Bayesian estimation of diagnostic sensitivity and specificity of a qPCR and a bacteriological culture method for Piscirickettsia salmonis in farmed Atlantic salmon (Salmo salar L.) in Chile

Early detection of piscirickettsiosis is an important purpose of government‐ and industry‐based surveillance for the disease in Atlantic salmon farms in Chile. Real‐time qPCRs are currently used for surveillance because bacterial isolation is inadequately sensitive or rapid enough for routine use. S...

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Bibliographic Details
Published in:Journal of fish diseases 2020-10, Vol.43 (10), p.1167-1175
Main Authors: Laurin, Emilie, Gardner, Ian A., Peña, Andrea, Rozas‐Serri, Marco, Gayosa, Jorge, Neumann Heise, Joaquin, Mardones, Fernando O.
Format: Article
Language:English
Subjects:
Animals
Aquaculture
Bacteriological Techniques
Bayes Theorem
Bayesian analysis
Bayesian latent class model
Chile
Diagnostic systems
Farms
Fish Diseases - diagnosis
Fish Diseases - microbiology
Freshwater fishes
Kidneys
Latent Class Analysis
Liver
Marine fishes
Mathematical models
Necropsy
Outbreaks
Piscirickettsia - growth & development
Piscirickettsia - isolation & purification
Piscirickettsia salmonis
Piscirickettsiaceae Infections - diagnosis
Piscirickettsiaceae Infections - veterinary
piscirickettsiosis
Probability theory
qPCR
Real-Time Polymerase Chain Reaction - veterinary
Salmo salar
Salmo salar - microbiology
Salmon
Sensitivity
Sensitivity and Specificity
Specificity
Surveillance
Tissue
Tissue culture
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Summary:Early detection of piscirickettsiosis is an important purpose of government‐ and industry‐based surveillance for the disease in Atlantic salmon farms in Chile. Real‐time qPCRs are currently used for surveillance because bacterial isolation is inadequately sensitive or rapid enough for routine use. Since no perfect tests exist, we used Bayesian latent class models to estimate diagnostic sensitivity (DSe) and specificity (DSp) of qPCR and culture using separate two‐test, single‐population models for three farms (n = 148, 151, 44). Informative priors were used for DSp (culture (beta(999,1); qPCR (beta(98,2)), and flat priors (beta 1,1) for DSe and prevalence. Models were run for liver and kidney tissues combined and separately, based on the presence of selected gross‐pathological signs. Across all models, qPCR DSe was 5‐ to 30‐fold greater than for culture. Combined‐tissue qPCR median DSe was highest in Farm 3 (sampled during P. salmonis outbreak (DSe = 97.6%)) versus Farm 1 (DSe = 85.6%) or Farm 2 (DSe = 83.5%), both sampled before clinical disease. Median DSe of qPCR was similar for liver and kidney, but higher when gross‐pathological signs were evident at necropsy. High DSe and DSp and rapid turnaround‐time indicate that the qPCR is fit for surveillance programmes and diagnosis during an outbreak. Targeted testing of salmon with gross‐pathological signs can enhance DSe.
ISSN:0140-7775
1365-2761
DOI:10.1111/jfd.13226