Molecular Dx Significance 6/10

Automated Urinalysis Advances: From Flow Cytometry to MALDI-TOF Pathogen ID

This review charts the technological progress in automated urinalysis including CMOS-enhanced test strip readers, high-throughput microscopy-based particle analyzers, and urinary flow cytometry capable of differentiating microorganisms. The integration of MALDI-TOF MS for rapid uropathogen identification and creatinine-corrected dilution parameters has significantly improved diagnostic accuracy. Emerging lab-on-a-chip approaches and expert systems for error reduction point toward further automation and point-of-care applications.

The original study

Progress in Automated Urinalysis.

Authors
Oyaert M, Delanghe J
Journal
Annals of laboratory medicine
Type
Journal Article, Review
PMID
30215225
Read the original study →

Original abstract

New technological advances have paved the way for significant progress in automated urinalysis. Quantitative reading of urinary test strips using reflectometry has become possible, while complementary metal oxide semiconductor (CMOS) technology has enhanced analytical sensitivity and shown promise in microalbuminuria testing. Microscopy-based urine particle analysis has greatly progressed over the past decades, enabling high throughput in clinical laboratories. Urinary flow cytometry is an alternative for automated microscopy, and more thorough analysis of flow cytometric data has enabled rapid differentiation of urinary microorganisms. Integration of dilution parameters (e.g., creatinine, specific gravity, and conductivity) in urine test strip readers and urine particle flow cytometers enables correction for urinary dilution, which improves result interpretation. Automated urinalysis can be used for urinary tract screening and for diagnosing and monitoring a broad variety of nephrological and urological conditions; newer applications show promising results for early detection of urothelial cancer. Concomitantly, the introduction of matrix-assisted laser desorption ionization-time-of-flight mass spectrometry (MALDI-TOF MS) has enabled fast identification of urinary pathogens. Automation and workflow simplification have led to mechanical integration of test strip readers and particle analysis in urinalysis. As the information obtained by urinalysis is complex, the introduction of expert systems may further reduce analytical errors and improve the quality of sediment and test strip analysis. With the introduction of laboratory-on-a-chip approaches and the use of microfluidics, new affordable applications for quantitative urinalysis and readout on cell phones may become available. In this review, we present the main recent developments in automated urinalysis and future perspectives.