Use of artificial intelligence for tailored routine urine analyses

Olivier Dauwalder; Agathe Michel; Cécile Eymard; Kevin Santos; Laura Chanel; Anatole Luzzati; Pablo Roy-Azcora; Jean François Sauzon; Marc Guillaumont; Pascale Girardo; Christine Fuhrmann; Gérard Lina; Frédéric Laurent; François Vandenesch; Chantal Sobas

doi:10.1016/j.cmi.2020.09.056

Use of artificial intelligence for tailored routine urine analyses

Clin Microbiol Infect. 2021 Aug;27(8):1168.e1-1168.e6. doi: 10.1016/j.cmi.2020.09.056. Epub 2020 Oct 7.

Authors

Affiliations

¹ Plateau de Microbiologie 24/24, Institut des Agents Infectieux, France; Pôle D'activité Médical Biologie, Service Pré Analytique, Hospices Civils de Lyon, Lyon, France. Electronic address: olivier.dauwalder@chu-lyon.fr.
² Plateau de Microbiologie 24/24, Institut des Agents Infectieux, France.
³ Pôle D'activité Médical Biologie, Cellule Informatique Biologie, Centre de Biologie et Pathologie Nord, France.
⁴ Pôle D'activité Médical Biologie, Service Pré Analytique, Hospices Civils de Lyon, Lyon, France.
⁵ Plateau de Microbiologie 24/24, Institut des Agents Infectieux, France; Pôle D'activité Médical Biologie, Service Pré Analytique, Hospices Civils de Lyon, Lyon, France.

PMID: 33038526
DOI: 10.1016/j.cmi.2020.09.056

Abstract

Objectives: Urine is the most common material tested in clinical microbiology laboratories. Automated analysis is already performed, permitting quicker results and decreasing the laboratory technologist's (LT) workload. These automatic systems have introduced digital imaging concepts. PhenoMATRIX (PHM) is an artificial intelligence software that merges picture algorithms and user rules to provide presumptive results. This study aimed at designing a tailored workflow using PHM, performing its validation and checking its performance in routine practice.

Methods: Two data collections including 96 and 135 urine samples from nephrostomy/ureterostomy and artificial bladder (US), 948 and 1257 urine samples from catheter (UC) and 3251 and 2027 midstream urine (MSU) were used to compare LT results with those obtained using two versions of PHM. Another 19 US, 102 UC and 508 MSU were used to monitor performance level 3 months after routine implementation.

Results: Before and after revisions, agreement between the first version of PHM and LT results were 83% (95% confidence interval [CI], 74.3-90.2) and 83% (95% CI, 75.3-90.9) (US), 66.7% (95% CI, 63.5-69.5) and 71.7% (95% CI, 68.8-74.4) (UC) and 65.4% (95% CI, 63.8-67.1) and 76% (95% CI, 74.1-77.1) (MSU). The second version improved results, demonstrating 96.2% (95% CI, 91.6-98.8) and 97% (95% CI, 92.6-99.2) (US), 87.5% (95% CI, 85.5-89.2) and 88.9% (95% CI, 87.0-90.5) (UC) and 91% (95% CI, 89.7-92.1) and 92% (95% CI, 91.1-93.4) (MSU) of agreement with LT results before and after revisions. The reliability of PHM results was confirmed by a routine study demonstrating 92% (95% CI, 90.0-94.2) overall agreement.

Conclusions: PHM showed high performance, with >90% of results in agreement with LT. PHM could help standardize and secure results, prioritize positive plates during analytical workflow and likely save LT time.

Keywords: Algorithms; CHROMIDCPSE; PhenoMATRIX; Urine; WASPLab artificial intelligence.

MeSH terms

Algorithms
Artificial Intelligence*
Humans
Reproducibility of Results
Software*
Urinalysis*
Urine