TY - JOUR
T1 - Synthetic Data Generation by Artificial Intelligence to Accelerate Research and Precision Medicine in Hematology
AU - D'Amico, Saverio
AU - Dall'Olio, Daniele
AU - Sala, Claudia
AU - Dall'Olio, Lorenzo
AU - Sauta, Elisabetta
AU - Zampini, Matteo
AU - Asti, Gianluca
AU - Lanino, Luca
AU - Maggioni, Giulia
AU - Campagna, Alessia
AU - Ubezio, Marta
AU - Russo, Antonio
AU - Bicchieri, Maria Elena
AU - Riva, Elena
AU - Tentori, Cristina A.
AU - Travaglino, Erica
AU - Morandini, Pierandrea
AU - Savevski, Victor
AU - Santoro, Armando
AU - Prada-Luengo, Iñigo
AU - Krogh, Anders
AU - Santini, Valeria
AU - Kordasti, Shahram
AU - Platzbecker, Uwe
AU - Diez-Campelo, Maria
AU - Fenaux, Pierre
AU - Haferlach, Torsten
AU - Castellani, Gastone
AU - Della Porta, Matteo Giovanni
PY - 2023
Y1 - 2023
N2 - PURPOSE: Synthetic data are artificial data generated without including any real patient information by an algorithm trained to learn the characteristics of a real source data set and became widely used to accelerate research in life sciences. We aimed to (1) apply generative artificial intelligence to build synthetic data in different hematologic neoplasms; (2) develop a synthetic validation framework to assess data fidelity and privacy preservability; and (3) test the capability of synthetic data to accelerate clinical/translational research in hematology. METHODS: A conditional generative adversarial network architecture was implemented to generate synthetic data. Use cases were myelodysplastic syndromes (MDS) and AML: 7,133 patients were included. A fully explainable validation framework was created to assess fidelity and privacy preservability of synthetic data. RESULTS: We generated MDS/AML synthetic cohorts (including information on clinical features, genomics, treatment, and outcomes) with high fidelity and privacy performances. This technology allowed resolution of lack/incomplete information and data augmentation. We then assessed the potential value of synthetic data on accelerating research in hematology. Starting from 944 patients with MDS available since 2014, we generated a 300% augmented synthetic cohort and anticipated the development of molecular classification and molecular scoring system obtained many years later from 2,043 to 2,957 real patients, respectively. Moreover, starting from 187 MDS treated with luspatercept into a clinical trial, we generated a synthetic cohort that recapitulated all the clinical end points of the study. Finally, we developed a website to enable clinicians generating high-quality synthetic data from an existing biobank of real patients. CONCLUSION: Synthetic data mimic real clinical-genomic features and outcomes, and anonymize patient information. The implementation of this technology allows to increase the scientific use and value of real data, thus accelerating precision medicine in hematology and the conduction of clinical trials.
AB - PURPOSE: Synthetic data are artificial data generated without including any real patient information by an algorithm trained to learn the characteristics of a real source data set and became widely used to accelerate research in life sciences. We aimed to (1) apply generative artificial intelligence to build synthetic data in different hematologic neoplasms; (2) develop a synthetic validation framework to assess data fidelity and privacy preservability; and (3) test the capability of synthetic data to accelerate clinical/translational research in hematology. METHODS: A conditional generative adversarial network architecture was implemented to generate synthetic data. Use cases were myelodysplastic syndromes (MDS) and AML: 7,133 patients were included. A fully explainable validation framework was created to assess fidelity and privacy preservability of synthetic data. RESULTS: We generated MDS/AML synthetic cohorts (including information on clinical features, genomics, treatment, and outcomes) with high fidelity and privacy performances. This technology allowed resolution of lack/incomplete information and data augmentation. We then assessed the potential value of synthetic data on accelerating research in hematology. Starting from 944 patients with MDS available since 2014, we generated a 300% augmented synthetic cohort and anticipated the development of molecular classification and molecular scoring system obtained many years later from 2,043 to 2,957 real patients, respectively. Moreover, starting from 187 MDS treated with luspatercept into a clinical trial, we generated a synthetic cohort that recapitulated all the clinical end points of the study. Finally, we developed a website to enable clinicians generating high-quality synthetic data from an existing biobank of real patients. CONCLUSION: Synthetic data mimic real clinical-genomic features and outcomes, and anonymize patient information. The implementation of this technology allows to increase the scientific use and value of real data, thus accelerating precision medicine in hematology and the conduction of clinical trials.
UR - http://www.scopus.com/inward/record.url?scp=85164234019&partnerID=8YFLogxK
U2 - 10.1200/CCI.23.00021
DO - 10.1200/CCI.23.00021
M3 - Journal article
C2 - 37390377
AN - SCOPUS:85164234019
VL - 7
SP - 1
EP - 22
JO - JCO clinical cancer informatics
JF - JCO clinical cancer informatics
SN - 2473-4276
M1 - e2300021
ER -