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Trichinella infection in Serbia from 2011 to 2020: a success story in the field of One Health

Published online by Cambridge University Press:  19 January 2023

Sasa Vasilev*
Affiliation:
National Reference Laboratory for Trichinellosis, Institute for the Application of Nuclear Energy – INEP, University of Belgrade, Belgrade, Serbia
Ivana Mitic
Affiliation:
National Reference Laboratory for Trichinellosis, Institute for the Application of Nuclear Energy – INEP, University of Belgrade, Belgrade, Serbia
Milorad Mirilovic
Affiliation:
Faculty of Veterinary Medicine, University of Belgrade, Belgrade, Serbia
Dragana Plavsa
Affiliation:
Institute of Public Health of Serbia – Dr Milan Jovanovic Batut, Belgrade, Serbia
Emina Milakara
Affiliation:
Ministry of Agriculture, Forestry and Water Management of Serbia, Veterinary Directorate, Belgrade, Serbia
Budimir Plavsic
Affiliation:
World Organization for Animal Health (OIE), Paris, France
Ljiljana Sofronic-Milosavljevic
Affiliation:
National Reference Laboratory for Trichinellosis, Institute for the Application of Nuclear Energy – INEP, University of Belgrade, Belgrade, Serbia
*
Author for correspondence: Sasa Vasilev, E-mail: [email protected]
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Abstract

In Serbia, modern pork production systems with implemented control measures, including the detection of Trichinella larvae in meat (ISO18743), have eliminated farmed pork from pigs slaughtered at abattoirs as a source of trichinellosis. Epidemiological data from 2011 to 2020 indicate that the number of human cases and the number of infected domestic pigs has decreased significantly. Over the years, pork was the most frequent source of human infection. Cases generally occurred in small family outbreaks, and the infection was linked to consumption of raw or undercooked pork from backyard pigs. In most of the outbreaks, T. spiralis was the aetiological agent of infection, but in 2016, a large outbreak was caused by consumption of uninspected wild boar meat containing T. britovi larvae. To achieve safe pork, it is important that consumers of pork from animals raised in backyard smallholdings and of wild game meat are properly educated about the risks associated with consumption of untested meat. Laboratories conducting Trichinella testing should have a functional quality assurance system to ensure competency of analysts and that accurate and repeatable results are achieved. Regular participation in proficiency testing is needed.

Type
Original Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Introduction

Parasitic nematodes from the genus Trichinella are causative agents for the zoonotic disease trichinellosis, which is a serious human health risk. This genus comprises 10 species: T. spiralis, T. nativa, T. britovi, T. murrelli, T. nelsoni, T. patagoniensis and T. chanchalensis (encapsulating species), T. pseudospiralis, T. papuae and T. zimbabwensis (non-encapsulated species) as well as three genotypes (Trichinella T6, T8 and T9) [Reference Pozio, Zarlenga and Bruschi1]. These nematodes are distributed worldwide and infect a broad variety of species while transmitting in both domestic and sylvatic cycles [Reference Pozio and Murrell2]. Consequently, Trichinella spp. infections in animals induce a food safety problem since humans acquire trichinellosis by the consumption of raw or undercooked meat of infected animals. In the EU, Trichinella spp. infection is well controlled since all Trichinella-susceptible animals intended for human consumption are required to be tested for the presence of Trichinella larvae in the muscles (Commission Implementing Regulation (EU) 2015/1375). Currently, trichinellosis is successfully kept under control in Serbia, as only individual cases occur annually [Reference Mitic3]. Communication between medical practitioners, public health and veterinary authorities (One Health concept) contributed to this success. In Serbia, meat inspection to detect Trichinella larvae is mandatory, by using the digestion method (for meat from farmed domestic pigs in abattoirs) or either the digestion method or trichinelloscopy (for meat intended for private consumption and from backyard pigs on smallholdings). For testing meat from wild boars, only the digestion method is allowed. The aims of this study were to determine the prevalence of Trichinella infection in domestic pigs and wild boars in Serbia during 2011–2020 and to evaluate the status of human disease caused by Trichinella spp. in the same period.

Materials and methods

Data sources

Epidemiological and parasitological data regarding animal and human Trichinella infections in Serbia for the period 2011–2020 were collected and analysed.

Annual reports issued by the Veterinary Directorate of the Republic of Serbia, containing data on the number of slaughtered, inspected and infected pigs, as well as the number of hunted and infected wild boars, were used as the source of information for estimating the prevalence of Trichinella infection in animals. The Veterinary Directorate also provided data on backyard pigs from smallholdings for 2020.

Data pertaining to the annual rate of human trichinellosis, i.e. the number of outbreaks (including number of illnesses for each outbreak) and individual cases, as well as the sources of infection, were provided by the Institute of Public Health of Serbia Milan Jovanovic Batut, Serbia.

Statistical analyses

We conducted a descriptive statistical analysis of epidemiological variables collected for 2011–2020 including traceback investigation information. We conducted a trend analysis using a linear trend and regression analysis. For comparing frequencies, the Chi-square (χ 2) test was used. The differences in results were considered as statistically significant at the level of P < 0.05. Statistical analysis of the obtained results was carried out using statistical software GraphPad Prism version 6.00 for Windows (GraphPad, San Diego, CA, USA) and Microsoft Office Excel 2010 (Microsoft Corp., Redmond, WA, USA).

Results

Trichinella infection in domestic pigs

The average number of pigs slaughtered for human consumption, i.e. inspected pigs, in Serbia was, on average, 2 172 165 per year in the last 10-year period (minimum in 2012 – 1 507 182, and maximum in 2019 – 2 529 564). Data regarding the number of inspected and infected pigs for 2011–2020 are summarised in Table 1. During these years, an 11-fold reduction in the prevalence of Trichinella infection in pigs was observed. In 2011, Trichinella larvae in meat (muscle) were detected in 523 carcasses of inspected pigs, and the number constantly decreased during the next few years, reaching the lowest number of 47 infected carcasses in 2020 (statistically significant difference, P < 0.0001). The rate of infection in farmed domestic pigs in Serbia in 2020 was 0.002%, indicating successful maintenance of a low infection prevalence, which was quite reduced compared to the rates in 2011–2013 (the prevalence of 0.026% in 2011 trended downwards in the next 2-year period, reaching the prevalence of 0.014% in 2013). The prevalences calculated for 2014–2017 corresponded to the prevalences that were measured in Serbia in the years before 1980 (<0.009%).

Table 1. Trichinella infection in pigs in Serbia, 2011–2020

During 2011–2020, Trichinella infection in pigs was detected in 23 out of 25 districts in Serbia (excluding Kosovo, because no data were available). Prevalences on average above 0.05% were found in Branicevo, Bor and Pcinja districts (Fig. 1), while for the other districts, prevalences on average during 2011–2020 were from 0.00% to 0.022%.

Fig. 1. Geographical distribution and average prevalence of Trichinella infection in domestic pigs in 25 districts in Serbia, 2011–2020. Dark grey – districts with an average prevalence above 0.05%. Light grey – districts with an average prevalence of 0.01–0.03%. White – districts with an average prevalence under 0.01%. Black – no data available. Image source: https://en.wikipedia.org/wiki/Districts_of_Serbia#/media/File:Districts_of_Serbia.png.

Improvements in pig rearing systems and the implementation of control measures [Reference Zivojinovic4Reference Plavsic7] have eliminated Trichinella infection in pigs from controlled housing, and these farms now (2020) have no positive animals. In 2020, all Trichinella-positive pigs in Serbia were from backyard smallholdings with uncontrolled housing conditions (Table 2).

Table 2. Number of Trichinella-infected pigs in Serbia in 2020, classified according to housing conditions

Trichinella infection in humans

During 2011–2020, a total of 699 cases of trichinellosis, on average 69.9 per year, without deaths, were reported in Serbia (Fig. 2). The calculated incidence of human infection at the country level for this period is shown in Figure 2. The annual incidence of trichinellosis varied from 2.68 to 0.16 per 100 000 inhabitants during those 10 years. In three districts in Serbia, outbreaks were reported in 5–6 years, in 13 districts, outbreaks occurred rarely and only in 1–3 years during the period, while there were no cases of infection in eight districts from 2011 to 2020 (Fig. 3).

Fig. 2. Number of trichinellosis cases per year in Serbia, 2011–2020, and trichinellosis incidence rate per 100 000 inhabitants, Serbia, 2011–2020. The trendline shows a steady decline in the incidence of human trichinellosis cases during this period. Trend line was derived by using the equation y = −0.1339x + 1.7127, based on data points in a Microsoft Excel chart, R 2 = 0.12519.

Fig. 3. Human Trichinella spp. infection in 25 districts of Serbia, 2011–2020. Dark grey – districts with trichinellosis cases registered in 4–6 years of the 10-year study period. Light grey – districts with trichinellosis cases registered in 1–3 years of the 10-year study period. White – districts with no trichinellosis cases registered in the study period. Black – no data available. Image source: https://en.wikipedia.org/wiki/Districts_of_Serbia#/media/File:Districts_of_Serbia.png.

A total of 54 outbreaks occurred in Serbia during 2011–2020 (Fig. 4). They were distributed equally between urban and rural areas. Epidemiological investigations performed in this period revealed that different sources of infection were responsible for the outbreaks of trichinellosis. The cause of the infection in 37 (88.09%) of the outbreaks was the consumption of pork, specifically raw or undercooked meat or meat products (homemade sausages and smoked meat). Other sources of infection included horse meat (1 outbreak, accounting for 2.38% of the outbreaks, and which took place in 2014) and wild boar meat (4 outbreaks, 9.52%, which took place in 2012, 2013, 2015 and 2016).

Fig. 4. Number of trichinellosis outbreaks per year in Serbia, 2011–2020. Trend line was derived by using the equation y = −0.9818x + 1984.3, based on data points in a Microsoft Excel chart, R 2 = 0.6605.

Trichinella infection in wild boars

Over the past 9 years (compared with the situation previously), parasitological testing by digestion of wild boars in game-handling establishments became more intensified and provided better insight into the prevalence and distribution of Trichinella in these animals (Fig. 5). The number of districts in which wild boars were hunted, tested and reported for Trichinella increased during the time (from 10 districts in 2012 up to all 25 districts in 2015), showing, nowadays, the reliable prevalence of Trichinella infection of 0.800% and 1.087% (in 2019 and 2020, respectively) and a prevalence range in the last 10 years from 2.32% in 2012 to 1.087% in 2020 (Table 3). Speciation of Trichinella was performed sporadically, and only the existence of T. britovi and T. spiralis infection was recognised among wild boars.

Fig. 5. Geographical distribution and average prevalence of Trichinella infection in wild boars in 25 districts in Serbia, 2011–2020. Dark grey – districts with an average prevalence above 3%. Grey – districts with an average prevalence of 1–3%. Light grey – districts with an average prevalence of 0.5–1%. White – districts with an average prevalence of under 0.5%. Black – no data available. Image source: https://en.wikipedia.org/wiki/Districts_of_Serbia#/media/File:Districts_of_Serbia.png.

Table 3. Trichinella infection in wild boars in Serbia for the period 2011–2020

Discussion

Trichinella infection in animals and humans in Serbia is still recognised as a health and animal husbandry problem, and some regions endemic for this zoonosis persist in the country, although a significant effort has been made to reduce the infection spreading and even to eliminate the parasite from the food chain. A promising trend of decreasing prevalence of Trichinella infection in pigs in Serbia was achieved during 2011–2020. The observed decrease in the infection rate in pigs could be attributed to implementation of animal health measures by veterinary services introduced from 2006 [Reference Sofronic-Milosavljevic8].

The prevalence of Trichinella infection in pigs is better than the prevalences seen during the 1980s, before the re-emergence of trichinellosis in this country [Reference Sofronic-Milosavljevic8Reference Cuperlovic, Djordjevic and Pavlovic10], and is better than the prevalences measured in 2001–2010 [Reference Sofronic-Milosavljevic8]. Although the prevalence of infection in domestic pigs has a downward trend, the efforts spent on reducing the spread of infection did not reduce the area where it is present, since Trichinella was detected in pigs over almost all of Serbia during 2011–2020. This observation implies that some further improvements to hygienic and sanitary conditions on farms and by households with backyard pigs should be implemented; this refers primarily to rat control programmes, since rats are considered as important vectors in the transmission of Trichinella infection to domestic pigs [Reference Mirilovic5, Reference Mirilovic6, Reference Sofronic-Milosavljevic8].

Along with the significant decline of the Trichinella prevalence in pigs, the number of human infection cases detected during last 10 years was also significantly lower than during 2001–2010. The distribution of human infection across the country corresponded to the geographical distribution of Trichinella infection in domestic backyard pigs that are now the main source of infection. This indicates that in districts where trichinellosis outbreaks occurred more frequently, there is inadequate awareness of the risk from consumption of untested wild boar meat and/or of meat from smallholdings with backyard and/or free-ranging pigs. In 2011–2020, the incidence of human cases was lower than during the previous decade, and altogether, the infection rates for the current 10-year period correlated with those detected during the 1980s. Since most of the outbreaks in Serbia were pork-related, it is worth mentioning that some of the observed causes of human infection, discussed previously by Sofronic-Milosavljevic et al. [Reference Sofronic-Milosavljevic8], still exist: the lack of knowledge that causes the reluctance of some individual farmers to provide meat samples for Trichinella testing to the veterinary service; and insufficient training and experience of a part of the veterinary inspection staff. New measures introduced by the Veterinary Directorate are additional education of veterinarians and certification for Trichinella testing. Also, from 2022, it is mandatory for all analysts testing meat for Trichinella to participate in proficiency testing (PT). For the first time in Serbia, PT for the detection of Trichinella larvae in meat by the magnetic stirrer method was organised in 2017 by NRLT INEP and according to the rules for PT providers. All participants (veterinary institutes) successfully passed the PT [Reference Vasilev, Ilic and Sofronic-Milosavljevic11]. In the years that followed, veterinary institutes achieved good results in PT organised in 2021 by NRLT INEP [Reference Vasilev12], and in 2022 by the Faculty of Veterinary Medicine, University of Belgrade (personal communication). The first Trichinella PT (NRLT INEP was the provider) for laboratories in export abattoirs was administered in 2022, and all participant laboratories successfully met the criteria (NRLT INEP data).

Molecular analysis for species identification has been sporadically performed on samples from infected Serbian pigs (at NRLT-INEP, and EURLP, ISS, Rome, Italy), revealing that only T. spiralis is present in domestic pigs in Serbia [Reference Sofronic-Milosavljevic8, NRLT-INEP data] out of the four Trichinella species (T. spiralis, T. britovi, T. pseudospiralis and T. nativa) identified in Europe so far [Reference Pozio13]. In the last 10 years, we have seen a significant improvement in the human incidence of trichinellosis, and the number of infected people is at the historically lowest level. In Serbia, the consumption of pork and products thereof originating from farms with controlled housing conditions, good rearing systems and all control measures implemented, including routine mandatory Trichinella testing by artificial digestion at public (belonging to veterinary institutes) and private (at veterinary stations and abattoirs) laboratories, does not present a risk for human infection. However, consumption of uninspected and undercooked meat originating from backyards and from locally slaughtered domestic pigs on private properties is considered an important risk for human infection with T. spiralis. Usually, the people involved in the processing of meat are affected, as are their families and people to whom infected meat is gifted, so most of the outbreaks are small family epidemics [Reference Sofronic-Milosavljevic8]. In addition, in Serbia, wild boars also present a serious risk of Trichinella spp. transmission to humans.

Despite the implementation of mandatory measures for controlling Trichinella in pork, small outbreaks of trichinellosis and some sporadic cases still occur in Serbia [Reference Zivojinovic4]. At the beginning of 2017, there were cases of imported (in personal luggage) untested, infected meat delicacies (as a gift) from Serbia to France and shared with about 47 relatives and friends, so a total of 20 cases of trichinellosis were reported − nine in France and 11 in Serbia [Reference Barruet14].

According to the number of human infection cases that have persisted over the last decade, it can be concluded that the above mentioned risk factors are still present in Serbia and that they continue to influence the occurrence of human cases. It is encouraging that the number of districts where trichinellosis occurred for 4–6 years during 2011–2020 decreased from 8 to 3 out of 25, and the number of districts with no human cases during the same period increased from 6 to 8. This distribution mostly corresponded to the geographical distribution of Trichinella infection in domestic pigs. This indicates that in districts where trichinellosis outbreaks occur more frequently, there is inadequate awareness of the risk of infection that can exist on smallholdings with backyard and/or free-ranging pigs. An exception was observed for Pcinja district, where there was a high prevalence of pig infection, but with no human cases detected during that period, which could be interpreted as being due to the effectiveness of control measures and public education conducted in this part of the country.

The One Health success in the field of Trichinella spp. control becomes evident when comparing the data presented here with those published for 2001–2010. In that decade, 2257 human infection cases, including three deaths, occurred. During that 10-year period, there were 144 outbreaks – 87 in the first 5 years and 57 in the second 5-year period [Reference Sofronic-Milosavljevic8]. In 2011–2020 (the current study), the total of 699 human cases in Serbia was three times lower than in the previous decade. Moreover, a total of 54 outbreaks were registered. In 2021, no cases of trichinellosis were registered, and in 2022, one outbreak with 26 confirmed cases of trichinellosis has been registered so far.

Meat and meat products offered to relatives and friends can be a source of infection with Trichinella when backyard pigs are raised without any compliance with hygienic rules and carcasses are not tested for Trichinella infection after slaughter [Reference Zhang15]. Over the years, pork was the most frequent source of trichinellosis in Serbia. Cases generally occurred within family outbreaks, and the risk derived from consumption of untested backyard pork [Reference Mitic3]. In most trichinellosis outbreaks in Serbia, T. spiralis was the aetiological agent of infection, but in 2016, a large outbreak was caused by consumption of wild boar meat containing T. britovi larvae [Reference Pavic16, Reference Dmitric17]. This was in spite of T. spiralis-infected pork meat being considered as the main source of the disease in humans. Alongside the reduction of the infection prevalence in pigs, it has become obvious that some cases of trichinellosis originate from the consumption of infected game meat. In 93% of outbreaks reported in 2011–2020, the source of infection was undercooked pork meat or meat products, while infected wild boar meat and horse meat were identified as the sources in 5% and 2% of outbreaks, respectively.

Wild boars are a significant reservoir of Trichinella spp. infection with consequent risk for human infection, and three outbreaks during the last decade were caused by the consumption of infected wild boar meat. Importantly, though, during the last decade, the inspection of wild boar meat was intensified, and now, wild boar meat from all 25 of the districts in Serbia is subjected to Trichinella inspection. The latest data have shown that all of the districts in Serbia host wild boars that have Trichinella infection. This implies that awareness of the necessity of meat inspection must be increased among hunters and potential consumers of wild boar meat.

The One Health approach to achieving Trichinella spp. infection control in Serbia is realised through the cooperation of all stakeholders at the local, regional and European levels. Medical practitioners who notice a case of trichinellosis immediately alert the Public Health Institute and the Veterinary authority, because effective communication, reporting and trace back system are necessary to identify the source of infection and prevent the spread of infection. The Veterinary Directorate in Serbia has introduced Trichinella control measures, such as systematic pig identification and registration systems, mandatory testing for Trichinella infection in all pigs slaughtered for human consumption (regardless of whether this is in abattoirs or on smallholdings), surveillance of wild boar populations and mandatory rodent control on pig farms all over the country. However, intensified supervision of the control measures was implemented in the areas with the highest infection prevalence [Reference Zivojinovic4, Reference Sofronic-Milosavljevic8]. All these measures had a One Health effect, reducing the number of infected animals, and consequently, reducing the number of trichinellosis cases, which was noticeable from year to year. The public is now informed about trichinellosis in local newspapers, radio stations and televisions, as well as on posters displayed in local veterinary stations, Public Health Institutes and health centres; these posters show proper sampling and transport of meat, along with the reasons why it is necessary to inspect meat for the presence of Trichinella spp. In addition to the activities described above at the Serbian (national) level, there is cooperation at the European level, and NRLT INEP is recognised in the network of parasitological laboratories of the Istituto Superiore di Sanità (ISS, Rome, Italy) (https://www.iss.it/en/web/guest/eurlp-chi-siamo).

As a result of improvements in pig production on farms and application of mandatory Trichinella inspection, the percentage of Trichinella-infected pigs decreased over the period 2001–2010 [Reference Sofronic-Milosavljevic8]. The trend of a reducing Trichinella prevalence in pigs continued in 2011–2020 with a statistically significant reduction, finally reaching the value of 0.002% in 2020.

Until 2009, T. spiralis was considered as the only species from the genus Trichinella that was present in domestic and wild animals in Serbia. Molecular analyses enabled the detection of T. britovi in red foxes and wolves for the first time in 2009 [Reference Cvetkovic18], in addition to the already confirmed presence of T. spiralis in wildlife [Reference Pozio13]. These analyses were the beginning of extensive study on Trichinella species in domestic pigs and wildlife. Notably, 6% of 469 animals hunted in Serbia between 1994 and 2013 were infected with Trichinella, showing that wild carnivores are important for Trichinella transmission in both the sylvatic and domestic cycles [Reference Klun19]. In Serbia, half (49.5%) of the examined wolves were infected with T. britovi [Reference Teodorovic20], while 16.5% of golden jackals were infected with Trichinella, of which more than 2/3 had T. spiralis and 1/3 had T. britovi [Reference Cirovic21]. These investigations have shown there is a risk that several species of wild animals can transmit Trichinella spp. to the backyard and free-ranging pig populations and, thus, contribute to the maintenance and spread of the parasite.

Conclusion

Although it is obvious that implementation of veterinary measures in Serbia has resulted in a considerable reduction of Trichinella infections in pigs, annually repeating outbreaks of trichinellosis indicate insufficient awareness of the risk of the disease and suggest that further efforts should be made in terms of education and trichinellosis prevention (using the One Health concept). To achieve safe food for consumers, it is important that: (1) consumers of meat from backyard pigs and hunters/consumers of wild game meat should be educated about the risk associated with consumption of untested meat; (2) laboratories conducting Trichinella testing should have a functional quality assurance system that ensures analyst competency and that accurate and repeatable results are achieved. Regular participation in PT is needed.

Acknowledgements

This work was supported by the Ministry of Education, Science and Technological Development of the Republic of Serbia (Contract No. 451-03-68/2022-14/200019).

Conflict of interest

None.

Disclaimer

The conclusions and opinions in this report are those of the authors and do not necessarily represent the official position of the Institute for Public Health of Serbia, the Ministry of Agriculture, Forestry and Water Management of the Republic of Serbia or the World Organization for Animal Health.

Data availability statement

This manuscript describes data obtained from the Veterinary Directorate and the Institute for Public Health of Serbia, and as such there is no broader dataset for release. Some data that support the findings of this study are publicly available from the Institute for Public Health of Serbia website. Any queries regarding the data can be directed to the corresponding author.

Footnotes

*

These authors contributed equally to this work.

References

Pozio, E and Zarlenga, DS (2021) Taxonomy of the Trichinella genus. In Bruschi, F (ed.), Trichinella and Trichinellosis. London, San Diego, Cambridge, Oxford: Academic press, pp. 3576.CrossRefGoogle Scholar
Pozio, E and Murrell, DK (2006) Systematics and epidemiology of Trichinella. Advances in Parasitology 63, 367439.CrossRefGoogle ScholarPubMed
Mitic, I et al. (2022) Trichinellosis in Serbia has become a rare event – one outbreak with pulmonary complications. Folia Parasitologica 69, 009.CrossRefGoogle ScholarPubMed
Zivojinovic, M et al. (2019) Trichinellosis in Serbia and possibilities to improve control measures. Veterinarski glasnik 73, 108115.CrossRefGoogle Scholar
Mirilovic, M et al. (2019) Economic evaluation of a program for monitoring and controlling Trichinella in pigs. Veterinarski glasnik 73, 116132.CrossRefGoogle Scholar
Mirilovic, M et al. (2019) Distribution of Trichinella infections in pigs and trichinellosis in humans in Serbia from 1994 to 2018. Veterinarski glasnik 73, 133143.CrossRefGoogle Scholar
Plavsic, B et al. (2009) Veterinary information management system (VIMS) in the process of notification and management of animal diseases. Acta Veterinaria 59, 99108.Google Scholar
Sofronic-Milosavljevic, LJ et al. (2013) Trichinella infection in Serbia in the first decade of the twenty-first century. Veterinary Parasitology 194, 145149.CrossRefGoogle ScholarPubMed
Djordjevic, M et al. (2003) Social, political, and economic factors responsible for the reemergence of trichinellosis in Serbia: a case study. Journal of Parasitology 89, 226231.CrossRefGoogle ScholarPubMed
Cuperlovic, K, Djordjevic, M and Pavlovic, S (2005) Re-emergence of trichinellosis in southeastern Europe due to political and economic changes. Veterinary Parasitology 132, 159166.CrossRefGoogle ScholarPubMed
Vasilev, S, Ilic, N and Sofronic-Milosavljevic, LJ (2019) First Serbian external quality assessment to detect Trichinella larvae in meat by the Magnetic Stirrer Method. Veterinarski glasnik 73, 168177.CrossRefGoogle Scholar
Vasilev, S et al. (2021) Serbian external quality assessment for Trichinella detection in meat in 2021 compared to 2017. Meat Technology 62, 140147.CrossRefGoogle Scholar
Pozio, E et al. (2009) Hosts and habitats of Trichinella spiralis and Trichinella britovi in Europe. International Journal for Parasitology 39, 7179.CrossRefGoogle ScholarPubMed
Barruet, R et al. (2020) A common source for a trichinellosis outbreak reported in France and Serbia in 2017. Euro Surveillance 25, 1900527.Google ScholarPubMed
Zhang, XZ et al. (2022) Epidemiology of trichinellosis in the People's Republic of China during 2009–2020. Acta Tropica 229, 106388.CrossRefGoogle ScholarPubMed
Pavic, S et al. (2020) Trichinella britovi outbreak: epidemiological, clinical, and biological features. Médecine et Maladies Infectieuses 50, 520524.CrossRefGoogle ScholarPubMed
Dmitric, M et al. (2018) Trichinella britovi in game meat linked to human trichinellosis outbreak in Serbia. Journal of Parasitology 104, 557559.CrossRefGoogle ScholarPubMed
Cvetkovic, J et al. (2001) First report of Trichinella britovi in Serbia. Acta Parasitologica 56, 232235.Google Scholar
Klun, I et al. (2019) Trichinella spp. in wild mesocarnivores in an endemic setting. Acta Veterinaria Hungarica 67, 3439.CrossRefGoogle Scholar
Teodorovic, V et al. (2014) The wolf (Canis lupus) as an indicator species for the sylvatic Trichinella cycle in the Central Balkans. Journal of Wildlife Diseases 50, 911915.CrossRefGoogle ScholarPubMed
Cirovic, D et al. (2015) A large-scale study of the Trichinella genus in the golden jackal (Canis aureus) population in Serbia. Veterinary Parasitology 212, 253256.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Trichinella infection in pigs in Serbia, 2011–2020

Figure 1

Fig. 1. Geographical distribution and average prevalence of Trichinella infection in domestic pigs in 25 districts in Serbia, 2011–2020. Dark grey – districts with an average prevalence above 0.05%. Light grey – districts with an average prevalence of 0.01–0.03%. White – districts with an average prevalence under 0.01%. Black – no data available. Image source: https://en.wikipedia.org/wiki/Districts_of_Serbia#/media/File:Districts_of_Serbia.png.

Figure 2

Table 2. Number of Trichinella-infected pigs in Serbia in 2020, classified according to housing conditions

Figure 3

Fig. 2. Number of trichinellosis cases per year in Serbia, 2011–2020, and trichinellosis incidence rate per 100 000 inhabitants, Serbia, 2011–2020. The trendline shows a steady decline in the incidence of human trichinellosis cases during this period. Trend line was derived by using the equation y = −0.1339x + 1.7127, based on data points in a Microsoft Excel chart, R2 = 0.12519.

Figure 4

Fig. 3. Human Trichinella spp. infection in 25 districts of Serbia, 2011–2020. Dark grey – districts with trichinellosis cases registered in 4–6 years of the 10-year study period. Light grey – districts with trichinellosis cases registered in 1–3 years of the 10-year study period. White – districts with no trichinellosis cases registered in the study period. Black – no data available. Image source: https://en.wikipedia.org/wiki/Districts_of_Serbia#/media/File:Districts_of_Serbia.png.

Figure 5

Fig. 4. Number of trichinellosis outbreaks per year in Serbia, 2011–2020. Trend line was derived by using the equation y = −0.9818x + 1984.3, based on data points in a Microsoft Excel chart, R2 = 0.6605.

Figure 6

Fig. 5. Geographical distribution and average prevalence of Trichinella infection in wild boars in 25 districts in Serbia, 2011–2020. Dark grey – districts with an average prevalence above 3%. Grey – districts with an average prevalence of 1–3%. Light grey – districts with an average prevalence of 0.5–1%. White – districts with an average prevalence of under 0.5%. Black – no data available. Image source: https://en.wikipedia.org/wiki/Districts_of_Serbia#/media/File:Districts_of_Serbia.png.

Figure 7

Table 3. Trichinella infection in wild boars in Serbia for the period 2011–2020