Concurrent use of two independent methods prevents erroneous HLA typing of deceased organ donors - An important strategy for patient safety and accurate virtual crossmatching for broader sharing.

Comprehensive and accurate human leukocyte antigen (HLA) typing within a short turnaround time is a crucial initial step for allocating deceased donor organs for transplantation. Erroneous HLA typing of deceased donors can be catastrophic and result in recipient death, failed transplant, and organ wastage due to inappropriately matched donors. The real-time polymerase chain reaction method is widely used as the sole method for HLA typing of deceased donors because of its simplified workflow. Herein, we have reported cases of four deceased donors showing discrepant HLA typing discovered using two independent methods concurrently. The HLA typing of these donors could have been erroneously reported if a single method had been used, which would have profound patient safety implications. In one case, the drop out of HLA-DR7 using a single method could have resulted in harmful organ allocation if the organ was transplanted after a virtual crossmatch to a sensitized candidate showing strong donor-specific HLA-DR7 antibodies. In conclusion, this case series suggests that concurrent dual typing is essential for accurate HLA typing of deceased donors. This strategy is vital because precise HLA typing is critical for accurate virtual crossmatching, which facilitates continuous distribution and broader geographic sharing of the deceased donor organ.

Concurrent typing of over 4000 samples by long-range PCR amplicon-based NGS and rSSO revealed the need to verify NGS typing for HLA allelic dropouts.

Hematopoietic stem cell transplantation (HSCT) from HLA-matched donors significantly decreases the risks of graft-rejection and graft-versus-host disease. Long-range PCR- amplicon-based next-generation sequencing (NGS) is increasingly used as a standalone method in clinical laboratories to determine HLA compatibility for HSCT and solid-organ transplantation. We hypothesized that an allelic dropout is a frequent event in the long-range PCR amplicon-based NGS HLA typing method. To test the hypothesis, we typed 4,006 samples concurrently using a commercially available long-range PCR amplicon-based NGS-typing and short exon-specific amplicon-based reverse sequence-specific oligonucleotide (rSSO) methods. The concordance between the NGS and rSSO typing results was 100% at HLA-A, -B, -C, -DRB1, -DRB3, -DRB5, -DQA1, DPA1 loci. However, 4.5% of the samples (179/4006) showed allelic-dropouts at one of the other three loci: HLA-DRB4 (3.9%), HLA-DPB1 (0.4%), and HLA-DQB1*(0.15%). The allelic-dropouts are not associated with specific haplotypes, and some dropouts can be reagent lot-specific. Although DRB1-DRB3/4/5-DQB1 linkages help to diagnose these allelic-dropouts in some cases, the rSSO typing was crucial to identify the dropouts in DQB1 and DPB1 loci. These results uncover the critical limitations of using long-range PCR amplicon-based NGS as a standalone method in clinical histocompatibility laboratories and advocate the need for strategies to diagnose and resolve allelic-dropouts.