Genetic data normalization for genomic medicine: a Fast Healthcare Interoperability Resources Genomics reference implementation

Abstract Objectives Demonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference implementation. Background Variability in genomics data representation is a significant impediment to precise search, clinical decision support rule writi...

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Published in	Journal of the American Medical Informatics Association : JAMIA Vol. 32; no. 10; pp. 1598 - 1608
Main Authors	Dolin, Robert H, Todor, Nicolae-Mihai, Shalaby, James, Arsalan, Huda, Shah, Eshani, Basravi, Nedah, Husami, Ammar, Rampersad, Akash, Heale, Bret S E, Chamala, Srikar
Format	Journal Article
Language	English
Published	England Oxford University Press 01.10.2025
Subjects	Algorithms Alleles Databases, Genetic Genetic Variation Genomics Health Information Interoperability HLA Antigens - genetics Humans variant annotation FHIR genomics genomics precision medicine genetic data normalization
Online Access	Get full text
ISSN	1067-5027 1527-974X 1527-974X
DOI	10.1093/jamia/ocaf136

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Abstract	Abstract Objectives Demonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference implementation. Background Variability in genomics data representation is a significant impediment to precise search, clinical decision support rule writing, variant annotation, and more. Such variability is problematic not just for genetic variants, but also applies to HLA alleles, phenotype codes, and more. Here, we provide an overview of genomic data variability and normalization algorithms, focusing on three key areas: genetic variants, HLA alleles, condition and medication variant annotations. We describe and demonstrate the strategies used in a public open source FHIR Genomics reference implementation. Materials and Methods We developed a set of design considerations, which we used to weigh different normalization approaches. All data (ingested patient data, ingested knowledge, query parameters) are subjected to normalization. Variant normalization leverages the biocommons/hgvs python package. HLA allele normalization leverages the py-ard python package. For variant annotation terminology variability (for conditions and medications), we leveraged FHIR-based ConceptMaps. Results Algorithms for normalization of genetic variants and HLA alleles, and terminology translations, have been implemented and deployed in a public open source FHIR Genomics Operations reference implementation. All data and source code described in this report are located at https://github.com/FHIR/genomics-operations, and deployed at https://fhir-gen-ops.herokuapp.com/. Every normalization strategy examined to date has known limitations. Conclusion While we report on our experience successfully encapsulating genomic data normalization in FHIR Genomics Operations, the challenges and solutions identified are broadly applicable to many other contexts.
AbstractList	Abstract Objectives Demonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference implementation. Background Variability in genomics data representation is a significant impediment to precise search, clinical decision support rule writing, variant annotation, and more. Such variability is problematic not just for genetic variants, but also applies to HLA alleles, phenotype codes, and more. Here, we provide an overview of genomic data variability and normalization algorithms, focusing on three key areas: genetic variants, HLA alleles, condition and medication variant annotations. We describe and demonstrate the strategies used in a public open source FHIR Genomics reference implementation. Materials and Methods We developed a set of design considerations, which we used to weigh different normalization approaches. All data (ingested patient data, ingested knowledge, query parameters) are subjected to normalization. Variant normalization leverages the biocommons/hgvs python package. HLA allele normalization leverages the py-ard python package. For variant annotation terminology variability (for conditions and medications), we leveraged FHIR-based ConceptMaps. Results Algorithms for normalization of genetic variants and HLA alleles, and terminology translations, have been implemented and deployed in a public open source FHIR Genomics Operations reference implementation. All data and source code described in this report are located at https://github.com/FHIR/genomics-operations, and deployed at https://fhir-gen-ops.herokuapp.com/. Every normalization strategy examined to date has known limitations. Conclusion While we report on our experience successfully encapsulating genomic data normalization in FHIR Genomics Operations, the challenges and solutions identified are broadly applicable to many other contexts. Demonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference implementation.OBJECTIVESDemonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference implementation.Variability in genomics data representation is a significant impediment to precise search, clinical decision support rule writing, variant annotation, and more. Such variability is problematic not just for genetic variants, but also applies to HLA alleles, phenotype codes, and more. Here, we provide an overview of genomic data variability and normalization algorithms, focusing on three key areas: genetic variants, HLA alleles, condition and medication variant annotations. We describe and demonstrate the strategies used in a public open source FHIR Genomics reference implementation.BACKGROUNDVariability in genomics data representation is a significant impediment to precise search, clinical decision support rule writing, variant annotation, and more. Such variability is problematic not just for genetic variants, but also applies to HLA alleles, phenotype codes, and more. Here, we provide an overview of genomic data variability and normalization algorithms, focusing on three key areas: genetic variants, HLA alleles, condition and medication variant annotations. We describe and demonstrate the strategies used in a public open source FHIR Genomics reference implementation.We developed a set of design considerations, which we used to weigh different normalization approaches. All data (ingested patient data, ingested knowledge, query parameters) are subjected to normalization. Variant normalization leverages the biocommons/hgvs python package. HLA allele normalization leverages the py-ard python package. For variant annotation terminology variability (for conditions and medications), we leveraged FHIR-based ConceptMaps.MATERIALS AND METHODSWe developed a set of design considerations, which we used to weigh different normalization approaches. All data (ingested patient data, ingested knowledge, query parameters) are subjected to normalization. Variant normalization leverages the biocommons/hgvs python package. HLA allele normalization leverages the py-ard python package. For variant annotation terminology variability (for conditions and medications), we leveraged FHIR-based ConceptMaps.Algorithms for normalization of genetic variants and HLA alleles, and terminology translations, have been implemented and deployed in a public open source FHIR Genomics Operations reference implementation. All data and source code described in this report are located at https://github.com/FHIR/genomics-operations, and deployed at https://fhir-gen-ops.herokuapp.com/. Every normalization strategy examined to date has known limitations.RESULTSAlgorithms for normalization of genetic variants and HLA alleles, and terminology translations, have been implemented and deployed in a public open source FHIR Genomics Operations reference implementation. All data and source code described in this report are located at https://github.com/FHIR/genomics-operations, and deployed at https://fhir-gen-ops.herokuapp.com/. Every normalization strategy examined to date has known limitations.While we report on our experience successfully encapsulating genomic data normalization in FHIR Genomics Operations, the challenges and solutions identified are broadly applicable to many other contexts.CONCLUSIONWhile we report on our experience successfully encapsulating genomic data normalization in FHIR Genomics Operations, the challenges and solutions identified are broadly applicable to many other contexts. Demonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference implementation. Variability in genomics data representation is a significant impediment to precise search, clinical decision support rule writing, variant annotation, and more. Such variability is problematic not just for genetic variants, but also applies to HLA alleles, phenotype codes, and more. Here, we provide an overview of genomic data variability and normalization algorithms, focusing on three key areas: genetic variants, HLA alleles, condition and medication variant annotations. We describe and demonstrate the strategies used in a public open source FHIR Genomics reference implementation. We developed a set of design considerations, which we used to weigh different normalization approaches. All data (ingested patient data, ingested knowledge, query parameters) are subjected to normalization. Variant normalization leverages the biocommons/hgvs python package. HLA allele normalization leverages the py-ard python package. For variant annotation terminology variability (for conditions and medications), we leveraged FHIR-based ConceptMaps. Algorithms for normalization of genetic variants and HLA alleles, and terminology translations, have been implemented and deployed in a public open source FHIR Genomics Operations reference implementation. All data and source code described in this report are located at https://github.com/FHIR/genomics-operations, and deployed at https://fhir-gen-ops.herokuapp.com/. Every normalization strategy examined to date has known limitations. While we report on our experience successfully encapsulating genomic data normalization in FHIR Genomics Operations, the challenges and solutions identified are broadly applicable to many other contexts.
Author	Basravi, Nedah Arsalan, Huda Rampersad, Akash Todor, Nicolae-Mihai Shah, Eshani Dolin, Robert H Shalaby, James Husami, Ammar Heale, Bret S E Chamala, Srikar
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Snippet	Abstract Objectives Demonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference... Demonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference implementation. Variability in... Demonstrate the ability to encapsulate clinical-grade genomics data normalization algorithms within a FHIR Genomics reference...
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SubjectTerms	Algorithms Alleles Databases, Genetic Genetic Variation Genomics Health Information Interoperability HLA Antigens - genetics Humans
Title	Genetic data normalization for genomic medicine: a Fast Healthcare Interoperability Resources Genomics reference implementation
URI	https://www.ncbi.nlm.nih.gov/pubmed/40966468 https://www.proquest.com/docview/3252223291 https://doi.org/10.1093/jamia/ocaf136
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