Evaluating the Diagnostic Accuracy of a Novel Bayesian Decision-Making Algorithm for Vision Loss.

The current diagnostic aids for acute vision loss are static flowcharts that do not provide dynamic, stepwise workups. We tested the diagnostic accuracy of a novel dynamic Bayesian algorithm for acute vision loss. Seventy-nine "participants" with acute vision loss in Windsor, Canada were assessed by an emergency medicine or primary care provider who completed a questionnaire about ocular symptoms/findings (without requiring fundoscopy). An ophthalmologist then attributed an independent "gold-standard diagnosis". The algorithm employed questionnaire data to produce a differential diagnosis. The referrer diagnostic accuracy was 30.4%, while the algorithm's accuracy was 70.9%, increasing to 86.1% with the algorithm's top two diagnoses included and 88.6% with the top three included. In urgent cases of vision loss ( n = 54), the referrer diagnostic accuracy was 38.9%, while the algorithm's top diagnosis was correct in 72.2% of cases, increasing to 85.2% (top two included) and 87.0% (top three included). The algorithm's sensitivity for urgent cases using the top diagnosis was 94.4% (95% CI: 85-99%), with a specificity of 76.0% (95% CI: 55-91%). This novel algorithm adjusts its workup at each step using clinical symptoms. In doing so, it successfully improves diagnostic accuracy for vision loss using clinical data collected by non-ophthalmologists.