Privacy-preserving federated data access and federated learning: Improved data sharing and AI model development in transfusion medicine

被引:0
|
作者
Li, Na [1 ,2 ,3 ]
Lewin, Antoine [4 ]
Ning, Shuoyan [3 ,5 ,6 ,7 ]
Waito, Marianne [8 ]
Zeller, Michelle P. [3 ,5 ,6 ,7 ]
Tinmouth, Alan [9 ,10 ]
Shih, Andrew W. [5 ,11 ]
机构
[1] Univ Calgary, Cumming Sch Med, Dept Community Hlth Sci, Calgary, AB, Canada
[2] McMaster Univ, Dept Comp & Software, Hamilton, ON, Canada
[3] McMaster Univ, Michael G DeGroote Ctr Transfus Res, Hamilton, ON, Canada
[4] Hema Quebec, Med Affairs & Innovat, Montreal, PQ, Canada
[5] McMaster Univ, Dept Pathol & Mol Med, Hamilton, ON, Canada
[6] McMaster Univ, Michael G DeGroote Sch Med, Dept Med, Hamilton, ON, Canada
[7] Canadian Blood Serv, Ancaster, ON, Canada
[8] Canadian Blood Serv, Transplantat Serv, Ottawa, ON, Canada
[9] Ottawa Hosp, Dept Med, Ottawa, ON, Canada
[10] Ottawa Hosp, Res Inst, Ottawa, ON, Canada
[11] Canadian Blood Serv, Ctr Innovat, Ottawa, ON, Canada
来源
TRANSFUSION | 2024年
基金
加拿大自然科学与工程研究理事会;
关键词
blood management; health research methodology; statistics; study design;
D O I
10.1111/trf.18077
中图分类号
R5 [内科学];
学科分类号
1002 ; 100201 ;
摘要
BackgroundHealth data comprise data from different aspects of healthcare including administrative, digital health, and research-oriented data. Together, health data contribute to and inform healthcare operations, patient care, and research. Integrating artificial intelligence (AI) into healthcare requires understanding these data infrastructures and addressing challenges such as data availability, privacy, and governance. Federated learning (FL), a decentralized AI training approach, addresses these challenges by allowing models to learn from diverse datasets without data leaving its source, thus ensuring privacy and security are maintained. This report introduces FL and discusses its potential in transfusion medicine and blood supply chain management.Methods and DiscussionFL can offer significant benefits in transfusion medicine by enhancing predictive analytics, personalized medicine, and operational efficiency. Predictive models trained on diverse datasets by FL can improve accuracy in forecasting blood transfusion demands. Personalized treatment plans can be refined by aggregating patient data from multiple institutions using FL, reducing adverse reactions and improving outcomes. Operational efficiency can also be achieved through precise demand forecasting and optimized logistics. Despite its advantages, FL faces challenges such as data standardization, governance, and bias. Harmonizing diverse data sources and ensuring fair, unbiased models require advanced analytical solutions. Robust IT infrastructure and specialized expertise are needed for successful FL implementation.ConclusionFL represents a transformative approach to AI development in healthcare, particularly in transfusion medicine. By leveraging diverse datasets while maintaining data privacy, FL has the potential to enhance predictions, support personalized treatments, and optimize resource management, ultimately improving patient care and healthcare efficiency.
引用
收藏
页数:7
相关论文
共 50 条
  • [41] NSPFL: A Novel Secure and Privacy-Preserving Federated Learning With Data Integrity Auditing
    Zhang, Zehu
    Li, Yanping
    IEEE TRANSACTIONS ON INFORMATION FORENSICS AND SECURITY, 2024, 19 : 4494 - 4506
  • [42] Splitting chemical structure data sets for federated privacy-preserving machine learning
    Jaak Simm
    Lina Humbeck
    Adam Zalewski
    Noe Sturm
    Wouter Heyndrickx
    Yves Moreau
    Bernd Beck
    Ansgar Schuffenhauer
    Journal of Cheminformatics, 13
  • [43] Splitting chemical structure data sets for federated privacy-preserving machine learning
    Simm, Jaak
    Humbeck, Lina
    Zalewski, Adam
    Sturm, Noe
    Heyndrickx, Wouter
    Moreau, Yves
    Beck, Bernd
    Schuffenhauer, Ansgar
    JOURNAL OF CHEMINFORMATICS, 2021, 13 (01)
  • [44] Federated Learning-Based Privacy-Preserving Data Aggregation Scheme for IIoT
    Fan, Hongbin
    Huang, Changbing
    Liu, Yining
    IEEE ACCESS, 2023, 11 : 6700 - 6707
  • [45] Privacy-Preserving Vertical Federated Learning With Tensor Decomposition for Data Missing Features
    Liao, Tianchi
    Fu, Lele
    Zhang, Lei
    Yang, Lei
    Chen, Chuan
    Ng, Michael K.
    Huang, Huawei
    Zheng, Zibin
    IEEE TRANSACTIONS ON INFORMATION FORENSICS AND SECURITY, 2025, 20 : 3445 - 3460
  • [46] Privacy-Preserving Federated Learning for Power Transformer Fault Diagnosis With Unbalanced Data
    Wu, Qi
    Dong, Chen
    Guo, Fanghong
    Wang, Lei
    Wu, Xiang
    Wen, Changyun
    IEEE TRANSACTIONS ON INDUSTRIAL INFORMATICS, 2024, 20 (04) : 5383 - 5394
  • [47] VFL: A Verifiable Federated Learning With Privacy-Preserving for Big Data in Industrial IoT
    Fu, Anmin
    Zhang, Xianglong
    Xiong, Naixue
    Gao, Yansong
    Wang, Huaqun
    Zhang, Jing
    IEEE TRANSACTIONS ON INDUSTRIAL INFORMATICS, 2022, 18 (05) : 3316 - 3326
  • [48] A privacy-preserving federated learning protocol with a secure data aggregation for the Internet of Everything
    Basudan, Sultan
    COMPUTER COMMUNICATIONS, 2024, 223 : 1 - 14
  • [49] FedER: Federated Learning through Experience Replay and privacy-preserving data synthesis
    Pennisi, Matteo
    Salanitri, Federica Proietto
    Bellitto, Giovanni
    Casella, Bruno
    Aldinucci, Marco
    Palazzo, Simone
    Spampinato, Concetto
    COMPUTER VISION AND IMAGE UNDERSTANDING, 2024, 238
  • [50] Privacy-preserving federated learning based on partial low-quality data
    Huiyong Wang
    Qi Wang
    Yong Ding
    Shijie Tang
    Yujue Wang
    Journal of Cloud Computing, 13
12345