key: cord-0002571-z3in6bi2 authors: FAZ, Mirna; MARTÍNEZ, José Simón; QUIJANO-HERNÁNDEZ, Israel; FAJARDO, Raúl title: Reliability of clinical diagnosis and laboratory testing techniques currently used for identification of canine parvovirus enteritis in clinical settings date: 2016-11-06 journal: J Vet Med Sci DOI: 10.1292/jvms.16-0227 sha: 9369b15083026f2929d6eb01a67999d1800e2ec0 doc_id: 2571 cord_uid: z3in6bi2 Canine parvovirus type 2 (CPV-2) is the main etiological agent of viral enteritis in dogs. Actually in literature, CPV-2 has been reported with clinical signs that vary from the classical disease, and immunochromatography test and PCR technique have been introduced to veterinary hospitals to confirm CPV-2 diagnosis and other infections. However, the reliability of these techniques has been poorly analyzed. In this study, we evaluated the sensitivity and specificity of veterinary clinical diagnosis, immunochromatography test and PCR technique. Our data indicate that variations in the clinical signs of CPV-2 complicate the gathering of an appropriate diagnosis; and immunochromatography test and PCR technique do not have adequate sensitivity to diagnose positive cases. diagnosis in a discrete manner, using the problem oriented veterinary medical record (POVMR) as their diagnostic tool. Next, fecal samples of all dogs were analyzed through PCR and immunochromatography test, while blood samples were used to perform a complete blood count. nPCR is considered a highly reliable and sensitive technique to identify CPV-2 viral particles [11, 13] , and therefore, in this study, the sensitivity of the used tests was correlated to those obtained previously from nPCR, for CPV-2 diagnosis. Dog's stool samples were obtained using rectal swabs, which were suspended in nuclease-free water and 200 µl of the homogenates, and were used for DNA extraction. The procedure was performed using the QIAamp® DNA Stool DNA extraction kit (QIAGEN, Mainz, Germany), following the manufacturer's instructions. All DNA samples were quantified using a Q5000 Quawell spectrophotometer (Quawell Technology, Inc., San Jose, CA, U.S.A.). 100 ng of DNA of each sample were used for PCR reactions with 50 µl of final volume. Previously, a pair of primers was designed in our laboratory to amplify a 275 bp fragment, ParvoInt2FB (5′-TCAAGCAGATGGTGATCCAAG-3′) and ParvoInt2CR (5′-GGTACATTATTTAATGCAGTTA-3′) located at nucleotides 1,107-1,130 and 1,360-1,382 of the VP2 gene (GenBank accession number FJ0051962c). PCR reactions were performed using 2 µl of each primer (200 nM), 12.5 µl of GoTaq® Green Master Mix (Promega, Madison, WI, U.S.A.) containing DNA polymerase, reaction Buffer (pH 8.5) and 400 µM of each nucleotide (dATP, dGTP, Dctp and dTTP); 3 mM of MgCl 2. and 28.5 µl of nuclease free water. All reactions were carried out under the following amplification conditions; 1 cycle at 94°C for 5 min for initial denaturation, followed by 35 cycles at 94°C for 30 sec, 52°C for 1 min, 72°C for 1 min and a final extension cycle at 72°C for 5 min. nPCR was initially done amplifying a fragment of 1,740 bp using ParvoExt1f (5′-ATGAGTGATGGAGCAGTTCA-3′) and ParvoExt3R (5′-AGGTGCTAGTTGAGATTTTTCATATAC-3′) primers, and were designed using the nucleotide sequences 1-20 and 1,712-1,740 from gene VP2 for canine parvovirus (GenBank accession number FJ0051962c). Reaction was standardized to a final volume of 50 µl. The reaction mix contained 1 µl of GoTaq® Flexi DNA Polymerase 5 U/µl (Promega), 5 µl of GoTaq® Flexi buffer 5X Green, 3 µl of MgCl 2 25 mM, 4 µl dNTP's 200 µM, 2 µl of primers, 10 µl of DNA with a final concentration of 100 ng and 23 µl of nuclease free water. The reaction was carried out under the following amplification conditions: 1 cycle at 94°C for 5 min, followed by 35 cycles at 94°C for 30 sec, 50°C for 45 sec, 72°C for 1 min and 1 cycle at 72°C for 5 min. Afterwards, 1 µl of the product of this reaction was used as a DNA template for the nesting procedure, and primers and amplification conditions were the same for 275 bp fragment. All the amplification products were identified through horizontal electrophoresis in 2% agarose gels stained with 0.5 µg/ml of ethidium bromide and visualized with a UV transilluminator. For the analysis of immunochromatography test for canine parvovirus (CPV Ag), the ANIGEN ® kit (Bionote Inc., Gyeonggi-do, Korea) was utilized. Each test was carried out following manufacturer's instructions. Blood samples were taken from the jugular vein using vacutainer tubes with EDTA as anticoagulant. Complete blood cell counts (CBC) were performed using an automated cell counter (QBC vet-IDEXX Laboratories, Inc., Westbrook, ME, U.S.A.). The blood films were stained with Wright-Giemsa and examined under a photonic microscope. Leukopenia was considered when a total CBC count was less than 6 × 10 3 /µl [3] . Results analysis was performed through the use of a matrix for encoded variables [20] , and contingency tables were created to determine the diagnostic test properties [12] . Furthermore, the Kappa statistic was determined to estimate the agreement between the three used tests, and nPCR. The kappa value was characterized according to Kantere and colleagues in 2015 where Kappa value 1 indicates absolute agreement, whereas a value of 0 indicates that agreement occurs due to chance. In general, Kappa values higher than 0.6 indicate a good agreement level; the analysis was carried out using the statistical package SPSS Ver. 22.0 (IBM, Inc., Armonk, NY, U.S.A.). Ninety one point one (91.1) % of positive dogs for CPV-2 by nPCR were pure bred; 95.5% of the patients were between two and eight months old, and 4.5% were older than one year. Concerning their vaccination status, 40% were vaccinated at least once to prevent CPV-2 infection. Frequency of clinical signs showed by these dogs was as follows: 44.4% displayed vomiting and diarrhea; 20% had fever, vomiting and diarrhea (catarrhal or hemorrhagic); 17.7% showed only diarrhea; 8.8% displayed only vomiting; and 4.4% had diarrhea and fever, and 4.4% presented vomiting and fever. Leukopenia was observed in 48.8% of the dogs (Table 1) . Using clinical examination, veterinarians diagnosed only 57.8% of patients positive to CPV-2 and 100% of the negative dogs; therefore, the sensitivity value for clinical diagnosis was estimated as 57.7% (CI 0.95 42.2-72), and the observed specificity was 100% (CI 0.95 46.2-98.8). Regarding laboratory tests diagnosis, out of 100% of dogs that resulted positive through nPCR, only 30/45 of these patients were CPV-2 positive through immunochromatography test, while the five control patients that tested negative for CPV-2 were correctly diagnosed. Therefore, this technique showed a sensitivity of 66.6% (CI 0.95 50.9-79.5), and the observed specificity was 100% (CI 0.95 46.2-98.8). Using PCR technique, 36/45 patients were positive to CPV-2, and the five control patients were confirmed negative throughout the nPCR. Thus, PCR demonstrated a sensitivity of 80% (CI 0.95 63.1-87.7) and a specificity of 100% (CI 0.95 67.8-99.1) (Fig. 1) . Agreement among the three techniques is demonstrated through the Kappa value (Table 2) . Gastroenteritis caused by CPV-2 is considered one of the main viral diseases that affect dogs. Although clinical signs of canine parvovirus infection may vary, the most common signs reported were: anorexia, depression, lethargy, fever [10, 18] , mucoid and hemorrhagic diarrhea and leukopenia [1, 6, 21] ; in subclinical cases, some of these signs may or may not be present [7, 15] . During clinical examination, variability in clinical manifestations of infection was observed. Only 20% of the studied dogs presented typical signs as commonly described in literature. Clinical variability for this disease has been reported previously [2, 4, 7, 10, 15, 18] , and some authors have discussed factors, such as age, immune status, exposure route, viral dose, virulence of strains and co-infection with other infectious agents as possible causes [4, 15, 18] . This complicates obtaining an accurate diagnosis of CPV-2 when veterinarians rely solely on their clinical examination. Therefore, regarding our investigation solely based on this procedure, 42.2% of dogs will have a false-negative CPV-2 diagnosis.Through dogs medical records in this study, we observed that veterinarians were ruling out the possibility of infection primarily because the dogs were not exhibiting the classical clinical signs described in literature, had been vaccinated against CPV-2 and/or were adults. However, most of the dogs in our study displayed atypical signs. Therefore, we believe that subclinical infections of CPV-2 are more common, and veterinarians, who must decide whether or not to use additional diagnostic tests with high sensitivity and specificity, should seriously consider these findings. --+ ---+ + 35 + -+ + + --+ + 36 --+ + ---+ + 37 --+ + -+ --+ 38 Nd --+ + ---+ 39 + -+ -+ ---+ 40 + -+ + -+ --+ 41 Nd In this study, 40% of patients positive to CVP-2 had been previously immunized. It is well known that PCR technique is highly sensitive, and therefore, it detects vaccine viral particles in feces from recently vaccinated patients; studies indicate that it is possible to obtain false-positive results from days 3 to 10 post-vaccination with a modified live CPV vaccine [10, 18] . Consequently, to perform this study, patients with history of vaccination on the previous 15 days were excluded. Additionally, samples from vaccinated dogs positive to CPV-2 were sequenced, and in all studied cases, the genovariant CPV-2c was identified (data not show), which implies that dogs were infected with field CPV-2c, knowing that no CPV-2c vaccine is available yet in Mexico. Moreover, in Mexico, Pedroza and colleagues reported that the most common antigenic variant in infected dogs was CPV-2c [16] . On the other hand, many veterinarians consider the presence of leukopenia, a supporting factor for CPV-2 diagnosis. However, we observed that only 48.8% (22/45) of the studied dogs presented leukopenia during evaluation, which is consistent with other reports that indicated around 50% of dogs don't display hematologic alterations at the time of evaluation [18] . Therefore, a CBC is a valuable tool that can provide information about the disease severity, suggesting a prognosis and determining the response to treatment. However, leukopenia should not be considered as a diagnostic tool for CPV-2, because it does not provide an evidence for virus presence. Various techniques of viral identification are used for the definitive confirmation of infection by CPV-2, for example, rapid tests based on immunochromatography are widely used by clinicians, because the procedure is easy, fast and accessible. Additionally, it doesn't require sample preparation or sending to a specialized laboratory for analysis. The varying sensitivity of this test is its downside; several studies have indicated that its sensitivity ranges from 50 to 100% [8, 9] , and in our study, the comparative sensitivity with nPCR was 66.6%. Some studies have suggested that the low technique sensitivity is due to the need of a large viral particles quantities to be shed into the stool of dogs to obtain a positive diagnosis [5, 8, 10, 18] . The use of this technique must be reconsidered, as higher probability of false negative results is expected. In order to prevent this, further techniques, with higher sensitivities must be used [19] . Several studies have demonstrated the high sensitivity of PCR-based tests; currently, there are multiple variants of the same procedure that offer sensitivities ranges from 80 to 100% [11, 17, 22, 25] . In the present study, PCR had 80% sensitivity, and it's noteworthy to mention that patients were only identified positive to infection throught nPCR meanwhile neither PCR nor immunochromatography tests were able to identify it. Regarding the kappa-value, we compared results among the three analyzed methods to nPCR. The poor agreement between clinical diagnosis and nPCR was demonstrated, nevertheless; moderate agreement was observed between conventional PCR and nPCR which may be due to the similarity between the two tests. Concerning clinical signs, the presence of either vomiting or diarrhea was observed in all virally infected patients, while other clinical signs were not considered relevant to the infection; in agreement with clinical signs and sensitivity of the used techniques, no relationship was observed. For example, case no. 26 showed only vomiting as a clinical sign, and it was deemed negative for CPV-2 by veterinary clinical diagnosis, however, immunochromatography test, PCR and nPCR tests were positive to CPV-2. Furthermore, cases 41 and 42 in which the main clinical sign was diarrhea, could only be diagnosed positive to CPV-2 using nPCR. Our data indicate that the most frequently used diagnostic tests in clinical and diagnostic veterinary laboratories to detect CPV-2 are highly specific, but they lack sensitivity, which prevents the precise diagnosis of CPV-2. In our study, PCR and immunochromatography test were not as sensitive as nPCR, which was confirmed in previous investigaions [14] , however, the use of nPCR as a diagnosis test is not yet wide-spread in veterinary hospitals, while it remains widely used for research purposes. On the other hand, Real-Time PCR, which is also highly sensitive, is rarely used, because of its high equipment costs and the requirement of a highly specialized staff for its handling. However, technological advances allowed these techniques to become cheaper and simpler to use, which could lead to their direct application in veterinary hospitals to improve the diagnostic accuracy for CPV-2. 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Role of capsid protein in parvoviruses infection Rapid method utilizing the polymerase chain reaction for detection of canine parvovirus in feces of diarrheic dogs ACKNOWLEDGMENTS. Mirna Faz would like to thank Consejo Nacional de Ciencia y Tecnología for the scholarship awarded with scholar ID 248462 for postgraduate studies in Universidad Autónoma del Estado de México, Programa de Maestría y Doctorado en Ciencias Agropecuarias y Recursos Naturales. The autors would like to thank Fundación Educación Superior Empresa, for the financial support awarded to this project and to the staff at Veterinary Hospital for Small Animals of the Universidad Autónoma de Estado de México, for allowing us to use their facilities and for their collaboration in the development of this project.