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. 2021 May 3;4(5):e2110446.
doi: 10.1001/jamanetworkopen.2021.10446.

Assessment of the Implementation of Pharmacogenomic Testing in a Pediatric Tertiary Care Setting

Iris Cohn  1   2   3 Roozbeh Manshaei  2 Eriskay Liston  3 John B A Okello  3 Reem Khan  3 Meredith R Curtis  3 Abby J Krupski  1 Rebekah K Jobling  3   4   5 Kelsey Kalbfleisch  3   4 Tara A Paton  6 Miriam S Reuter  3   6   7   8 Robin Z Hayeems  9   10 Ruud H J Verstegen  1   11   12 Aaron Goldman  13 Raymond H Kim  3   4   14 Shinya Ito  1   2   12
Affiliations

Assessment of the Implementation of Pharmacogenomic Testing in a Pediatric Tertiary Care Setting

Iris Cohn et al. JAMA Netw Open. .

Abstract

Importance: Pharmacogenomic (PGx) testing provides preemptive pharmacotherapeutic guidance regarding the lack of therapeutic benefit or adverse drug reactions of PGx targeted drugs. Pharmacogenomic information is of particular value among children with complex medical conditions who receive multiple medications and are at higher risk of developing adverse drug reactions.

Objectives: To assess the implementation outcomes of a PGx testing program comprising both a point-of-care model that examined targeted drugs and a preemptive model informed by whole-genome sequencing that evaluated a broad range of drugs for potential therapy among children in a pediatric tertiary care setting.

Design, setting, and participants: This cohort study was conducted at The Hospital for Sick Children in Toronto, Ontario, from January 2017 to September 2020. Pharmacogenomic analyses were performed among 172 children who were categorized into 2 groups: a point-of-care cohort and a preemptive cohort. The point-of-care cohort comprised 57 patients referred to the consultation clinic for planned therapy with PGx targeted drugs and/or for adverse drug reactions, including lack of therapeutic benefit, after the receipt of current or past medications. The preemptive cohort comprised 115 patients who received exploratory whole-genome sequencing-guided PGx testing for their heart conditions from the cardiac genome clinic at the Ted Rogers Centre for Heart Research.

Exposures: Patients received PGx analysis of whole-genome sequencing data and/or multiplex genotyping of 6 pharmacogenes (CYP2C19, CYP2C9, CYP2D6, CYP3A5, VKORC1, and TPMT) that have established PGx clinical guidelines.

Main outcomes and measures: The number of patients for whom PGx test results warranted deviation from standard dosing regimens.

Results: A total of 172 children (mean [SD] age, 8.5 [5.6] years; 108 boys [62.8%]) were enrolled in the study. In the point-of-care cohort, a median of 2 target genes (range, 1-5 genes) were investigated per individual, with CYP2C19 being the most frequently examined; genotypes in 21 of 57 children (36.8%) were incompatible with standard treatment regimens. As expected from population allelic frequencies, among the 115 children in the whole-genome sequencing-guided preemptive cohort, 92 children (80.0%) were recommended to receive nonstandard treatment regimens for potential drug therapies based on their 6-gene pharmacogenetic profile.

Conclusions and relevance: In this cohort study, among both the point-of-care and preemptive cohorts, the multiplex PGx testing program provided dosing recommendations that deviated from standard regimens at an overall rate that was similar to the population frequencies of relevant variants.

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Conflict of interest statement

Conflict of Interest Disclosures: Ms Cohn reported receiving support from the Ted Rogers Centre for Heart Research during the conduct of the study. Dr Ito reported receiving grants from UCB Pharma and being a site director for the Canadian Pharmacogenomics Network for Drug Safety outside the submitted work. No other disclosures were reported.

Figures

Figure.
Figure.. Patient Flowchart and Overview of Pharmacogenomic Data Integration
PGx indicates pharmacogenomic; WGS, whole-genome sequencing. aNon-*1 haplotype in CYP2C9, CYP2C19, CYP2D6, and TPMT; VKORC1 1639 G>A (GA variant in the presence of CYP2C9*1/*1 is defined as a reference); and non-*3 haplotype in CYP3A5.
See this image and copyright information in PMC

Comment in

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