigs held for 12 h or more showed a greater chance of acquiring Salmonella from the lairage environment (16·7%), as compared with pigs held for 1–3 h (11·1%) [Reference Bonardi51].

Transportation and lairage conditions are thus important steps in the pork production chain that can increase the number of infected animals that are slaughtered. However, some studies suggest that external sources of infection might have a greater impact than stress, in increasing the detection of Salmonella at slaughter. For example, in a comparison of on-farm and slaughtered pigs, Hurd et al. [Reference Hurd21] reported a sevenfold increase, and detected a variety of Salmonella serovars in necropsied animals, that had not been isolated from pigs on the farm. Such infections could be acquired before slaughter from various shedder pigs in transport trucks or the lairage environment, as infection of the gastrointestinal tract and infiltration of the associated lymph nodes can occur in as little as 2 h [Reference Hurd, Gailey and Rostagno52]. Rapid infection during transportation, and particularly during holding of pigs, is a major cause of increased Salmonella prevalence. Generally, the holding pen could be an important control point for Salmonella in the pork production chain [Reference Hurd21]. Reduced exposure in trucks and holding pens is more likely to reduce Salmonella prevalence, than attempts to minimise stress, which is inevitable during transportation and lairage [Reference Dickson, Hurd and Rostagno53]. To facilitate the movement of pigs, stress at lairage can be kept under control by using well-designed infrastructure, well-lit corridors and minimal and careful handling of pigs, as specified by Regulation (EC) 1069/2009 [54], and discussed by some authors [Reference De Busser55]. In addition, showering pigs when the temperature rises to >10°C [Reference Schütte56] improves animal welfare at lairage. However, these measures can successfully reduce infections in pigs, only if the lairage environment is not already contaminated with Salmonella, thus posing a challenge for all slaughterhouses [Reference De Busser55]. Contamination of the lairage might be responsible for oral infections in holding pigs, as well as skin contamination, which is directly related to carcass contamination during the slaughter process. In a comparison of carcasses with contaminated skin and those without, the probability of surface contamination of the carcass was reduced from 59% to 35%, respectively [Reference Rossel, Jouffe and Belceil57]. Furthermore, failure to dehair the carcass can significantly increase the number of contaminated carcasses [Reference Bonardi58].

Salmonella at slaughter (the harvest stage)

The prevalence of Salmonella contamination in pork carcasses has been extensively studied in most European countries. Detection rates vary among studies, but all underline that Salmonella can be frequently isolated from MLN and faecal samples of pigs. Indeed, detection of Salmonella in the lymph nodes is frequently considered the ‘gold standard’ for definition of the carrier state at slaughter [22]. Alternatively, caecal material or faeces can be tested for carriage of Salmonella in pigs [22]. According to recent studies, the prevalence of Salmonella in MLN ranges from 7·4% to 26·0% [Reference Argüello14, Reference Visscher24, Reference Bonardi51, Reference Gomes-Neves59Reference De Busser62] in EU countries (Table 1). In 2014, very low levels of prevalence were detected in Sweden (0·0%) and Finland (0·03%), where control and eradication programmes reported the presence of Salmonella in the lymph nodes of finishing pigs [3]. Different surveys have reported prevalence at around 20–30% in faecal contents [Reference Davies11, Reference Visscher24, Reference Powell63, Reference Bonardi64] (Table 1). Furthermore, monitoring programmes based in the analysis of pig faeces in Denmark and Estonia reported rates of 21·6% and 27·3%, respectively [3]. Other data on the prevalence of Salmonella in pigs at slaughter are also available based on examination of the tonsils [Reference Visscher24, Reference Vieira-Pinto, Temudo and Martins61, Reference Powell63] (Table 1), mandibular lymph nodes [Reference Vieira-Pinto, Temudo and Martins61], gall [Reference Visscher24], heart and tongue [Reference Powell63].

Table 1. Prevalence of Salmonella in MLN, faeces, tonsils and carcasses of pigs at slaughter in different EU countries

EU, European Union; MLN, mesenteric lymph nodes; n.s., not shown.

Routes of contamination might be related to the pig or the slaughter environment. Contamination from the faeces of pigs that have been slaughtered on the same day might occur, with a typical distribution of Salmonella to the distal and medial surfaces of carcasses [Reference Smid65]. Contamination of carcasses with Salmonella on the skin of pigs has been demonstrated [Reference Bonardi58], but is probably less significant than faecal contamination [Reference Smid65]. In addition to the pig, the slaughter environment, in which microflora pose a potential risk for carcass contamination, is a major source of Salmonella [Reference Argüello66]. Equipment, such as carcass splitters and belly openers, might be contaminated with Salmonella from fluids dripping from the carcasses onto the machines. Consequently, Salmonella on contaminated equipment could be transferred to other carcasses that are subsequently slaughtered [Reference Smid65]. Salmonella can also be spread by workers at the abattoir, as the hands of meat handlers can be frequently contaminated [Reference Gomes-Neves59].

A marked reduction has been observed in the prevalence of Salmonella and the number of contaminated carcasses as the slaughtering process progresses [Reference Duggan67], because of the steps taken to reduce bacterial flora on the skin of pigs. In one study examining a relatively large number of Salmonella-positive carcasses, the prevalence of Salmonella contamination was 96·6% at exsanguination and 35·9% after slaughter. During the slaughter process, skin contamination was reduced from 96·6% to 16·2%, but cross-contamination via equipment was responsible for the final number of Salmonella-positive carcasses reported [Reference van Hoek68]. Several authors have outlined that the main means of contamination is probably the result of a continuous cycle between pigs, the environment and the carcasses [Reference De Busser62, Reference Botteldoorn69].

Different levels of prevalence have been detected in pig carcasses in EU countries, ranging from 3·2% to 16% [Reference Davies11, Reference Argüello14, Reference Gomes-Neves59Reference Vieira-Pinto, Temudo and Martins61, Reference Bonardi64, Reference Bolton, Ivory and McDowell70] (Table 1). Data from several countries in 2014, reported by the EFSA and ECDC are shown in Table 2. The differences observed could be attributed to several factors, such as the number of carrier pigs introduced to the slaughter line; implementation of effective steps for decontamination including dehairing, polishing and flaming; maintenance of good hygienic standards at slaughter; cross-contamination between carcasses and equipment; cross-contamination among carcasses; presence of resident slaughterhouse microflora and passive transmission via the hands of workers. Regulation (EC) 2015/1474 [71] regarding the use of recycled hot water to remove microbiological surface contamination from carcasses has recently offered increased opportunity to reduce the prevalence of Salmonella.

Table 2. Prevalence of Salmonella in pig carcasses at slaughter in 2014

Sampling unit: single pig [3].

Because the pathogen is not only introduced to the slaughter line by the pigs, but could persist in the slaughterhouse environment, or be acquired during transportation and holding, the serovars isolated from on-farm samples can vary widely from those isolated after slaughter [Reference Visscher24, Reference Merialdi25, Reference Rostagno, Eicher and Lay49, Reference Gebreyes72]. The most commonly reported Salmonella serovars isolated from carcasses at slaughter are Derby, Typhimurium, Typhimurium monophasic variant, Rissen, Brandenburg, London, Manhattan, Muenchen and Stanley [Reference Bonardi51, Reference Smid65]. The monophasic variant of S. Typhimurium (but not the biphasic S. Typhimurium) has been identified in pigs at slaughter [Reference Bonardi51]. It is the most commonly isolated serovar in some countries, such as the UK, where it accounted for 32·9% of the serovars isolated from pigs in 2013 [73]. The rise in incidence of the monophasic variant of S. Typhimurium might be related to a novel clonal group that is characterised by the tetra-resistant pattern ASSuT (ampicillin, streptomycin, sulphonamides, tetracycline), which emerged during the 2000s in some EU countries, and has become particularly common in some member states, such as Italy, Denmark, the UK and Germany. In this clonal group, multidrug resistance is conferred by a new genomic island and the pattern ASSuT can be used for provisional identification of the isolates [Reference Hauser74, Reference Lucarelli75].

Salmonella in the post-harvest stage: the EU Regulation (EC) No 2073/2005 criteria

The criteria for Salmonella in foodstuffs, laid down by Regulation (EC) No 2073/2005 [76], have been in force since 1 January 2006. In member states of the EU, most national monitoring programmes for Salmonella in pork and pork products are based on the collection of swab samples of the carcass at the slaughterhouse, and/or meat samples at the processing plants. Regulation (EC) No 217/2014 [77] is a revision of Regulation 2073/2005 [76] and serves to reduce the acceptable number of Salmonella-positive pig carcasses from 5 out of 50 (10%) to 3 out of 50 (6%). Therefore, food business operators have to implement appropriate interventions to reduce the number of contaminated carcasses.

The studies on pork and ready-to-eat pork products have not been uniformly conducted among various EU countries, and show differences in sampling procedures, types of end-products and detection methods. Thus, consideration was given only to the most recent data provided by EFSA, which reported an overall Salmonella prevalence of 0·5% in fresh pork and 0·7% in ready-to-eat minced meat, meat preparations and meat products. Despite these relatively low numbers, pork and pork products, especially if consumed raw or undercooked, frequently represent a source of non-typhoidal Salmonella strains to humans [3].

PIGS AS A SOURCE OF SALMONELLA TO HUMANS

Besides poultry, laying hens and turkeys, pigs are one of the major animal species that are responsible for the transmission of Salmonella to humans. However, their role in food-borne salmonellosis in humans varies among EU countries. Salmonella source attribution studies estimate that pigs are a major source of salmonellosis in Southern Europe, accounting for 43·6% of all cases, whereas laying hens are the most significant source in Northern, Eastern and Western EU countries accounting for between 30·0% and 57·6% of all reported cases [Reference Pires, de Knegt and Hald1]. Overall, laying hens (via the eggs) represents the most important source of human salmonellosis in the EU, accounting for 42·4% of all cases, followed by pigs, accounting for 31·1%. Pigs are the major contributors of salmonellosis in eight countries, namely Belgium, Cyprus, Finland, France, Ireland, Italy, Poland and Sweden, whereas disease attribution to laying hens and pigs are similar in the Netherlands [Reference De Knegt, Pires and Hald78].

The role of pork in food-borne outbreaks of human salmonellosis has been demonstrated in several investigations, and many isolates detected in pigs have been responsible for human cases [Reference Bonardi51]. Overall, pork is ranked third among food categories that show strong epidemiological evidence of an association with human outbreaks of salmonellosis. The highest ranked food category is eggs and egg products, and the second, baked products, which were each responsible for 44·0% and 12·9% of outbreaks of human salmonellosis in 2014, respectively. Pork and pork products show strong evidence of an association with 9·3% of outbreaks reported in the EU. Pork is therefore the most significant source of meat that is responsible for the transmission of Salmonella to consumers [3].

Furthermore, when the source is known, the category ‘pork and products thereof’ is the mode of transmission most frequently associated with S. Typhimurium outbreaks [3]. Because S. Typhimurium and its monophasic variant are prevalent both on farm and at slaughter, isolation of this serovar in strong evidence outbreaks attributed to the consumption of pork is not surprising. In 2014, the most common Salmonella serovars isolated from pork and pork products in various EU countries were S. Typhimurium (28·3%), S. Derby (23·6%), S. Typhimurium monophasic variant (18·0%), S. Infantis (8·8%), S. Rissen (4·9%), S. Brandenburg (4·9%) and S. Enteritidis (2·1%). Although S. Typhimurium was the most commonly isolated serovar from both pigs and pork, the isolation of S. Typhimurium in pigs was significantly higher (54·7%) than it was in pork. This could be attributed to the fact that some countries submit more data on Salmonella from pigs than from pork, thus reducing the reported prevalence of S. Typhimurium in pork [3].

With respect to human salmonellosis, recent information on Salmonella serovars collected at the EU level, highlights the most common as S. Enteritidis and S. Typhimurium, which account for 44·4% and 17·4%, respectively, of all serovars reported in 2014. These serovars have been identified in all member states of the EU. The monophasic variant of S. Typhimurium represents the third most common serovar, responsible for 7·8% of all notified human cases. In order of frequency, S. Infantis (2·5%), S. Stanley (1%) and S. Derby (1%) are reported in fewer confirmed human cases, but are more widely distributed in several countries [3]. The pig-adapted S. Choleraesuis causes a serious infection in humans that is associated with high mortality, tends to be more invasive and cause fewer gastrointestinal symptoms than most other serovars [Reference Cohen, Bartlett and Corey79]. Fortunately, it is not a common serovar in humans [3], despite the reappearance of the Kunzendorf variant within recent years [Reference Pedersen12].

European data on the most frequently isolated Salmonella serovars, confirm that they can all be detected in pigs and pork, but in varying proportions. Otherwise, to establish possible epidemiological correlations between porcine and human strains, genotyping of the isolates responsible for human cases that have also been detected in suspicious food sources, should be performed. Salmonella isolates can be subtyped by pulsed-field gel electrophoresis (PFGE), multiple-locus variable-number tandem-repeats analysis (MLVA) and patterns of antimicrobial resistance, in order to characterise the isolates that are associated with outbreaks. For example, in 2011, one major outbreak and several geographically dispersed smaller outbreaks that had been linked to pork were traced back to a butcher's shop and a pig farm in England, where a multidrug-resistant ASSuTTm (ampicillin, streptomycin, sulphonamides, tetracycline, trimethoprim) strain of S. Typhimurium phage type 120 (DT120) was isolated [Reference Paranthaman80]. An outbreak at a wedding in Italy in 2011 was caused by the monophasic variant of S. Typhimurium 4,[5],12:i:-, of the rare phage type DT7a [Reference Lettini81]. Since the source was identified in a cooked pork product, epidemiological investigations on the farm of origin revealed that the pigs carried a different serovar (biphasic S. Typhimurium) of the same phage type DT7a in their faeces. To identify specifically the most suitable subtyping methods by which the isolates associated with this outbreak could have been characterised, isolates from humans, pork and pigs were typed using XbaI PFGE, MLVA and patterns of antimicrobial resistance. That study could not demonstrate whether isolates of the outbreak were directly related to isolates from the animals, but suggested that MLVA in particular, could be a reliable tool to support outbreak investigations and assess the genetic relatedness among Salmonella isolates [Reference Lettini81]. In Italy two outbreaks of S. 4,[5],12:i:- DT193 were found to be caused by different strains, as the isolates were characterised using both BlnI-PFGE and MLVA [Reference Barco82]. In contrast, XbaI PFGE showed that the strains associated with the outbreaks were undistinguishable [Reference Barco82]. Characterisation of Salmonella is essential for proper identification, tracking and intervention during food-borne outbreaks. The phenotypic methods that traditionally provide important epidemiologic data during outbreak investigations have reduced value as typing tools for the surveillance and detection of common sources during outbreaks [Reference Lettini81]. Within recent years, WGS (whole-genome sequencing) has increasingly become more readily available, and is routinely used as a powerful tool in diagnostic and epidemiological investigations during outbreaks and in various studies on infectious bacteria [Reference Leekitcharoenphon83].

Molecular investigations and studies in antimicrobial resistance have been conducted both in food-borne outbreaks [Reference Lettini81Reference Leekitcharoenphon83] and in research studies [Reference Bonardi51, Reference Kérouanton84Reference Sandt87], demonstrating the epidemiological connection between porcine and human compartments. In Italy, a comparison of XbaI PFGE profiles of porcine and human Salmonella isolates demonstrated shared profiles of S. Derby, S. 4,[5],12:i:-, S. Rissen, S. Manhattan, S. Brandenburg, S. Livingstone, S. London and S. Muenchen [Reference Bonardi51]. The relationship between porcine and human cases of salmonellosis (S. Derby) has also been demonstrated in France, in a study that typed porcine and human isolates with XbaI, BlnI and SpeI PFGE [Reference Kérouanton84]. Most S. Derby isolates from pigs and humans were found to be resistant to streptomycin, sulphonamides and tetracycline (R-type SSuT) [Reference Kérouanton84]. The whole-genome sequence of the most commonly detected strain of S. Derby in French pigs was recently characterised. The porcine isolate showed PFGE profiles and patterns of resistance (S, SSu, T) that have also been frequently identified in human isolates of Salmonella [Reference Kérouanton84]. In Switzerland, two distinct clones of S. 4,[5],12:i:-, showing the ASSuT and SSuT patterns of antimicrobial resistance, were identified among human and porcine isolates [Reference Gallati86].

Food-borne outbreaks of S. Typhimurium associated with pork products have been frequently reported, and have been associated with the consumption of dried pork sausages in Spain [Reference Arnedo-Pena88], pork in England [Reference Paranthaman80], smoked pork tenderloin [Reference Wójcik89], ready-to-eat spreadable pork sausage (Teewurst) [Reference Kuhn90] and salami produced with pork and venison in Denmark [Reference Kuhn91], and pork salami in Italy [Reference Luzzi92]. S. Typhimurium monophasic variant was identified as the causative agent of an outbreak in Germany following the consumption of minced pork [Reference Alt93] and in Italy following the consumption of cooked pork [Reference Lettini81]. In another outbreak in Spain, both monophasic and biphasic S. Typhimurium strains, as well as S. Derby, were associated with the consumption of dried pork sausages [Reference Arnedo-Pena88].

S. Derby is strongly associated with pigs and pork products. In 2013, a food-borne outbreak of S. Derby affected 145 elderly patients and caused one death in Berlin, Germany, following the consumption of Teewurst [Reference Frank94]. Another outbreak was reported in France during the same year, and S. Derby was isolated from a typical meal, in which cross-contamination of the meat (beef and pork) probably occurred during preparation [73].

In 2014, Germany reported one food-borne outbreak of S. Muenchen that affected 164 people, of which four persons died. This outbreak was associated with the consumption of mostly raw pork products, in private households and a residential institution. A comprehensive investigation was conducted and the outbreak strain was detected in various food samples and in primary pig production facilities [3].

Over the last decade, Germany, Italy, the UK and Portugal have reported an increased prevalence of S. Typhimurium monophasic variant in pig populations [Reference Bonardi51, Reference Hauser74, 95Reference Gomes-Neves97], and consequently in humans affected by salmonellosis [3]. Another emerging serovar related to the pig is S. Brandenburg [Reference Bonardi51, Reference Korsak98], which has been increasingly isolated from humans affected by the disease [3, Reference Bonardi51, 73]. Although it is not among the most frequently detected serovars in pigs in Europe generally, S. Rissen is common in pigs in Southern Europe [Reference Bonardi51, Reference Gomes-Neves59]. It is among the most frequently detected serovars in humans and pork production systems in several parts of the world, particularly Asia, and frequently detected in the USA [Reference Pornsukarom99]. Over the last few years, S. Rissen has been rarely detected in the EU, and the number of confirmed human cases is relatively low [3]. As Far-Eastern strains of epidemic multidrug-resistant S. Rissen have been isolated from pigs in some countries, for example Spain [Reference Antunes100], further dissemination to other member states is possible.

CONCLUSIONS

Salmonellosis has a major impact on human health, being the second most frequently reported zoonosis in EU countries [3]. Among food animals, pigs are estimated to be the second largest contributor to human cases of salmonellosis in the EU, after laying hens. For this reason, the symptomatic or asymptomatic carriage by pigs, epidemiology of the infection in herds, distribution of Salmonella serovars among pigs and contamination routes at slaughter have all been intensively investigated.

Many risk factors exist on the pig farm, including those related to feed, animal management, hygiene and biosecurity. The complexity of interactions among these factors can either amplify or reduce the prevalence Salmonella in pigs (Fig. 1). Consequently, implementing a unique strategy to reduce the levels of Salmonella in the pork production chain is a major challenge, especially as it relates to farm management, which over several years, can progressively change risk factor patterns [Reference Gotter42]. Transportation practices and holding at slaughter are often responsible for contamination among animals, and these factors largely influence the prevalence of Salmonella in positive pigs entering the slaughter chain (Fig. 1). At slaughter, dehairing, polishing, flaming and sectioning operations can all affect the bacterial contamination of pork carcasses in several ways, and these processes generally do not include any hazard eliminating points [Reference Borch, Nesbakken and Christensen101]. Furthermore, one of the main risk factors for contamination is the persistence of Salmonella in the slaughter environment and the subsequent spread of variable serovars to pig carcasses. Nevertheless, many studies have demonstrated that good hygienic practices at slaughter are more effective in reducing the prevalence of Salmonella than on-farm interventions [Reference Baptista, Dahl and Nielsen102]. Abattoir interventions and their role in Salmonella control on pig carcasses are summarised in Figure 1.

Fig. 1. Salmonella amplification and control points in the pork production system.

Within recent years, Salmonella transmission from pigs to humans via the food chain has often been demonstrated, both in food-borne outbreaks and in epidemiological studies, with the aid of molecular techniques that are able to identify the strains responsible for porcine and human infections [Reference Bonardi51, Reference Paranthaman80Reference Sandt87]. The EU Regulation (EC) No. 2160/2003 [103] on zoonoses targets the reduction of Salmonella in animals and food products of animal origin during all phases of production, transformation and distribution, with an emphasis on primary production. Member states of the EU are required to take effective measures to control Salmonella in specific animal species (including pigs), and thereby lower the incidence of human salmonellosis. The interventions should be done on farm, at the slaughterhouse, or a combination of the two, as agreed by the member states [28]. Although quantitative microbiological risk assessment has shown that specific interventions at slaughter are more likely to produce a more significant reduction in cases of human illness than interventions at the level of primary production [Reference Bollaerts104, 105], evaluation of the health status of pigs on the farm is still highly recommended. In some EU countries, such as Germany and Denmark, specific monitoring programmes categorise herds through a nationwide sampling scheme, based on Salmonella seroprevalence in pigs. Herds are categorised according to the percentage of ELISA (enzyme-linked immunosorbent assay) seropositive samples present [Reference Merle106, Reference Alban, Stege and Dahl107]. Serological monitoring aims to estimate the risk for Salmonella at the level of the herd, and reduce the risk of introducing the pathogen into the meat production chain [Reference Blaha108]. This type of monitoring should be considered a strategic tool for food safety in all European countries.

ACKNOWLEDGEMENTS

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Pires, SM, de Knegt, L, Hald, T. Estimation of the relative contribution of different food and animal sources to human Salmonella infections in the European Union. Søborg, Denmark: National Food Institute, Technical University of Denmark. EFSA Supporting Publications 2011. Published online: 25 August 2011. doi: 10.2903/sp.efsa.2011.EN-184.Google Scholar
2. Hendriksen, RS, et al. Global monitoring of Salmonella serovar distribution from the World Health Organization Global Foodborne Infections Network Country Data Bank: results of quality assured laboratories from 2001 to 2007. Foodborne Pathogens and Disease 2011; 8: 887900. doi: 10.1089/fpd.2010.0787.CrossRefGoogle ScholarPubMed
3. European Food Safety Authority, European Centre for Disease Prevention and Control. The European Union summary report on trends of zoonoses, zoonotic agents and food-borne outbreaks in 2014. EFSA Journal 2015; 13: 4329. doi: 10.2903/j.efsa.2015.4329.Google Scholar
4. Su, LH, Chiu, CH. Salmonella: clinical importance and evolution of nomenclature. Chang Gun Medical Journal 2007; 30: 210219.Google Scholar
5. Chen, HM, et al. Nontyphoidal Salmonella infection: microbiology, clinical features, and antimicrobial therapy. Pediatric Neonatology 2013; 54: 147152. doi: 10.1016/j.pedneo.2013.01.010.Google Scholar
6. Deen, J, et al. Community- acquired bacterial bloodstream infections in developing countries in south and southeast Asia: a systematic review. Lancet Infectious Diseases 2012; 12: 480487. doi: 10.1016/S1473-3099(12)70028-2.CrossRefGoogle ScholarPubMed
7. Uzzau, S, et al. Host adapted serotypes of Salmonella enterica . Epidemiology and Infection 2000; 125: 229255.CrossRefGoogle ScholarPubMed
8. Wilcock, BP, Schwartz, K. Salmonellosis. In: Leman, AD, Straw, BE, Mengeling, WE, D'Allaire, S, Taylor, DJ, eds. Diseases of swine, 7th edn. Ames: Iowa State University Press, 1992, pp. 570583.Google Scholar
9. Gray, JT, et al. Natural transmission of Salmonella choleraesuis in swine. Applied and Environmental Microbiology 1996; 62: 141146.CrossRefGoogle ScholarPubMed
10. Fedorka-Cray, PJ, Gray, JT, Wray, C. Salmonella infections in pigs. In: Wray, C, Wray, A, eds. Salmonella in Domestic Animals. Wallingford: CAB International, 2000, pp. 191207.CrossRefGoogle Scholar
11. Davies, RH, et al. National survey for Salmonella in pigs, cattle and sheep at slaughter in Great Britain (1999–2000). Journal of Applied Microbiology 2004; 96: 750760.Google Scholar
12. Pedersen, K, et al. Reappearance of Salmonella serovar Choleraesuis var. Kunzendorf in Danish pig herds. Veterinary Microbiology 2015; 176: 282291. doi: 10.1016/j.vetmic.2015.01.004.Google Scholar
13. Nollet, N, et al. Risk factors for the herd-level bacteriologic prevalence of Salmonella in Belgian slaughter pigs. Preventive Veterinary Medicine 2004; 65: 6375. doi: 10.1016/j.prevetmed.2004.06.009.CrossRefGoogle ScholarPubMed
14. Argüello, H, et al. Prevalence, serotypes and resistance patterns of Salmonella in Danish pig production. Research in Veterinary Science 2013; 95: 334342. doi: 10.1016/j.rvsc.2013.04.001.CrossRefGoogle ScholarPubMed
15. Nathues, C, et al. Campylobacter spp., Yersinia enterocolitica, and Salmonella enterica and their simultaneous occurrence in German fattening pig herds and their environment. Journal of Food Protection 2013; 76: 17041711. doi: 10.4315/0362-028X.JFP-13-076.CrossRefGoogle ScholarPubMed
16. Wales, A, et al. Investigation of the distribution of Salmonella within an integrated pig breeding and production organisation in the United Kingdom. ISRN Veterinary Science 2013. Published online: 20 November 2013. doi: 10.1155/2013/943126.Google Scholar
17. García-Fierro, R, et al. Antimicrobial drug resistance and molecular typing of Salmonella enterica serovar Rissen from different sources. Microbial Drug Resistance 2016; 22: 211217. doi: 10.1089/mdr.2015.0161.Google Scholar
18. Boyen, F, et al. Non-typhoidal Salmonella infections in pigs: a closer look at epidemiology, pathogenesis and control. Veterinary Microbiology 2008; 130: 119. doi: 10.1016/j.vetmic.2007.12.017.Google Scholar
19. Fedorka-Cray, PJ, et al. Alternate routes of invasion may affect pathogenesis of Salmonella typhimurium in swine. Infection and Immunity 1995; 63: 26582664.Google Scholar
20. Hurd, HS, et al. Estimation of the Salmonella enterica prevalence in finishing swine. Epidemiology and Infection 2004; 132: 127135.Google Scholar
21. Hurd, HS, et al. Salmonella enterica infections in market swine before and after transport and holding. Applied and Environmental Microbiology 2002; 68: 23762381.CrossRefGoogle ScholarPubMed
22. European Food Safety Authority. Risk assessment and mitigation options for Salmonella in pig production. EFSA Journal 2006; 341: 1131. doi: 10.2903/j.efsa.2006.341.Google Scholar
23. Côté, S, et al. Distribution of Salmonella in tissues following natural and experimental infection in pigs. Canadian Journal of Veterinary Research 2004; 68: 241248.Google Scholar
24. Visscher, CF, et al. Serodiversity and serological as well as cultural distribution of Salmonella on farms and in abattoirs in Lower Saxony, Germany. International Journal of Food Microbiology 2011; 146: 4451. doi: 10.1016/j.ijfoodmicro.2011.01.038.Google Scholar
25. Merialdi, G, et al. Longitudinal study of Salmonella infection in Italian farrow-to-finish swine herds. Zoonoses and Public Health 2008; 55: 222226. doi: 10.1111/j.1863-2378.2008.01111.x.Google Scholar
26. Magistrali, C, et al. Contamination of Salmonella spp. in a pig finishing herd, from the arrival of the animals to the slaughterhouse. Research in Veterinary Science 2008; 85: 204207. doi: 10.1016/j.rvsc.2007.12.002.CrossRefGoogle Scholar
27. Denis, M, et al. Distribution of serotypes and genotypes of Salmonella enterica species in French pig production. Veterinary Record 2013; 173: 370. doi: 10.1136/vr.101901.Google Scholar
28. European Food Safety Authority. Report of the Task Force on Zoonoses Data Collection on the Analysis of the baseline survey on the prevalence of Salmonella in slaughter pigs, in the EU, 2006–2007 – Part A: Salmonella prevalence estimates. EFSA Journal 2008; 8: 135r, 111 pp. doi: 10.2903/j.efsa.2008.135r.Google Scholar
29. European Food Safety Authority. Analysis of the baseline survey on the prevalence of Salmonella in holdings with breeding pigs in the EU, 2008, Part A: Salmonella prevalence estimates. EFSA Journal 2009; 7: 1377. doi: 10.2903/j.efsa.2009.1377.Google Scholar
30. Funk, J, Davies, PR, Nichols, MA. The effect of sample weight on detection of Salmonella enterica in swine feces. Journal of Veterinary Diagnostic Investigation 2000; 12: 412418.Google Scholar
31. Pires, AF, Funk, JA, Bolin, CA. Longitudinal study of Salmonella shedding in naturally infected finishing pigs. Epidemiology and Infection 2013; 141: 19281936. doi: 10.1017/S0950268812002464.Google Scholar
32. Sauli, I, et al. Estimating the probability and level of contamination with Salmonella of feed for finishing pigs produced in Switzerland – the impact of the production pathway. International Journal of Food Microbiology 2005; 100: 289310. doi: 10.1016/j.ijfoodmicro.2004.10.026.Google Scholar
33. Prohászka, L, et al. The role of intestinal volatile fatty acids in the Salmonella shedding of pigs. Zentralblatt für Veterinärmedizin Reihe B 1990; 37: 570574.Google Scholar
34. Van der Wolf, PJ, et al. Administration of acidified drinking water to finishing pigs in order to prevent Salmonella infections. Veterinary Quarterly 2001; 23: 121125. doi: 10.1080/01652176.2001.9695097.CrossRefGoogle ScholarPubMed
35. Van Winsen, RL et al. Mechanism of Salmonella reduction in fermented pig feed. Journal of the Science of Food and Agriculture 2000; 83: 342346.Google Scholar
36. Wilkins, W, et al. Distribution of Salmonella serovars in breeding, nursery, and grow-to-finish pigs, and risk factors for shedding in ten farrow-to-finish swine farms in Alberta and Saskatchewan. Canadian Journal of Veterinary Research 2010; 74: 8190.Google ScholarPubMed
37. Visscher, CF, et al. Effects of feed particle size at dietary presence of added organic acids on caecal parameters and the prevalence of Salmonella in fattening pigs on farm and at slaughter. Journal of Animal Physiology and Animal Nutrition 2009; 93: 423430. doi: 10.1111/j.1439-0396.2008.00821.x.CrossRefGoogle ScholarPubMed
38. Missotten, JAM, et al. Fermented liquid feed for pigs: an ancient technique for the future. Journal of Animal Science and Biotechnology 2015; 6: 4. Published online 20 January 2015. doi: 10.1186/2049-1891-6-4.Google Scholar
39. O'Connor, AM, et al. Feeding management practices and feed characteristics associated with Salmonella prevalence in live and slaughtered market-weight finisher swine: a systematic review and summation of evidence from 1950 to 2005. Preventive Veterinary Medicine 2008; 87: 213228. doi: 10.1016/j.prevetmed.2008.06.017.Google Scholar
40. Lo Fo Wong, DMA, et al. Herd level risk factors for subclinical Salmonella infection in European finishing-pig herds. Preventive Veterinary Medicine 2004; 62: 253266. doi: 10.1016/j.prevetmed.2004.01.001.Google Scholar
41. García-Feliz, C, et al. Herd-level risk factors for faecal shedding of Salmonella enterica in Spanish fattening pigs. Preventive Veterinary Medicine 2009; 91: 130136. doi: 10.1016/j.prevetmed.2009.05.011.Google Scholar
42. Gotter, V, et al. Main risk factors for Salmonella-infections in pigs in north-western Germany. Preventive Veterinary Medicine 2012; 106: 301307. doi: 10.1016/j.prevetmed.2012.03.016.CrossRefGoogle ScholarPubMed
43. Fosse, J, Seegers, H, Magras, C. Prevalence and risk factors for bacterial food-borne zoonotic hazards in slaughter pigs: a review. Zoonoses and Public Health 2009; 56: 2954. doi: 10.1111/j.1863-2378.2008.01185.x.Google Scholar
44. Marin, C, Hernandiz, A, Lainez, M. Biofilm development capacity of Salmonella strains isolated in poultry risk factors and their resistance against disinfectants. Poultry Science 2009; 88: 424431. doi: 10.3382/ps.2008-00241.Google Scholar
45. Rajić, A, et al. Salmonella infections in ninety Alberta swine finishing farms: serological prevalence, correlation between culture and serology, and risk factors for infection. Foodborne Pathogens and Disease 2007; 4: 169177. doi: 10.1089/fpd.2006.0073.Google Scholar
46. Rasschaert, G, et al. Effect of farm type on within-herd Salmonella prevalence, serovar distribution, and antimicrobial resistance. Journal of Food Protection 2012; 75: 859866. doi: 10.4315/0362-028X.JFP-11-469.Google Scholar
47. Nollet, N, et al. Salmonella in sows: a longitudinal study in farrow-to-finish pig herds. Veterinary Research 2005; 36: 645656. doi: 10.1051/vetres:2005022.CrossRefGoogle ScholarPubMed
48. Dors, A, et al. Prevalence and risk factors for Lawsonia intracellularis, Brachyspira hyodysenteriae and Salmonella spp. in finishing pigs in Polish farrow-to-finish swine herds. Polish Journal of Veterinary Sciences 2015; 18: 825831. doi: 10.1515/pjvs-2015-0107.CrossRefGoogle ScholarPubMed
49. Rostagno, MH, Eicher, SD, Lay, DC. Jr Does pre-slaughter stress affect pork safety risk? In: Proceedings of the 21st International Pig Veterinary Society (IPVS) Congress, July 18–21, 2010, Vancouver, Canada. p. 176.Google Scholar
50. Martín-Peláez, S, et al. Different feed withdrawal times before slaughter influence caecal fermentation and faecal Salmonella shedding in pigs. Veterinary Journal 2009; 182: 469473. doi: 10.1016/j.tvjl.2008.08.002.Google Scholar
51. Bonardi, S, et al. Detection of Salmonella enterica in pigs at slaughter and comparison with human isolates in Italy. International Journal of Food Microbiology 2016; 218: 4450. doi: 10.1016/j.ijfoodmicro.2015.11.005.Google Scholar
52. Hurd, HS, Gailey, JK, Rostagno, MH. Rapid infection in market swine occurs following exposure to a Salmonella contaminated environment. American Journal of Veterinary Research 2001; 62: 11941197.Google Scholar
53. Dickson, JS, Hurd, HS, Rostagno, MH. Salmonella in the pork production chain. National Pork Board /American Meat Science Association Fact Sheet. Published online: 11 December 2015.Google Scholar
54. Anon. Regulation (EC) No 1099/2009 of the Council of 24 September 2009 on the protection of animals at the time of killing. Official Journal of the European Union 2009; L 303: 130.Google Scholar
55. De Busser, EV, et al. Salmonella control in live pigs and at slaughter. Veterinary Journal 2013; 196: 2027. doi: 10.1016/j.tvjl.2013.01.002.Google Scholar
56. Schütte, A, et al. Effect of different kinds of showering in lairage on physiological and meat quality parameters, taking climate circumstances into account. Landbauforschung Völkenrode Sonderheft 1996; 166: 181201.Google Scholar
57. Rossel, R, Jouffe, L, Belceil, P-A. Analysis of factors associated with Salmonella isolation on pork carcass using Bayesian networks. Journées de la Recherche Porcine 2009; 41: 4348.Google Scholar
58. Bonardi, S, et al. Influence of pig skin in Salmonella contamination of pig carcasses and cutting lines in an Italian slaughterhouse. Italian Journal of Food Safety 2016; 5: 6568. doi: 10.4081/ijfs.2016.5654.CrossRefGoogle Scholar
59. Gomes-Neves, E, et al. Salmonella cross-contamination in swine abattoirs in Portugal: carcasses, meat and meat handlers. International Journal of Food Microbiology 2012; 157: 8287. doi: 10.1016/j.ijfoodmicro.2012.04.015.Google Scholar
60. Marier, EA, et al. Abattoir based survey of Salmonella in finishing pigs in the United Kingdom 2006–2007. Preventive Veterinary Medicine 2014; 117: 542553. doi: 10.1016/j.prevetmed.2014.09.004.Google Scholar
61. Vieira-Pinto, M, Temudo, P, Martins, C. Occurrence of Salmonella in the ileum, ileocolic lymph nodes, tonsils, mandibular lymph nodes and carcasses of pigs slaughtered for consumption. Journal of Veterinary Medicine. B, Infectious Diseases and Veterinary Public Health 2005; 52: 476481. doi: 10.1111/j.1439-0450.2005.00892.x.Google Scholar
62. De Busser, EV, et al. Detection and characterization of Salmonella in lairage, on pig carcasses and intestines in five slaughterhouses. International Journal of Food Microbiology 2011; 145: 279286. doi: 10.1016/j.ijfoodmicro.2011.01.009.Google Scholar
63. Powell, LF, et al. A prevalence study of Salmonella spp., Yersinia spp., Toxoplasma gondii and porcine reproductive and respiratory syndrome virus in UK pigs at slaughter. Epidemiology and Infection 2016; 144: 15381549. doi: 10.1017/S0950268815002794.Google Scholar
64. Bonardi, S, et al. Prevalence, characterization and antimicrobial susceptibility of Salmonella enterica and Yersinia enterocolitica in pigs at slaughter in Italy. International Journal of Food Microbiology 2013; 163: 248257. doi: 10.1016/j.ijfoodmicro.2015.11.005.CrossRefGoogle ScholarPubMed
65. Smid, JH, et al. Quantifying the sources of Salmonella on dressed carcasses of pigs based on serovar distribution. Meat Science 2014; 96: 14251431. doi: 10.1016/j.meatsci.2013.12.002.Google Scholar
66. Argüello, H, et al. Role of slaughtering in Salmonella spreading and control in pork production. Journal of Food Protection 2013; 76: 899911. doi: 10.4315/0362-028X. JFP-12-404.Google Scholar
67. Duggan, SJ, et al. Tracking the Salmonella status of pigs and pork from lairage through the slaughter process in the Republic of Ireland. Journal of Food Protection 2010; 73: 21482160.Google Scholar
68. van Hoek, AH, et al. A quantitative approach towards a better understanding of the dynamics of Salmonella spp. in a pork slaughter-line. International Journal of Food Microbiology 2012; 153: 4552. doi: 10.1016/j.ijfoodmicro.2012.04.015.Google Scholar
69. Botteldoorn, N, et al. Phenotypic and molecular typing of Salmonella strains reveals different contamination sources in two commercial pig slaughterhouses. Applied and Environmental Microbiology 2004; 70: 53055314. doi: 10.1128/AEM.70.9.5305-5314.2004.CrossRefGoogle ScholarPubMed
70. Bolton, DJ, Ivory, C, McDowell, D. A study of Salmonella in pigs from birth to carcass: serotypes, genotypes, antibiotic resistance and virulence profiles. International Journal of Food Microbiology 2013; 160: 298303. doi: 10.1016/j.ijfoodmicro.2012.11.001.Google Scholar
71. Anon. Regulation (EC) 2015/1474 of 27 August concerning the use of recycled hot water to remove microbiological surface contamination from carcasses. Official Journal of the European Union 2015; L 225: 79.Google Scholar
72. Gebreyes, WA, et al. Salmonella enterica serovars from pigs on farms and after slaughter and validity of using bacteriologic data to define herd Salmonella status. Journal of Food Protection 2004; 67: 691697.Google Scholar
73. European Food Safety Authority, European Centre for Disease Prevention and Control. The European Union summary report on trends of zoonoses, zoonotic agents and food-borne outbreaks in 2013. EFSA Journal 2015; 13: 3991. doi: 10.2903/j.efsa.2015.3991.Google Scholar
74. Hauser, E, et al. Pork contaminated with Salmonella enterica serovar 4,[5],12:i:-, an emerging health risk for humans. Applied and Environmental Microbiology 2010; 76: 46014610. doi: 10.1128/AEM.02991-09.Google Scholar
75. Lucarelli, C, et al. Evidence for a second genomic island conferring multidrug resistance in a clonal group of strains of Salmonella enterica serovar Typhimurium and its monophasic variant circulating in Italy, Denmark, and the United Kingdom. Journal of Clinical Microbiology 2010; 48: 21032109. doi: 10.1128/JCM.01371-09.Google Scholar
76. Anon. Regulation (EC) No 2073/2005 of the Commission of 15 November 2005 on microbiological criteria for foodstuff. Official Journal of the European Union 2005; L 338: 126.Google Scholar
77. Anon. Regulation (EU) of the Commission No 217/2014 of 7 March 2014 amending Regulation (EC) No 2073/2005 as regards Salmonella in pig carcases. Official Journal of the European Union 2014; L 69: 9394.Google Scholar
78. De Knegt, LV, Pires, SM, Hald, T. Attributing foodborne salmonellosis in humans to animal reservoirs in the European Union using a multi-country stochastic model. Epidemiology and Infection 2015; 143: 11751186. doi: 10.1017/S0950268814001903.Google Scholar
79. Cohen, JL, Bartlett, JA, Corey, R. Extra-intestinal manifestations of Salmonella infections. Medicine (Baltimore) 1987; 66: 349388.Google Scholar
80. Paranthaman, K, et al. Emergence of a multidrug-resistant (ASSuTTm) strain of Salmonella enterica serovar Typhimurium DT120 in England in 2011 and the use of multiple-locus variable-number tandem-repeat analysis supporting outbreak investigations. Foodborne Pathogens and Disease 2013; 10: 850855. doi: 10.1089/fpd.2013.1513.CrossRefGoogle ScholarPubMed
81. Lettini, AA, et al. Characterization of an unusual Salmonella phage type DT7a and report of a foodborne outbreak of salmonellosis. International Journal of Food Microbiology 2014; 189: 1117. doi: 10.1016/j.ijfoodmicro.2014.07.021.Google Scholar
82. Barco, L, et al. Molecular characterization of Salmonella enterica serovar 4,[5],12:i:- DT193 ASSuT strains from two outbreaks in Italy. Foodborne Pathogens and Disease 2014; 11: 138144. doi: 10.1089/fpd.2013.1626.Google Scholar
83. Leekitcharoenphon, P, et al. Evaluation of whole genome sequencing for outbreak detection of Salmonella enterica . PLoS ONE 2014; 9: e87991. Published on line: 4 February 2014. doi.org/10.1371/journal.pone.0087991.CrossRefGoogle ScholarPubMed
84. Kérouanton, A, et al. Genetic diversity and antimicrobial resistance profiles of Salmonella enterica serotype Derby isolated from pigs, pork, and humans in France. Foodborne Pathogens and Disease 2013; 10: 977984. doi: 10.1089/fpd.2013.1537.Google Scholar
85. Kérouanton, A, et al. First complete genome sequence of a Salmonella enterica subsp. enterica serovar Derby strain associated with pork in France. Genome Announcements 2015; 3: e00853–15. Published online: 30 July 2015. doi: 10.1128/genomeA.00853-15.Google Scholar
86. Gallati, C, et al. Characterization of Salmonella enterica subsp. enterica serovar 4,[5],12:i:- clones isolated from human and other sources in Switzerland between 2007 and 2011. Foodborne Pathogens and Disease 2013; 10: 549554. doi: 10.1089/fpd.2012.1407.CrossRefGoogle Scholar
87. Sandt, CH, et al. A comparison of non-typhoidal Salmonella from humans and food animals using pulsed-field gel electrophoresis and antimicrobial susceptibility patterns. PLoS ONE 2013; 8: e77836. Published online: 30 October 2013. doi: 10.1371/journal.pone.0077836.CrossRefGoogle ScholarPubMed
88. Arnedo-Pena, A, et al. An outbreak of monophasic and biphasic Salmonella Typhimurium, and Salmonella Derby associated with the consumption of dried pork sausage in Castellon (Spain). Enfermedades Infecciosas Microbiología Clínica 2016; 34: 544550. doi: 10.1016/j.eimc.2015.11.016.Google Scholar
89. Wójcik, OP, et al. Salmonella Typhimurium outbreak associated with smoked pork tenderloin in Denmark, January to March 2011. Scandinavian Journal of Infectious Diseases 2012; 44: 903908. doi: 10.3109/00365548.2012.693196.Google Scholar
90. Kuhn, KG, et al. A long-lasting outbreak of Salmonella Typhimurium U323 associated with several pork products, Denmark, 2010. Epidemiology and Infection 2013; 141: 260268. doi: 10.1017/S0950268812000702.Google Scholar
91. Kuhn, K, et al. An outbreak of Salmonella Typhimurium traced back to salami, Denmark, April to June 2010. Euro Surveillance 2011; 16. Published online: 12 May 2011.Google Scholar
92. Luzzi, I, et al. An Easter outbreak of Salmonella Typhimurium DT 104A associated with traditional pork salami in Italy. Euro Surveillance 2007; 12: 149152.Google Scholar
93. Alt, K, et al. Outbreak of uncommon O4 non-agglutinating Salmonella typhimurium linked to minced pork, Saxony-Anhalt, Germany, January to April 2013. PLoS ONE 2015; 10: e0128349. Published online: 1 June 2015. doi: 10.1371/journal.pone.0128349.Google Scholar
94. Frank, C, et al. Catering risky food to those at-risk: Salmonella Derby outbreak among the elderly in Berlin, December 2013/January 2014. In: Proceedings of the European Scientific Conference on Applied Infectious Disease, Stockholm; 5–7 November 2014.Google Scholar
95. European Food Safety Authority. Scientific opinion of the Panel on Biological Hazards on a request from the Health and Consumer Protection, Directorate General, European Commission on Microbiological Risk Assessment in feeding stuffs for food producing animals. EFSA Journal 2008; 720: 184. doi: 10.2903/j.efsa.2008.720.Google Scholar
96. Mueller-Doblies, D, Speed, K, Davies, RH. A retrospective analysis of Salmonella serovars isolated from pigs in Great Britain between 1994 and 2010. Preventive Veterinary Medicine 2013; 110: 447455. doi: 10.1016/j.prevetmed.2013.02.023.CrossRefGoogle ScholarPubMed
97. Gomes-Neves, E, et al. Clinically relevant multidrug resistant Salmonella enterica in swine and meat handlers at the abattoir. Veterinary Microbiology 2014; 168: 229233. doi: 10.1016/j.vetmic.2013.10.017.Google Scholar
98. Korsak, N, et al. Salmonella contamination of pigs and pork in an integrated pig production system. Journal of Food Protection 2003; 66: 11261133.Google Scholar
99. Pornsukarom, S, et al. Comparative phenotypic and genotypic analyses of Salmonella Rissen that originated from food animals in Thailand and United States. Zoonoses and Public Health 2015; 62: 151158. doi: 10.1111/zph.12144.Google Scholar
100. Antunes, P, et al. Leakage of emerging clinically relevant multidrug-resistant Salmonella clones from pig farms. Journal of Antimicrobial Chemotherapy 2011; 66: 20282032. doi: 10.1093/jac/dkr228.Google Scholar
101. Borch, E, Nesbakken, T, Christensen, H. Hazard identification in swine slaughter with respect to foodborne bacteria. International Journal of Food Microbiology 1996; 30: 925.Google Scholar
102. Baptista, FM, Dahl, J, Nielsen, LR. Factors influencing Salmonella carcass prevalence in Danish pig abattoirs. Preventive Veterinary Medicine 2010; 95: 231238. doi: 10.1016/j.prevetmed.2010.04.007.CrossRefGoogle ScholarPubMed
103. Anon. Regulation (EC) No 2160/2003 of the European Parliament and of the Council of 17 November 2003 on the control of Salmonella and other specified food-borne zoonotic agents. Official Journal of the European Union 2003; L 325: 115.Google Scholar
104. Bollaerts, K, et al. Evaluation of scenarios for reducing human salmonellosis through household consumption of fresh minced pork meat. Risk Analysis 2010; 30: 853865. doi: 10.1111/j.1539-6924.2010.01368.x.Google Scholar
105. European Food Safety Authority. Scientific opinion on a quantitative microbiological risk assessment of Salmonella in slaughter and breeder pigs. EFSA Journal 2010; 8: 1547. doi: 10.2903/j.efsa.2010.1547.Google Scholar
106. Merle, R, et al. Serological Salmonella monitoring in German pig herds: results of the years 2003–2008. Preventive Veterinary Medicine 2011; 99: 229233. doi: 10.1016/j.prevetmed.2011.02.007.CrossRefGoogle ScholarPubMed
107. Alban, L, Stege, H, Dahl, J. The new classification system for slaughter-pig herds in the Danish Salmonella surveillance-and-control program. Preventive Veterinary Medicine 2002; 53: 133146.Google Scholar
108. Blaha, T. Bisherige Erkenntnisse aus dem QS Salmonellenmonitoring-und–reduzierungsprogramm. Deutsche Tierarztliche Wochenschrift 2004; 111: 324326.Google Scholar
Figure 0

Table 1. Prevalence of Salmonella in MLN, faeces, tonsils and carcasses of pigs at slaughter in different EU countries

Figure 1

Table 2. Prevalence of Salmonella in pig carcasses at slaughter in 2014

Figure 2

Fig. 1. Salmonella amplification and control points in the pork production system.