Abstract
The present study was focused on the current state of Dirofilaria species distribution in the territory of the Slovak Danubian Lowland, a region previously identified endemic for Dirofilaria repens. For the research, blood samples of 330 dogs tested positive for dirofilariosis using concentration tests or “rapid heartworm tests” were sent by private veterinary practitioners for further DNA analyses and species determination. The results revealed an unquestionable change in the pattern of Dirofilaria species distribution with Dirofilaria immitis, diagnosed as the agent of mono- and co-infections with D. repens, responsible for 60.00% of all cases. The results showed that in the course of the last 5 years, D. immitis has spread significantly in Slovakia and has become the dominant causal agent of dirofilariosis in the former endemic areas of D. repens distribution, which increases infection risk for both dogs and humans.
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Introduction
Dirofilaria immitis and Dirofilaria repens, mosquito-transmitted parasitic filarioids, are of great concern in Europe for several decades. Dogs are the main hosts for both species with D. immitis causing severe cardiopulmonary “heartworm” disease (HWD) and D. repens responsible for the subcutaneous and ocular form of the infection. Both species have a zoonotic character, but in Europe, the majority of human cases of dirofilariosis are associated with D. repens (ESDA 2017).
From the epidemiological point of view, the recent data show a stable situation or even a decreasing trend in D. immitis prevalence in Western European countries, including previously hyperendemic areas, and a faster spread of D. repens in these territories (Genchi and Kramer 2020). Contrary to this, in several regions of Europe, including the Great Hungarian Plain or Apulia region and Linosa island in Southern Italy, D. immitis prevalence increased evidently in a short period (Mendoza-Roldan et al. 2020; Fuehrer et al. 2021; Brianti et al. 2023). This situation was also observed in Slovakia, Central Europe, where canine dirofilariosis was reported for the first time in 2005 (Svobodová et al. 2005). The area-wide epidemiological investigations that were performed afterward revealed the presence of D. repens in high-endemic areas with an overall prevalence of over 30.0% and with the highest positivity recorded among working dogs (Miterpáková et al. 2008, 2010).
During the first decade of epidemiological research on canine dirofilariosis in Slovakia (between 2005 and 2015), D. immitis cases were recorded only sporadically (Miterpáková et al. 2016). However, the situation has recently changed significantly and an evident increasing trend in the number of heartworm infections has been observed (Miterpáková et al. 2018, 2020).
The present study aimed to evaluate the current distribution of Dirofilaria species in the population of dogs with microfilaremia from the previously identified hyperendemic region.
Material and methods
Study area and sample collection
The present study was carried out in a previously identified endemic region of canine subcutaneous dirofilariosis situated in the southwestern part of Slovakia represented by the Slovak Danubian Lowland near the Slovak-Hungarian borders. The majority of the dogs examined came from districts Komárno and Nové Zámky (Fig. 1).
Between 2019 and 2022, private veterinary practitioners residing in the study regions were asked to send blood samples from dogs diagnosed with dirofilariosis to the Institute of Parasitology of the Slovak Academy of Sciences in Košice (IP SAS) and Veterinary and Food Institute in Bratislava (VFI) for Dirofilaria species identification and further analyses. All samples were accompanied by questionnaire forms with data concerning age, breed, sex, travel history, locality of residence, and health status.
Diagnostic procedures
In veterinary practices, Dirofilaria spp. infections were diagnosed using fresh blood smear or Knott’s test (Knott 1939) to detect microfilariae or commercial rapid test system based on enzyme immunoassay technique for presence of circulating D. immitis antigen (Rapid CHW Ag Test Kit; BioNote, Inc., Republic of Korea or SNAP Heartworm RT Test; IDEXX Laboratories, Inc., Westbrook, ME, USA). All dogs confirmed positive using the heartworm test were subsequently examined also by Knott’s test.
All samples that tested positive for microfilariae and/or D. immitis antigen (n = 330) were delivered to IP SAS for Dirofilaria species confirmation employing DNA analyses. For this purpose, DNA was extracted from 200 μl of blood with DNeasy Blood & Tissue Kit (Qiagen, Hilden, Germany) and afterward tested using a conventional PCR approach which amplifies a 203-bp fragment of the cytochrome c oxidase subunit 1 (cox1) gene of D. immitis and o 209-bp portion of D. repens COI gene according to Rishniw et al. (2006).
Results
Dirofilaria species occurrence
Within the study, altogether 330 dogs were found to be positive for canine dirofilariosis by private veterinary practitioners. The age of the dogs varied from 1 to 15 years (in 26 individuals the age was not referred to); 144 of them were females and 186 were males. Out of 330 dogs, 170 were kept by private owners, and 160 came from two dog shelters situated in Komárno and Nové Zámky districts.
The diagnosis was predetermined based on microfilariae presence (n = 284) and/or positive result of the heartworm antigen test (n = 82). Thirty-six of 82 D. immitis–seropositive dogs revealed also microfilariae in the blood; contrary, the remaining 46 seropositive dogs tested negative using Knott’s test. The diagnostic procedures and their results are illustrated in Figure 2.
DNA analysis of 284 microfilaraemic blood samples confirmed the mono-infection with D. repens in 132 dogs (46.48%), D. immitis in 63 animals (22.18%), and D. repens and D. immitis co-infection in 89 individuals (31.33%). In total, heartworm infection, confirmed either by DNA analysis or by serology, was diagnosed in 198 out of 330 dogs examined, which represents 60.00% of Dirofilaria-positive dogs included in the study (Figure 2).
Considering dogs from shelters independently, the majority of the animals, 79 of 160, were infected with D. immitis (49.38%), in 42 (26.25%) of them co-infection with both dirofilarial species was confirmed, and in 39 (24.38%) the mono-infection with D. repens was diagnosed.
Clinical manifestation
According to questionnaires that accompanied each sample, the changes in health conditions were observed in 82 infected dogs (24.85%). Out of 132 dogs that tested positive for D. repens infection, 44 (33.33%) showed clinical signs to some extent, most frequently the presence of subcutaneous nodules (27×), followed by pyometra observed in eight dogs, cachexia in five, and renal failure in four infected animals.
The mixed dirofilarial infection diagnosed in 89 dogs was clinically manifested in 30 individuals (33.71%) with clinical signs including most often chronic cough (15×), tachypnea (7×), and pneumonia (6×), followed by heart murmurs (4×), ascites (3×), hydropericardium syndrome (2×), dermatitis (2×), hepatopathy (1×), pancreatitis (1×), and effusion in the thorax (1×). Several dogs suffered simultaneously from various symptoms.
In eight of 63 (12.70%) dogs with diagnosed D. immitis mono-infection, heart failure–related ascites was observed; in three of them, also adult worms were found post-mortem in the right heart ventricle and pulmonary arteries. One dog with heartworm infection suffered also from haemolytic anaemia.
Discussion
The data analysed in the present study show an unquestionable change in the pattern of Dirofilaria species distribution in dogs living in the southwestern region of Slovakia over the recent 5 years in a favour of more pathogenic D. immitis. The results exposed that the number of dogs with heartworm diseases (HWD) has increased progressively, and D. immitis was responsible for more than half of all cases of canine dirofilariosis registered by veterinarians in surveyed districts Komárno and Nové Zámky (Fig. 2). A similar trend was reported in Hungary, neighbouring Slovakia from the south, where D. immitis recently became hyperendemic in the Great Hungarian Plain, previously considered endemic only for D. repens (Farkas et al. 2020; Széll et al. 2020). Also in Ukraine, bordering both Slovakia and Hungary, despite the shortness of accessible data, the current situation points to an increasing trend of D. immitis infections in the dog population. Most information is available from the Kharkiv region lying in northern Ukraine on the borders with Russia where several epidemiological studies were performed recently. In a survey carried out between September 2018 and February 2019, a total of 112 dogs were examined for dirofilariosis. The infection was diagnosed in 24 (21.4%) of them with D. immitis confirmed in 14 and D. repens in ten individuals (Kryvoruchenko et al. 2019). Additionally, during the winter hunting season in 2019/2020, 27 red foxes from the same region were examined by autopsy, and six of them were found positive for D. immitis adult worms localized in the right heart ventricle, pulmonary trunk, and pulmonary arteries (Liulin et al. 2021). On the other hand, in three other countries bordering Slovakia, Austria, Czechia, and Poland, D. immitis still occurs only sporadically, mainly as an agent imported from the Mediterranean region (Fuehrer et al. 2021). Interestingly enough, the quite recent epidemiological study performed in parallel on the territory of Czechia and Slovakia, the neighbouring countries with a common social and political background as well as similar veterinary care levels, revealed significant differences in the distribution of Dirofilaria-infected dogs with the recorded prevalence of 1.86% and 10.56%, respectively (Miterpáková et al. 2021). The epidemiological situation concerning canine dirofilariosis is changing also in historically endemic regions, e.g. the decreasing trend of HWD cases in the previously hyperendemic area in Northern Italy is accompanied by simultaneous expansion of D. immitis towards southern, previously non-endemic regions (Genchi and Kramer 2020; Panarese et al. 2020a). Apart from environmental changes, the reason for this reverse trend of D. immitis distribution could be explained by the regular long-term use of chemoprophylaxis treatment in previously endemic areas and its absence in regions where veterinary practitioners are not aware of HWD yet.
The lack of preventive measures and adequate treatment could also be the main reason for high D. immitis prevalence in the shelter and street dogs representing a suitable source for the infection spread (Otranto et al. 2017; Panarese et al. 2020a). This fact was backed also by the results of our study seeing that many dogs with diagnosed HWD, caused by D. immitis or co-infection with D. repens, came from shelters. From the epidemiology point of view, it is important to note that high numbers of dogs kept in Slovak shelters are exported abroad, most frequently to Austria, Germany, and Switzerland (personal information with shelter managers and veterinarians), which can contribute to the expansion of the infection agents into non-endemic regions.
Considering that in more than one half of D. immitis seropositive dogs (46 out of 82; 56.10%), microfilariae were absent in the peripheral blood, it could be suspected that the true prevalence of HWD in Slovakia is underestimated. The high probability of occult D. immitis infections, caused by a small number of microfilariae, unisex infestation, testing within the incubation period, or drug-induced sterility of the female worms, has been reported by several authors (e.g. Rawling et al. 1982; Pantchev et al. 2011). One of the most recent studies carried out by Panarese et al. (2020b) in a high-risk geographic area in Southern Italy revealed that the prevalence of canine dirofilariosis varied between 44.4 and 79.6% according to the diagnostic method used. From the practical point of view, the use of Knott’s (or another concentration) test alone may lead to false-negative results; therefore, a diagnostics of canine dirofilariosis in veterinary clinics should, at least in endemic regions, include also a rapid serological test for heartworm antigen detection. Nevertheless, from another point of view, the question regarding the sensitivity and specificity of the serological tests arises. A lot of studies based on various antigen tests detecting heartworm disease have been carried out worldwide with a very different sensitivity unveiled. For instance, several recent comparative studies revealed rather great differences in sensitivity (varied between 76.9 and over 97.0%) and specificity (ranged from 66.7 to 99.5%) of tests routinely used in veterinary praxes in the USA and Europe (Burton et al. 2020; Becker et al. 2022). For that reason, also dogs from our study diagnosed with the occult form of D. immitis infection should be correctly defined as “suspected for heartworm disease”. Anyway, the research of occult dirofilariosis needs more attention, especially in currently formed endemic areas where both dirofilarial species circulate.
On the other hand, dogs with microfilariaemia, in particular individuals without clinical manifestation and any adequate treatment, represent the main source for the spread of infection. Veterinarians in endemic regions should therefore take this possibility into account and focus more widely on prophylactic measures.
Conclusion
The presented study confirmed that Slovakia, endemic for D. repens since 2007, became endemic for D. immitis in the course of recent 5 years, whereby the endemic regions are identical for both species. From a practical point of view, to reduce the risk of infection and given the zoonotic nature of the parasites, it is essential to continue the epidemiological surveillance of heartworm disease and to emphasise awareness raising among veterinarians and dog breeders.
References
Becker Z, Holló N, Farkas R, Gyurkovszky M, Reiczigel J, Olaszy K, Vári Z, Vörös K (2022) Serodiagnostic difficulties and possibilities of heartworm disease in regions where both Dirofilaria immitis and Dirofilaria repens infections occur. Acta Veterin Hungarica 70:92–99. https://doi.org/10.1556/004.2022.00006
Brianti E, Napoli E, De Benedetto G, Venco L, Mendoza-Roldan J, Basile A, Bezerra-Santos MA, Drake J, Schaper R, Otranto D (2023) Elimination of Dirofilaria immitis infection in dogs, Linosa island, Italy, 2020–2022. Emerg Infect Dis 8:1559–1565. https://doi.org/10.3201/eid2908.221910
Burton KW, Liu J, Drexel J, Pulaski CN, Heartsill S, Dupuy C (2020) Comparative evaluation of field samples using 2 in-clinic assays for heartworm antigen detection in dogs. Vet Parasitol 283:109163. https://doi.org/10.1016/j.vetpar.2020.109163
ESDA (European Society of Dirofilariosis and Angiostrongylosis) (2017) Guidelines for clinical management of human. In: Dirofilaria infections Available online: https://www.esda.vet/wp-content/uploads/2017/11/GUIDELINES-FOR-CLINICAL-MANAGEMENT-OF-HUMAN-DIROFILARIA-INFECTIONS.pdf. Accessed 28 Feb 2022
Farkas R, Mag V, Gyurkovszky M, Takács N, Vörös K, Solymosi N (2020) The current situation of canine dirofilariosis in Hungary. Parasitol Res 119:129–135. https://doi.org/10.1007/s00436-019-06478-5
Fuehrer H-P, Morelli S, Unterköfler MS, Bajer A, Bakran-Lebl K, Dwużnik-Szarek D, Farkas R, Grandi G, Heddergott M, Jokelainen P, Knific T, Leschnik M, Miterpáková M, Modrý D, Petersen HH, Skírnisson K, Vergles Rataj A, Schnyder M, Strube C (2021) Dirofilaria spp. and Angiostrongylus vasorum: current risk of spreading in Central and Northern Europe. Pathogens 10:1268. https://doi.org/10.3390/pathogens10101268
Genchi C, Kramer LH (2020) The prevalence of Dirofilaria immitis and D. repens in the Old World. Vet Parasitol 280:108995. https://doi.org/10.1186/s13071-022-05459-5
Knott J (1939) A method for making microfilarial surveys on day blood. Trans R Soc Trop Med Hyg 33:191–196
Kryvoruchenko DO, Prykhodko YO, Mazannyy OV, Byrka VI (2019) Diagnostics of dog dirofilariosis and epizootic situation in Kharkov region of Ukraine [Діагностика дирофіляріозу собак та епізоотична ситуація у Харківському регіоні України]. Veterin Sci Technol Animal Husbandry and Natural Manag 4:95–102. (in Ukrainian with English abstract). https://doi.org/10.31890/vttp.2019.04.19
Liulin PV, Prykhodko YO, Mazannyі OV, Fedorova HV, Nikiforova OV, Kryvoruchenko DO (2021) Occurrence of Dirofilaria immitis (Nematoda, Onchocercidae) in red foxes (Vulpes vulpes) from the suburbs of Kharkiv (Ukraine). Zoodiversity 55:425–430. https://doi.org/10.15407/zoo2021.05.425
Mendoza-Roldan J, Benelli G, Panarese R, Iatta R, Furlanello T, Beugnet F, Zatelli A, Otranto D (2020) Leishmania infantum and Dirofilaria immitis infections in Italy, 2009–2019: changing distribution patterns. Parasites Vectors 13:193. https://doi.org/10.1186/s13071-020-04063-9
Miterpáková M, Antolová D, Hurníková Z, Dubinský P (2008) Dirofilariosis in Slovakia - a new endemic area in Central Europe. Helminthol 45:20–23
Miterpáková M, Antolová D, Hurníková Z, Dubinský P, Pavlačka A, Németh J (2010) Dirofilaria infection in working dogs in Slovakia. J Helminthol 84:173–176. https://doi.org/10.2478/s11687-008-0003-6
Miterpáková M, Hurníková Z, Valentová D, Borková L (2021) Different epidemiological pattern of canine dirofilariosis in two neighboring countries in Central Europe - the Czech Republic and Slovakia. Parasitol Res 120:547–552
Miterpáková M, Iglódyová A, Čabanová V, Stloukal E, Miklisová D (2016) Canine dirofilariosis endemic in Central Europe - 10 years of epidemiological study in Slovakia. Parasitol Res 116:2389–2395
Miterpáková M, Valentová D, Čabanová V, Berešíková Ľ (2018) Heartworm on the rise - new insights into Dirofilaria immitis epidemiology. Parasitol Res 117:2347–2350
Miterpáková M, Zborovská H, Bielik B, Halán M (2020) The fatal case of an autochthonous heartworm disease in a dog from a non-endemic region of south-eastern Slovakia. Helminthol 57:120–128
Otranto D, Dantas-Torres F, Mihalca AD, Traub RJ, Lappin M, Baneth G (2017) Zoonotic parasites of sheltered and stray dogs in the era of the global economic and political crisis. Trends Parasitol 33:813–825. https://doi.org/10.1007/s00436-016-4989-2
Panarese R, Iatta R, Latrofa MS, Zatelli A, Ignjatović Ćupina A, Montarsi F, Pombi M, Mendoza-Roldan JA, Beugnet F, Otranto D (2020a) Hyperendemic Dirofilaria immitis infection in a sheltered dog population: an expanding threat in the Mediterranean region. Int J Parasitol 50:555–559. https://doi.org/10.1016/j.ijpara.2020.04.002
Panarese R, Iatta R, Mendoza-Roldan JA, Szlosek D, Braff J, Liu JZ, Beugnet F, Dantas-Torres F, Beall MJ, Otranto D (2020b) Comparison of diagnostic tools for the detection of Dirofilaria immitis infection in dogs. Pathogens 9:499. https://doi.org/10.3390/pathogens9060499
Pantchev N, Etzold M, Daugschies A, Dyachenko V (2011) Diagnosis of imported canine filarial infections in Germany 2008-2010. Parasitol Res 109:S61–S76. https://doi.org/10.1007/s00436-011-2403-7
Rawlings CA, Dave DL, McCall JW (1982) Four types of occult Dirofilaria immitis infection in dogs. J Am Vet Med Asso 180:1323–1326
Rishniw M, Barr SC, Simpson KW, Frongillo M, Franz M, Dominquez AJL (2006) Discrimination between six species of canine microfilariae by a single polymerase chain reaction. Vet Parasitol 135:303–314. https://doi.org/10.1016/j.vetpar.2005.10.013
Svobodová V, Svobodová Z, Beladičová V, Valentová D (2005) First cases of canine dirofilariosis in Slovakia: a case report. Veterin Med–Czech 50:510–512. https://doi.org/10.17221/5656-VETMED
Széll Z, Bacsadi Á, Szeredi L, Nemes C, Fézer B, Bakcsa E, Kalla H, Tolnai Z, Sréter T (2020) Rapid spread and emergence of heartworm resulting from climate and climate-driven ecological changes in Hungary. Vet Parasitol 280:109067. https://doi.org/10.1016/j.vetpar.2020.109067
Acknowledgements
The authors are cordially grateful to all veterinary practitioners and dog owners for their cooperation.
Funding
Open access funding provided by The Ministry of Education, Science, Research and Sport of the Slovak Republic in cooperation with Centre for Scientific and Technical Information of the Slovak Republic The research was financially supported by the Science Grant Agency VEGA—project no. 2/0014/21.
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Martina Miterpáková: Conceptualization, Funding acquisition, Investigation, Writing – original draft. Daniela Valentová: Investigation, Formal analysis, Writing – review. Zuzana Hurníková: Investigation, Formal analysis, Writing – review & editing.
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No approval of research committees was required to accomplish the goals of this study, as the collection of the blood samples was carried out within diagnostic procedures by veterinarians following good veterinary practice.
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Miterpáková, M., Valentová, D. & Hurníková, Z. Dirofilaria immitis conquering the regions in Slovakia previously endemic for D. repens. Parasitol Res 122, 2945–2950 (2023). https://doi.org/10.1007/s00436-023-07983-4
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DOI: https://doi.org/10.1007/s00436-023-07983-4