OBJECTIVE To estimate reliability of interpretation of neurologic examination findings for localization of vestibular dysfunction in dogs.
DESIGN Cross-sectional study.
ANIMALS 496 dogs that underwent MRI of the head for diagnosis of a neurologic problem between September 2011 and September 2015.
PROCEDURES Medical records were reviewed and data collected regarding signalment and neurologic examination, MRI, and CSF findings. Independent observers interpreted the findings, and agreement was assessed for a subset of dogs. Distributions of variables were compared between dogs with and without a neurologic findings–based interpretation of vestibular disease.
RESULTS 37% (185/496) of dogs had signs of vestibular dysfunction, of which 82% (151/185) had MRI abnormalities. In 73% (110/151) of dogs with MRI abnormalities, lesions involved central vestibular structures, and in 19% (29/151), lesions involved peripheral vestibular structures. On the basis of neurologic findings interpretation, 86% (160/185) of dogs were classified as having central vestibular dysfunction, and 61% (98/160) of these had an MRI-identified central vestibular lesion. Agreement among 3 independent observers was good (κ = 0.72) regarding use of neurologic examination findings to diagnose central versus peripheral vestibular dysfunction and very good (κ = 0.85) regarding use of MRI to diagnose peripheral vestibular lesions. Despite this agreement, only 29% (7/24) of dogs with a consensus clinical interpretation of peripheral vestibular dysfunction had MRI-identified peripheral lesions.
CONCLUSIONS AND CLINICAL RELEVANCE Although interobserver agreement was good for distinguishing central from peripheral vestibular dysfunction in dogs through interpretation of neurologic examination findings, this interpretation did not agree with the MRI-based diagnosis.
Objective—To determine whether expression of feline coronavirus (FCoV) 7b protein, as indicated by the presence of specific serum antibodies, consistently correlated with occurrence of feline infectious peritonitis (FIP) in cats.
Sample Population—95 serum samples submitted for various diagnostic assays and 20 samples from specific-pathogen–free cats tested as negative control samples.
Procedures—The 7b gene from a virulent strain of FCoV was cloned into a protein expression vector. The resultant recombinant protein was produced and used in antibody detection assays via western blot analysis of serum samples. Results were compared with those of an immunofluorescence assay (IFA) for FCoV-specific antibody and correlated with health status.
Results—Healthy IFA-seronegative cats were seronegative for antibodies against the 7b protein. Some healthy cats with detectable FCoV-specific antibodies as determined via IFA were seronegative for antibodies against the 7b protein. Serum from cats with FIP had antibodies against the 7b protein, including cats with negative results via conventional IFA. However, some healthy cats, as well as cats with conditions other than FIP that were seropositive to FCoV via IFA, were also seropositive for the 7b protein.
Conclusions and Clinical Relevance—Expression of the 7b protein, as indicated by detection of antibodies against the protein, was found in most FCoV-infected cats. Seropositivity for this protein was not specific for the FCoV virulent biotype or a diagnosis of FIP.