Jessica M Boyd1, Richard Krause1, Gayle Waite2, William Hui2, Elham Yazdi2, David Wilmink2, Isolde Seiden-Long3. 1. Department of Pathology and Laboratory Medicine, University of Calgary and Calgary Laboratory Services, Canada. 2. Gamma-Dynacare Medical Laboratories, Canada. 3. Department of Pathology and Laboratory Medicine, University of Calgary and Calgary Laboratory Services, Canada. Electronic address: Isolde.seidenlong@cls.ab.ca.
Abstract
BACKGROUND: There is limited information about the effects of instituting CLSI Document C56A recommended workflows for the automated detection of hemolysis, lipemia and icterus (HIL) in different clinical laboratories and patient populations. We describe a process to develop and tailor automated reporting rules that are appropriate for the local laboratory population. METHODS: Automated decision algorithms were generated and applied to 2 high volume labs serving community and hospital populations. Proposed rules were applied to the datasets offline to predict the outcomes, and then were further optimized prior to implementation. RESULTS: Introduction of automated serum indices decreased HIL flagging compared to manual flagging. Hemolysis flagging was the greatest in all 3 patient populations, and was successfully reduced for LD, CK and AST by optimized rules that incorporated both the H-index result and the analyte result. Changes in flagging rates were also patient population specific, particularly for icterus which was a problem in hospitalized populations but not in the community. Overall, concordance between manual and automated flagging methods was very low in both laboratories. CONCLUSIONS: We demonstrate that flagging algorithms may not be universally transferable due to lab specific and population specific factors and demonstrate the benefits of local, a priori testing of algorithms prior to implementation.
BACKGROUND: There is limited information about the effects of instituting CLSI Document C56A recommended workflows for the automated detection of hemolysis, lipemia and icterus (HIL) in different clinical laboratories and patient populations. We describe a process to develop and tailor automated reporting rules that are appropriate for the local laboratory population. METHODS: Automated decision algorithms were generated and applied to 2 high volume labs serving community and hospital populations. Proposed rules were applied to the datasets offline to predict the outcomes, and then were further optimized prior to implementation. RESULTS: Introduction of automated serum indices decreased HIL flagging compared to manual flagging. Hemolysis flagging was the greatest in all 3 patient populations, and was successfully reduced for LD, CK and AST by optimized rules that incorporated both the H-index result and the analyte result. Changes in flagging rates were also patient population specific, particularly for icterus which was a problem in hospitalized populations but not in the community. Overall, concordance between manual and automated flagging methods was very low in both laboratories. CONCLUSIONS: We demonstrate that flagging algorithms may not be universally transferable due to lab specific and population specific factors and demonstrate the benefits of local, a priori testing of algorithms prior to implementation.
Authors: J Henny; R Nadif; S Le Got; S Lemonnier; A Ozguler; F Ruiz; K Beaumont; D Brault; E Sandt; M Goldberg; M Zins Journal: Front Public Health Date: 2020-12-10