OMOP CDM Can Facilitate Data-Driven Studies for Cancer Prediction: A Systematic Review.
Najia AhmadiYuan PengMarkus WolfienMichéle ZochMartin SedlmayrPublished in: International journal of molecular sciences (2022)
The current generation of sequencing technologies has led to significant advances in identifying novel disease-associated mutations and generated large amounts of data in a high-throughput manner. Such data in conjunction with clinical routine data are proven to be highly useful in deriving population-level and patient-level predictions, especially in the field of cancer precision medicine. However, data harmonization across multiple national and international clinical sites is an essential step for the assessment of events and outcomes associated with patients, which is currently not adequately addressed. The Observational Medical Outcomes Partnership (OMOP) Common Data Model (CDM) is an internationally established research data repository introduced by the Observational Health Data Science and Informatics (OHDSI) community to overcome this issue. To address the needs of cancer research, the genomic vocabulary extension was introduced in 2020 to support the standardization of subsequent data analysis. In this review, we evaluate the current potential of the OMOP CDM to be applicable in cancer prediction and how comprehensively the genomic vocabulary extension of the OMOP can serve current needs of AI-based predictions. For this, we systematically screened the literature for articles that use the OMOP CDM in predictive analyses in cancer and investigated the underlying predictive models/tools. Interestingly, we found 248 articles, of which most use the OMOP for harmonizing their data, but only 5 make use of predictive algorithms on OMOP-based data and fulfill our criteria. The studies present multicentric investigations, in which the OMOP played an essential role in discovering and optimizing machine learning (ML)-based models. Ultimately, the use of the OMOP CDM leads to standardized data-driven studies for multiple clinical sites and enables a more solid basis utilizing, e.g., ML models that can be reused and combined in early prediction, diagnosis, and improvement of personalized cancer care and biomarker discovery.
Keyphrases
- electronic health record
- data analysis
- big data
- machine learning
- papillary thyroid
- high throughput
- healthcare
- squamous cell
- mental health
- artificial intelligence
- systematic review
- small molecule
- chronic kidney disease
- end stage renal disease
- squamous cell carcinoma
- climate change
- dna methylation
- lymph node metastasis
- newly diagnosed
- skeletal muscle
- single cell
- health information
- adipose tissue
- copy number
- deep learning
- high resolution
- single molecule