Abstracts

Introduction

The scientific literature reports divergence between the efficiency of different methods for the diagnosis of gastrointestinal parasites in dogs (FOREYT, 1989Foreyt WJ. Diagnostic parasitology. Vet Clin North Am Small Anim Pract 1989; 19(5): 979-1000.; TÁPARO et al., 2006Táparo CV, Perri SH, Serrano AC, Ishizaki MN, da Costa TP, Amarante AFT, et al. Comparison between coproparasitological techniques for the diagnosis of helminth eggs or protozoa oocysts in dogs. Rev Bras Parasitol Vet 2006; 15(1): 1-5.; KATAGIRI; OLIVEIRA-SEQUEIRA, 2008Katagiri S, Oliveira-Sequeira TCG. Prevalence of Dog Intestinal Parasites and Risk Perception of Zoonotic Infection by Dog Owners in São Paulo State, Brazil. Zoonoses Public Health 2008; 55(8-10): 406-413.http:∕∕dx.doi.org∕10.1111∕j.1863-2378.2008.01163.x
http:∕∕dx.doi.org∕10.1111∕j.1863-2378.20... ). Dogs can as act as sources of infection of gastrointestinal parasites for humans (XIAO et al., 2007Xiao L, Cama AV, Cabrera L, Ortega Y, Pearson J, Gilman RH. Possible transmission of Cryptosporidium canis among children and a dog in a household. J Clin Microbiol 2007; 45(6): 2014-2016. http:∕∕dx.doi.org∕10.1128∕JCM.00503-07
http:∕∕dx.doi.org∕10.1128∕JCM.00503-07... ; RODIE et al., 2008Rodie G, Stafford P, Holland C, Wolfe A. Contamination of dog hair with eggs of Toxocara canis. Vet Parasitol 2008; 152(1-2): 85-93.http:∕∕dx.doi.org∕10.1016∕j.vetpar.2007.12.008
http:∕∕dx.doi.org∕10.1016∕j.vetpar.2007.... ; BRIDGER; WHITNEY, 2009Bridger KE, Whitney H. Gastrointestinal parasites in dogs from the Island of St. Pierre off the south coast of Newfoundland. Vet Parasitol 2009; 162(1): 167-170. http:∕∕dx.doi.org∕10.1016∕j.vetpar.2009.02.016
http:∕∕dx.doi.org∕10.1016∕j.vetpar.2009.... ). In order to evaluate the true extent of the emerging zoonoses, sensitive diagnostic techniques should be widely available (McCARTHY; MOORE, 2000McCarthy J, Moore TA. Emerging helminth zoonoses. Int J Parasitol 2000; 30(12-13): 1351-1360. http:∕∕dx.doi.org∕10.1016∕S0020-7519(00)00122-3
http:∕∕dx.doi.org∕10.1016∕S0020-7519(00)... ; MEIRELES, 2010Meireles MV. Cryptosporidium infection in Brazil: implications for veterinary medicine and public health. Rev Bras Parasitol Vet 2010; 19(4): 197-204. http:∕∕dx.doi.org∕10.1590∕S1984-29612010000400002
http:∕∕dx.doi.org∕10.1590∕S1984-29612010... ). Besides that, improved methods for the detection of parasites in animals and environment would allow for more effective control measures and monitoring strategies.

Among the techniques proposed for fecal examinations in animals, the most common methods for detection of canine gastrointestinal parasitosis are centrifugation-flotation (OLIVEIRA-SEQUEIRA et al., 2002Oliveira-Sequeira TCG, Amarante AFT, Ferrari TB, Nunes LC. Prevalence of intestinal parasites in dogs from São Paulo State, Brazil. Vet Parasitol 2002; 103(1-2): 19-27. http:∕∕dx.doi.org∕10.1016∕S0304-4017(01)00575-1
http:∕∕dx.doi.org∕10.1016∕S0304-4017(01)... ), simple-flotation (SOUSA et al., 2010Sousa VR, Almeida AF, Cândido AC, Barros LA . Ovos e larvas de helmintos em caixas de areia de creches, escolas municipais e praças públicas de Cuiabá, MT. Cienc Anim Bras 2010; 11(2): 390-395. http:∕∕dx.doi.org∕10.5216∕cab.v11i2.3150
http:∕∕dx.doi.org∕10.5216∕cab.v11i2.3150... ) and microscopy exam (HENDRIX; ROBINSON, 2006Hendrix CM, Robinson E. Diagnostic Parasitology for Veterinary Technicians. 3rd ed. Mosby; 2006.). The technique calledThree Fecal Test (TF-Test®), here and forth referred to as TF-Test Conventional, was proposed for the diagnosis of intestinal parasites in humans, showing high diagnostic sensitivity (HOSHINO-SHIMIZU et al., 2001Hoshino-Shimizu S, Gomes JF, Dias LCS. Intestinal Parasites: traditional techniques and commercial kits. Braz J Parasitol 2001; 37: 44.; GOMES et al., 2004Gomes JF, Hoshino-Shimizu S, Dias LC, Araujo AJ, Castilho VL, Neves FA. Evaluation of a novel Kit (TF-Test) for the diagnosis of intestinal parasitic infections. J Clin Lab Anal 2004; 18(2): 132-138.http:∕∕dx.doi.org∕10.1002∕jcla.20011
http:∕∕dx.doi.org∕10.1002∕jcla.20011... ). The first study using TF-Test Conventional for gastrointestinal parasite detection in animals, specifically in sheep (Ovis aries), was reported by Lumina et al. (2006)Lumina G, Bricarello PA, Gomes JF, Amarante AFT. The evaluation of TF-Test Kit for diagnosis of gastrointestinal parasite infections in sheep. Braz J Vet Res Anim Sci 2006; 43: 496-501.. The results showed that the TF-Test Conventional could be more sensitive than the modified Gordon & Whitlock technique (UENO; GONÇALVES, 1998Ueno H, Gonçalves PC. Manual for diagnosis of helminthiasis in ruminants. 4rd ed. Tokyo: J. I. C. A; 1998.) and the techniques of flotation by sodium chloride and direct microscopy exam (GOMES et al., 2006Gomes JF, Lumina G, Amarante AFT, Hoshino-Shimizu S, Leme DP, Dias LCS, et al. Using the TF-Test Kit for the parasitological Diagnosis in dogs (Canis familiaris). Braz J Parasitol Vet 2006; 001-043: 406.).

In this work, we revisited the methods for dogs by proposing a considerable improvement in the TF-Test Conventional technique with the establishment of TF-Test Modified∕Dog, comparing it with the techniques of centrifugation-flotation by saturated solution of zinc sulfate, simple-flotation by saturated solution of sodium chloride and direct microscopy exam. The sensitivity, specificity and efficiency of each technique and their agreement with the Kappa (k) index were determined, classifying them as Poor, Low, Moderate, Substantial andAlmost perfect.

Materials and Methods

Sample collections and laboratory tests

Fecal samples were obtained from 106 dogs kept in kennels in the cities of Botucatu and Bragança Paulista, State of São Paulo, Brazil. A single stool sample was collected from each dog to perform the techniques of centrifugation-flotation by saturated solution of zinc sulfate (FAUST et al., 1938), simple-flotation by saturated solution of sodium chloride (WILLIS, 1921Willis HH. A simple levitation method for the detection of hookworm ova. Med J Aust 1921; 29: 375-376.) and direct microscopy exam (KATO; MIURA, 1954Kato K, Miura M. Comparative examinations. Jpn J Parasitol 1954; 3: 35.). For the TF-Test Conventional (GOMES et al., 2004Gomes JF, Hoshino-Shimizu S, Dias LC, Araujo AJ, Castilho VL, Neves FA. Evaluation of a novel Kit (TF-Test) for the diagnosis of intestinal parasitic infections. J Clin Lab Anal 2004; 18(2): 132-138.http:∕∕dx.doi.org∕10.1002∕jcla.20011
http:∕∕dx.doi.org∕10.1002∕jcla.20011... ) andTF-Test Modified∕Dog (FALCÃO et al., 2010), fecal samples from each animal were collected using theTF-Test kit in three alternate days.

Statistical analysis

The diagnostic sensitivity, specificity and efficiency of each technique were determined by comparison with reference data. The union of the positive results found by each of the five techniques studied was used as a reasonable approximation of the true positivity (FLEISS, 1981Fleiss JL. Statistical methods for rates and proportions. Nova York, John Wiley & Sons; 1981.; MacLURE; WILLET, 1987MacLure M, Willet WC. Misinterpretation and misuse of the Kappa statistic. Am J Epidemiol 1987; 126(2): 161-169. http:∕∕dx.doi.org∕10.1093∕aje∕126.2.161
http:∕∕dx.doi.org∕10.1093∕aje∕126.2.161... ). Similarly, the intersection of the true negative results in all five techniques was also used as reference. The agreement of the techniques with these reference data was calculated by the Kappa (k) index, statistically testing the consistency ofk and ranking it as: Poor (0 to 2.0); Low (0.21 to 0.40);Moderate (0.41 to 0.60);Substantial (0.61 to 0.80); and Almost perfect (0.8 to 1.0), according to Gomes et al. (2004)Gomes JF, Hoshino-Shimizu S, Dias LC, Araujo AJ, Castilho VL, Neves FA. Evaluation of a novel Kit (TF-Test) for the diagnosis of intestinal parasitic infections. J Clin Lab Anal 2004; 18(2): 132-138.http:∕∕dx.doi.org∕10.1002∕jcla.20011
http:∕∕dx.doi.org∕10.1002∕jcla.20011... .

Results

According to the statistical criteria above, 63 (59.42%) dogs showed positive results by at least one technique, whereas the remaining 43 (40.57%) dogs were considered negative by all five techniques. Among the infected animals, it was possible to verify that 51 (82.26%) dogs had a single type of parasite infection, 8 (12.90%) revealed double infections, and 3 (4.84%) presented triple infections. In the individual evaluation, the positivity was higher in the TF-Test Modified∕Dog (58.49%), followed by flotation by saturated zinc sulfate (47.17%),TF-Test Conventional (43,39%), flotation by saturated sodium chloride (33.02%), and direct microscopy exam (17.92%), as shown in Table 1. Single infections were predominantly detected by each of the five techniques, but they varied from 29.03% to 82.26%.

Sixty-three dogs were infected by seven parasite species (Table 2). Infections by three protozoa species were found in 31 (49.21%) dogs and infections by four species of helminths were found in 32 (50.79%) dogs. Among the gastrointestinal parasite species, Giardia spp. andAncylostoma spp. were detected in a large number of dogs, followed by Entamoeba spp., Trichuris vulpis, Toxocara canis, Isospora spp., and Spirocerca lupi.

The diagnostic performances of the five techniques are shown in Table 3, with the TF-Test Modified∕Dog technique presenting the highest sensitivity and efficiency among them. All techniques were able to detect the same 43 dogs as negative, so they presented 100% specificity.

The kappa indexes (k) of the five techniques are shown in Table 4, with statistically significant values (P < 0.05). The TF-Test Modified∕Dog was ranked as Almost perfect, whereas the other techniques were ranked from Substantial toModerate.

Discussion

The positive diagnosis of canine gastrointestinal parasitosis depends on the parasitological technique adopted (GOMES et al., 2006Gomes JF, Lumina G, Amarante AFT, Hoshino-Shimizu S, Leme DP, Dias LCS, et al. Using the TF-Test Kit for the parasitological Diagnosis in dogs (Canis familiaris). Braz J Parasitol Vet 2006; 001-043: 406.; TÁPARO et al., 2006Táparo CV, Perri SH, Serrano AC, Ishizaki MN, da Costa TP, Amarante AFT, et al. Comparison between coproparasitological techniques for the diagnosis of helminth eggs or protozoa oocysts in dogs. Rev Bras Parasitol Vet 2006; 15(1): 1-5.; KATAGIRI; OLIVEIRA-SEQUEIRA, 2010Katagiri S, Oliveira-Sequeira TCG. Comparison of three concentration methods for the recovery of canine intestinal parasites from stool samples. Exp Parasitol 2010; 126(2): 214-216. http:∕∕dx.doi.org∕10.1016∕j.exppara.2010.04.027
http:∕∕dx.doi.org∕10.1016∕j.exppara.2010... ). In this context, the present study demonstrates interesting aspects of the techniques studied, with significant differences in sensitivity and efficiency.

The proposed technique, TF-Test Modified∕Dog, detected 13 infected dogs more than the flotation by the saturated zinc sulfate technique (a gain of 11.32%), 16 infected dogs more than theTF-Test Conventional (a gain of 15.10%), and more than 27 infected dogs with respect to the other techniques (a gain greater than 25.47%). These considerable gains in sensitivity can be justified by the combination of various parasitic enrichment processes, such as: a) collection of fecal material in three alternate days using a preservative solution; b) double filtering of the collected fecal samples; c) two stages of parasitic concentration, centrifugation-sedimentation followed by concentration-flotation; and d) reading of two fecal smears, as recommended in the scientific literature (GARCIA, 2007Garcia LS. Diagnostic Medical Parasitology. 5th ed. Washington: ASM; 2007.). The collection of fecal samples in three alternate days using preservative solution considerably favors increased detection of parasitic species, including helminths and protozoa (Table 2).

This happens due to the different biological cycles of each parasite species, some of them with intermittent elimination of parasitic structures. In this case, the suppression of parasitic structures elimination can occur for hours, days, weeks or even months (HOSHINO-SHIMIZU et al., 2001Hoshino-Shimizu S, Gomes JF, Dias LCS. Intestinal Parasites: traditional techniques and commercial kits. Braz J Parasitol 2001; 37: 44.; GOMES et al., 2004Gomes JF, Hoshino-Shimizu S, Dias LC, Araujo AJ, Castilho VL, Neves FA. Evaluation of a novel Kit (TF-Test) for the diagnosis of intestinal parasitic infections. J Clin Lab Anal 2004; 18(2): 132-138.http:∕∕dx.doi.org∕10.1002∕jcla.20011
http:∕∕dx.doi.org∕10.1002∕jcla.20011... ; GARCIA, 2007Garcia LS. Diagnostic Medical Parasitology. 5th ed. Washington: ASM; 2007.). At the same time, the use of preservative solution preserves the morphology of parasites for a period of thirty days at room temperature (GARCIA, 2007Garcia LS. Diagnostic Medical Parasitology. 5th ed. Washington: ASM; 2007.). This is essential for a conclusive diagnosis (GOMES et al., 2004Gomes JF, Hoshino-Shimizu S, Dias LC, Araujo AJ, Castilho VL, Neves FA. Evaluation of a novel Kit (TF-Test) for the diagnosis of intestinal parasitic infections. J Clin Lab Anal 2004; 18(2): 132-138.http:∕∕dx.doi.org∕10.1002∕jcla.20011
http:∕∕dx.doi.org∕10.1002∕jcla.20011... ). The double-layered sieves eliminate part of the fecal impurities and the two-stage parasitic concentration – centrifugation-sedimentation followed by concentration-flotation, considerably reduces the remaining impurities. The technique of centrifugation-sedimentation concentrates parasitic structures with density higher than 1.19 g∕mL, such as the capsule with eggs of the parasiteDipylidium caninum, for instance.

The subsequent flotation-concentration aims at the detection of parasitic structures with density lower than 1.19 g∕mL, such asEntamoeba spp., Giardia spp., andIsospora spp. Finally, the TF-Test Modified∕Dog adopts two microscope readings. The first aliquot (60µL) examined consists of fecal material processed in the centrifugation-sedimentation step; in the flotation-concentration step, all the sediment from the previous step is used and examined. Helminths and protozoa can be diagnosed in the centrifugation-sedimentation aliquot, but after the performance of the flotation-concentration step, protozoa are found in much greater amounts. This way, one can have a good idea of the parasitic infection intensity in dogs.

In the current study, enteroparasitic positivity in dogs varied from 17.92% to 58.49%, depending on the parasitologic technique. These findings emphasize that the choice of a sensitive technique is fundamental to avoid misdiagnosis and, from the viewpoint of public health, implement effective control programs of zoonoses.

We detected 59.42% of infected animals and this positivity is consistent to the one reported by Oliveira-Sequeira et al. (2002)Oliveira-Sequeira TCG, Amarante AFT, Ferrari TB, Nunes LC. Prevalence of intestinal parasites in dogs from São Paulo State, Brazil. Vet Parasitol 2002; 103(1-2): 19-27. http:∕∕dx.doi.org∕10.1016∕S0304-4017(01)00575-1
http:∕∕dx.doi.org∕10.1016∕S0304-4017(01)... for stray dogs in the State of Sao Paulo Brazil, as determined by the association of three different techniques, such as: sedimentation, simple-flotation and centrifugation-flotation. However, in Chubut, Argentina, the association of these three techniques showed lower prevalence of parasitic infections in stray dogs (SÁNCHEZ-THEVENET et al., 2003Sánchez-Thevenet P, Jensen O, Mellado I, Torrecillas C, Raso S, Flores ME, et al. Presence and persistence of intestinal parasites in canine fecal material collected from the environment in the Province of Chubut, Argentine Patagonia. Vet Parasitol 2003; 117(4): 263-269. http:∕∕dx.doi.org∕10.1016∕j.vetpar.2003.09.014
http:∕∕dx.doi.org∕10.1016∕j.vetpar.2003.... ).

The techniques studied also detected 82.26% of positive dogs with a single type of infection, 12.90% with double infections, and 4.84% with triple infections. In other localities, such as Neuquén, Argentina, the reported prevalence of multiple parasitic infections was also lower than the single parasitic infection (SORIANO et al., 2009Soriano SV, Pierangeli NB, Roccia I, Bergagna HFJ, Lazzarini LE, Celescinco A, et al. A wide diversity of zoonotic intestinal parasites infects urban and rural dogs in Neuquén, Patagonia, Argentina. Vet Parasitol 2009; 167(1): 81-85. http:∕∕dx.doi.org∕10.1016∕j.vetpar.2009.09.048
http:∕∕dx.doi.org∕10.1016∕j.vetpar.2009.... ), by the use of two conventional techniques (flotation and sedimentation). Possibly, stray dogs infected by two or more parasite species have lower natural resistance or immunity than those with only one parasite species or without any infection.

Seven parasite species were identified by the five techniques studied:Ancylostoma spp. was detected in 16 (15.09%) dogs by four techniques, except the direct microscopy exam, which detected only half of the cases (7.54%). It is important to emphasize that the adult form of this intestinal helminth, when present in the host, seems to eliminate a great number of eggs, diagnosed even by low sensitive techniques. Other investigators (OLIVEIRA-SEQUEIRA et al., 2002Oliveira-Sequeira TCG, Amarante AFT, Ferrari TB, Nunes LC. Prevalence of intestinal parasites in dogs from São Paulo State, Brazil. Vet Parasitol 2002; 103(1-2): 19-27. http:∕∕dx.doi.org∕10.1016∕S0304-4017(01)00575-1
http:∕∕dx.doi.org∕10.1016∕S0304-4017(01)... ) have also found, in the State of Sao Paulo, no significant difference in the detection of this helminth infection in dogs by the association of three techniques. Nevertheless, in the diagnosis of Giardia spp. and Entamoeba spp., the TF-Test Modified∕Dog was more sensitive than all the other techniques (Table 2), pointing out the influence of the parasitic enrichment procedures and the collection of fecal samples in three alternate days.

Giardia spp. and Ancylostoma spp. were the most prevalent parasites in this study. These parasite species were also detected with moderate and high prevalence in different localities of the State of São Paulo by different authors (GENNARI et al., 2001Gennari SM, Kasai N, Cortez A. Ocorrência de protozoários e helmintos em amostras de fezes de cães e gatos da cidade de São Paulo. Braz J Vet Res Anim Sci 2001; 36(2): 87-91.; OLIVEIRA-SEQUEIRA et al., 2002Oliveira-Sequeira TCG, Amarante AFT, Ferrari TB, Nunes LC. Prevalence of intestinal parasites in dogs from São Paulo State, Brazil. Vet Parasitol 2002; 103(1-2): 19-27. http:∕∕dx.doi.org∕10.1016∕S0304-4017(01)00575-1
http:∕∕dx.doi.org∕10.1016∕S0304-4017(01)... ). Moreover, five out of seven parasite species,Toxocara canis, Ancylostoma spp.,Isospora spp., Giardia spp. andTrichuris vulpis, were also detected by the same authors, along with other investigators from Spain (MARTÍNEZ-CARRASCO et al., 2007Martínez-Carrasco C, Berriatua E, Garijo M, Martínez J, Alonso FD, Ruiz de Ybáñez R. Epidemiological study of non-systemic parasitism in dogs in southeast mediterranean Spain assessed by coprological and post-mortem examination. Zoonoses Public Health 2007; 54(5): 195-203. http:∕∕dx.doi.org∕10.1111∕j.1863-2378.2007.01047.x
http:∕∕dx.doi.org∕10.1111∕j.1863-2378.20... ).

The results obtained with the TF-Test Conventionalconfirm our previous study in dogs (GOMES et al., 2006Gomes JF, Lumina G, Amarante AFT, Hoshino-Shimizu S, Leme DP, Dias LCS, et al. Using the TF-Test Kit for the parasitological Diagnosis in dogs (Canis familiaris). Braz J Parasitol Vet 2006; 001-043: 406.), showing that the sensitivity of this technique is lower than the one obtained with flotation by saturated zinc sulfate, which differs from its high sensitivity found for sheep and humans (LUMINA et al., 2006Lumina G, Bricarello PA, Gomes JF, Amarante AFT. The evaluation of TF-Test Kit for diagnosis of gastrointestinal parasite infections in sheep. Braz J Vet Res Anim Sci 2006; 43: 496-501.; GOMES et al., 2004Gomes JF, Hoshino-Shimizu S, Dias LC, Araujo AJ, Castilho VL, Neves FA. Evaluation of a novel Kit (TF-Test) for the diagnosis of intestinal parasitic infections. J Clin Lab Anal 2004; 18(2): 132-138.http:∕∕dx.doi.org∕10.1002∕jcla.20011
http:∕∕dx.doi.org∕10.1002∕jcla.20011... ). Our findings indicate that dogs eliminate parasitic structures of lower specific densities (less than 1.19 g∕mL most of the times) in comparison to sheep and human parasites, resulting in a higher detection of these structures in the flotation using the saturated zinc sulfate technique. However, some species present specific densities higher than 1.19 g∕mL, such as Dipylidium caninum egg packets, which do not fluctuate, being detected only by centrifugation-sedimentation. That explains the indication of dual processing in the laboratory routine, such as centrifugation-sedimentation and concentration-flotation.

The highest sensitivity was obtained by the TF-Test Modified∕Dog (98.41%), while the sensitivity of the other techniques varied from 30.16% to 77.78%. This result represents considerable sensitivity gains of 25.39% and 20.63% with respect to the other two most sensitive techniques, TF-Test Conventional and flotation by saturated zinc sulfate, respectively. The diagnostic efficiency varied from 58.49% to 99.06%, with the highest value also obtained by the TF-Test Modified∕Dog. All studied techniques presented maximum specificity, since no parasite was found in the same 43 negative dogs.

The agreement of each technique with the reference data revealed similarities and differences between them. The TF-Test Modified∕Dog presented a k index ranked asAlmost Perfect, being significantly higher than thek indexes of the flotation by saturated zinc sulfate andTF-Test Conventional techniques, both ranked asSubstantial. These two techniques, in turn, showedk indexes significantly higher than the flotation by saturated sodium chloride and direct microscopy exam techniques, both atModerate rank. The TF-Test Modified∕Doghas proved to be simple and fast, since it requires less manual handling and less space to be performed. The use of preservative solution prevents the degradation of the parasitic structure, allowing for better visualization.

Conclusions

The TF-Test Modified∕Dog presented the best diagnostic performance in all aspects together with some advantages over the conventional techniques. In this sense, the high sensitivity of the TF-Test Modified∕Dog makes it suitable for epidemiological surveys of gastrointestinal parasitosis in dogs, zoonoses control and preventive surveillance programs.

The authors are grateful to the College of Parasitology, Institute of Biosciences, State University of São Paulo - UNESP, Botucatu, for providing the laboratory facilities. We would also like to thank ‘ImmunoAssay Ind. Com. S∕A.’, for the help of one of its technicians and laboratory supplies. We are also grateful to the ‘Research Support Foundation of the State of São Paulo’ – FAPESP (grants n° 2008∕57428-4 and n° 2008∕50090-8) for the financial support.

References

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