Performance Characteristics of Next-Generation Sequencing–Based Engraftment Monitoring and Microchimerism Detection in Allogeneic Hematopoietic Cell Transplantation A Practical Approach for Clinical Assay Validation

Abstract

Chimerism analysis by next-generation sequencing (NGS) is an emerging method for engraftment monitoring after allogeneic hematopoietic cell transplantation. A high-sensitivity method is required for the detection of microchimerism (<1% chimerism), which may have clinical utility in early relapse detection, allograft monitoring in organ transplantation, and other allogeneic cellular therapies (such as microtransplantations). As more clinical laboratories adopt this method, a thorough assessment of performance is needed. This study evaluated one such NGS-based assay that uses both single-nucleotide polymorphisms and insertions/deletions as genetic markers. An assessment of accuracy, linearity, sensitivity, and reproducibility was performed. Analytical sensitivity was 0.2% donor for single donor and 0.5% donors for double donors. The assay showed a high degree of reproducibility over a full range of chimerism. Comparison to short-tandem-repeat (STR) PCR showed high concordance; yet <5% chimerism was consistently detected by NGS, but not by STR-PCR. Comparison to real-time quantitative PCR showed high concordance, but with lower correlation in the midrange (40% to 60% chimerism). Overall, the assay showed consistent performance with high sensitivity and accuracy compared with STR-PCR and real-time quantitative PCR across a full range of chimerism in the setting of single-donor and multidonor transplantations. In addition, criteria for quality metrics were established for sequencing performance and data analysis and considerations made for clinical laboratory validation of NGS-based chimerism assay and analysis software.