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European Journal of Nuclear Medicine and Molecular Imaging

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01-11-2021 | Artificial Intelligence | Review Article

Distributed learning: a reliable privacy-preserving strategy to change multicenter collaborations using AI

Authors: Margarita Kirienko, Martina Sollini, Gaia Ninatti, Daniele Loiacono, Edoardo Giacomello, Noemi Gozzi, Francesco Amigoni, Luca Mainardi, Pier Luca Lanzi, Arturo Chiti

Published in: European Journal of Nuclear Medicine and Molecular Imaging | Issue 12/2021

Abstract

Purpose

The present scoping review aims to assess the non-inferiority of distributed learning over centrally and locally trained machine learning (ML) models in medical applications.

Methods

We performed a literature search using the term “distributed learning” OR “federated learning” in the PubMed/MEDLINE and EMBASE databases. No start date limit was used, and the search was extended until July 21, 2020. We excluded articles outside the field of interest; guidelines or expert opinion, review articles and meta-analyses, editorials, letters or commentaries, and conference abstracts; articles not in the English language; and studies not using medical data. Selected studies were classified and analysed according to their aim(s).

Results

We included 26 papers aimed at predicting one or more outcomes: namely risk, diagnosis, prognosis, and treatment side effect/adverse drug reaction. Distributed learning was compared to centralized or localized training in 21/26 and 14/26 selected papers, respectively. Regardless of the aim, the type of input, the method, and the classifier, distributed learning performed close to centralized training, but two experiments focused on diagnosis. In all but 2 cases, distributed learning outperformed locally trained models.

Conclusion

Distributed learning resulted in a reliable strategy for model development; indeed, it performed equally to models trained on centralized datasets. Sensitive data can get preserved since they are not shared for model development. Distributed learning constitutes a promising solution for ML-based research and practice since large, diverse datasets are crucial for success.

Sollini M, Antunovic L, Chiti A, Kirienko M. Towards clinical application of image mining: a systematic review on artificial intelligence and radiomics. Eur J Nucl Med Mol Imaging. 2019;46:2656–72.CrossRef

Park JE, Kim D, Kim HS, Park SY, Kim JY, Cho SJ, et al. Quality of science and reporting of radiomics in oncologic studies: room for improvement according to radiomics quality score and TRIPOD statement. Eur Radiol. 2020;30:523–36.CrossRef

Sollini M, Berchiolli R, Delgado Bolton RC, Rossi A, Kirienko M, Boni R, et al. The “3M” approach to cardiovascular infections: multimodality, multitracers, and multidisciplinary. Semin Nucl Med. 2018;48:199–224.CrossRef

Kirienko M, Ninatti G, Cozzi L, Voulaz E, Gennaro N, Barajon I, et al. Computed tomography (CT)-derived radiomic features differentiate prevascular mediastinum masses as thymic neoplasms versus lymphomas. Radiol Med. 2020;125:951–60.CrossRef

Sollini M, Cozzi L, Ninatti G, Antunovic L, Cavinato L, Chiti A, et al. PET/CT radiomics in breast cancer: mind the step. Methods. 2020;S1046–2023:30263–4.

Sollini M, Bartoli F, Marciano A, Zanca R, Slart RHJA, Erba PA. Artificial intelligence and hybrid imaging: the best match for personalized medicine in oncology. Eur J Hybrid Imaging. 2020;4:24.CrossRef

Kaissis GA, Makowski MR, Rückert D, Braren RF. Secure, privacy-preserving and federated machine learning in medical imaging. Nat Mach Intell. 2020.

Konečný J, McMahan B, Ramage D. Federated optimization:distributed optimization beyond the datacenter. 2015;

Zerka F, Barakat S, Walsh S, Bogowicz M, Leijenaar RTH, Jochems A, et al. Systematic review of privacy-preserving distributed machine learning from federated databases in health care. JCO Clin Cancer Informatics. 2020;4:184–200.CrossRef

10.

Verbraeken J, Wolting M, Katzy J, Kloppenburg J, Verbelen T, Rellermeyer JS. A survey on distributed machine learning. ACM Comput Surv. 2020;53:1–33.CrossRef

11.

Dean J, Corrado GS, Monga R, Chen K, Devin M, Le QV, et al. Large scale distributed deep networks. Adv Neural Inf Proces Syst. 2012.

12.

Chang K, Balachandar N, Lam C, Yi D, Brown J, Beers A, et al. Distributed deep learning networks among institutions for medical imaging. J Am Med Inform Assoc. 2018;25:945–54.CrossRef

13.

Vepakomma P, Gupta O, Swedish T, Raskar R. Split learning for health: distributed deep learning without sharing raw patient data. 2018;

14.

Polikar R. Ensemble based systems in decision making. IEEE Circuits Syst Mag. 2006;6:21–45.CrossRef

15.

Wolpert DH. Stacked generalization. Neural Netw. 1992;5:241–59.CrossRef

16.

Gupta O, Raskar R. Distributed learning of deep neural network over multiple agents. J Netw Comput Appl. 2018.

17.

Rieke N, Hancox J, Li W, Milletarì F, Roth HR, Albarqouni S, et al. The future of digital health with federated learning. npj Digit Med. 2020.

18.

Brendan McMahan H, Moore E, Ramage D, Hampson S, Agüera y Arcas B. Communication-efficient learning of deep networks from decentralized data. Proc 20th Int Conf Artif Intell Stat AISTATS 2017. 2017.

19.

Huang L, Shea AL, Qian H, Masurkar A, Deng H, Liu D. Patient clustering improves efficiency of federated machine learning to predict mortality and hospital stay time using distributed electronic medical records. J Biomed Inform. 2019;99:103291.CrossRef

20.

Sheller MJ, Reina GA, Edwards B, Martin J, Bakas S. Multi-institutional deep learning modeling without sharing patient data: a feasibility study on brain tumor segmentation. Brainlesion. 2019;11383:92–104.PubMedPubMedCentral

21.

Li X, Gu Y, Dvornek N, Staib LH, Ventola P, Duncan JS. Multi-site fMRI analysis using privacy-preserving federated learning and domain adaptation: ABIDE results. Med Image Anal. 2020;65:101765.CrossRef

22.

Jochems A, Deist TM, van Soest J, Eble M, Bulens P, Coucke P, et al. Distributed learning: developing a predictive model based on data from multiple hospitals without data leaving the hospital – a real life proof of concept. Radiother Oncol. 2016;121:459–67.CrossRef

23.

Deist TM, Jochems A, van Soest J, Nalbantov G, Oberije C, Walsh S, et al. Infrastructure and distributed learning methodology for privacy-preserving multi-centric rapid learning health care: euroCAT. Clin Transl Radiat Oncol. 2017;4:24–31.CrossRef

24.

Jochems A, Deist TM, El Naqa I, Kessler M, Mayo C, Reeves J, et al. Developing and validating a survival prediction model for NSCLC patients through distributed learning across 3 countries. Int J Radiat Oncol. 2017;99:344–52.CrossRef

25.

Deist TM, Dankers FJWM, Ojha P, Scott Marshall M, Janssen T, Faivre-Finn C, et al. Distributed learning on 20 000+ lung cancer patients – the personal health train. Radiother Oncol. 2020;144:189–200.CrossRef

26.

Dankar FK, Madathil N, Dankar SK, Boughorbel S. Privacy-preserving analysis of distributed biomedical data: designing efficient and secure multiparty computations using distributed statistical learning theory. JMIR Med Inf. 2019;7:e12702.CrossRef

27.

Li Z, Roberts K, Jiang X, Long Q. Distributed learning from multiple EHR databases: contextual embedding models for medical events. J Biomed Inform. 2019.

28.

Lee J, Sun J, Wang F, Wang S, Jun C-H, Jiang X. Privacy-preserving patient similarity learning in a federated environment: development and analysis. JMIR Med Inf. 2018;6:e20.CrossRef

29.

Brisimi TS, Chen R, Mela T, Olshevsky A, Paschalidis IC, Shi W. Federated learning of predictive models from federated electronic health records. Int J Med Inform. 2018;112:59–67.CrossRef

30.

Duan R, Boland MR, Liu Z, Liu Y, Chang HH, Xu H, et al. Learning from electronic health records across multiple sites: a communication-efficient and privacy-preserving distributed algorithm. J Am Med Inform Assoc. 2020;27:376–85.CrossRef

31.

Silva S, Gutman BA, Romero E, Thompson PM, Altmann A, Lorenzi M. Federated learning in distributed medical databases: meta-analysis of large-scale subcortical brain data. 2019 IEEE 16th Int Symp biomed imaging (ISBI 2019). IEEE; 2019. p. 270–4.

32.

Remedios SW, Roy S, Bermudez C, Patel MB, Butman JA, Landman BA, et al. Distributed deep learning across multisite datasets for generalized CT hemorrhage segmentation. Med Phys. 2020;47:89–98.CrossRef

33.

Remedios S, Roy S, Blaber J, Bermudez C, Nath V, Patel MB, et al. Distributed deep learning for robust multi-site segmentation of CT imaging after traumatic brain injury. In: Angelini ED, Landman BA, editors. Med Imaging 2019 Image process. SPIE; 2019. p. 9.

34.

Balachandar N, Chang K, Kalpathy-Cramer J, Rubin DL. Accounting for data variability in multi-institutional distributed deep learning for medical imaging. J Am Med Inform Assoc. 2020;27:700–8.CrossRef

35.

Wu X, Zheng H, Dou Z, Chen F, Deng J, Chen X, et al. A novel privacy-preserving federated genome-wide association study framework and its application in identifying potential risk variants in ankylosing spondylitis. Brief Bioinform. 2020;

36.

Xu Y, Ma L, Yang F, Chen Y, Ma K, Yang J, et al. A collaborative online AI engine for CT-based COVID-19 diagnosis. medRxiv Prepr Serv Heal Sci. 2020.

37.

Choudhury O, Park Y, Salonidis T, Gkoulalas-Divanis A, Sylla I, Das AK. Predicting adverse drug reactions on distributed health data using federated learning. AMIA Annu Symp Proc AMIA Symp. 2019;2019:313–22.PubMed

38.

Wang Y, Hong C, Palmer N, Di Q, Schwartz J, Kohane I, et al. A fast divide-and-conquer sparse Cox regression. Biostatistics. 2019.

39.

Xie J, Liu S, Dai H. Manifold regularization based distributed semi-supervised learning algorithm using extreme learning machine over time-varying network. Neurocomputing. 2019.

40.

Dluhoš P, Schwarz D, Cahn W, van Haren N, Kahn R, Španiel F, et al. Multi-center machine learning in imaging psychiatry: a meta-model approach. Neuroimage. 2017.

41.

Scardapane S, Di Lorenzo P. A framework for parallel and distributed training of neural networks. Neural Netw. 2017.

42.

Tuladhar A, Gill S, Ismail Z, Forkert ND. Building machine learning models without sharing patient data: a simulation-based analysis of distributed learning by ensembling. J Biomed Inform. 2020.

43.

Bogowicz M, Jochems A, Deist TM, Tanadini-Lang S, Huang SH, Chan B, et al. Privacy-preserving distributed learning of radiomics to predict overall survival and HPV status in head and neck cancer. Sci Rep. 2020.

44.

Sheller MJ, Edwards B, Reina GA, Martin J, Pati S, Kotrotsou A, et al. Federated learning in medicine: facilitating multi-institutional collaborations without sharing patient data. Sci Rep. 2020;10:12598.CrossRef

45.

Bhaskar H, Hoyle DC, Singh S. Machine learning in bioinformatics: a brief survey and recommendations for practitioners. Comput Biol Med. 2006;36:1104–25.CrossRef

46.

Sollini M, Gelardi F, Matassa G, Delgado Bolton RC, Chiti A, Kirienko M. Interdisciplinarity: an essential requirement for translation of radiomics research into clinical practice – a systematic review focused on thoracic oncology. Rev Española med Nucl e Imagen Mol (English Ed) SEMNIM. 2020;39:146–56.

47.

Bruynseels K, Santoni de Sio F, van den Hoven J. Digital twins in health care: ethical implications of an emerging engineering paradigm. Front Genet. 2018;9.

48.

Björnsson B, Borrebaeck C, Elander N, Gasslander T, Gawel DR, Gustafsson M, et al. Digital twins to personalize medicine. Genome Med. 2019.

49.

Oncoradiomics - Radiomics research Software - Clinical A.I platform [Internet]. [cited 2020 Nov 9]. Available from: https://www.oncoradiomics.com/.

50.

Home [Internet]. [cited 2020 Nov 9]. Available from: https://distributedlearning.ai/.

51.

NVIDIA Clara Platform to Usher in Next Generation of Medical Instruments | NVIDIA Blog [Internet]. [cited 2020 Nov 9]. Available from: https://blogs.nvidia.com/blog/2018/09/12/nvidia-clara-platform/.

52.

Mandl KD, Glauser T, Krantz ID, Avillach P, Bartels A, Beggs AH, et al. The genomics research and innovation network: creating an interoperable, federated, genomics learning system. Genet Med. 2020;22:371–80.CrossRef

53.

Kirienko M, Biroli M, Gelardi F, Seregni E, Chiti A, Sollini M. Deep learning in nuclear medicine—focus on CNN-based approaches for PET/CT and PET/MR: where do we stand? Clin Transl Imaging. Springer. 2021:1–19.

54.

Barredo Arrieta A, Díaz-Rodríguez N, Del Ser J, Bennetot A, Tabik S, Barbado A, et al. Explainable artificial intelligence (XAI): concepts, taxonomies, opportunities and challenges toward responsible AI. Inf Fusion Elsevier. 2020;58:82–115.CrossRef

55.

Weeks J, Pardee R. Learning to share health care data: a brief timeline of influential common data models and distributed health data networks in U.S. Health Care Research. eGEMs (Generating Evid Methods to Improv patient outcomes). 2019;7:4.

56.

Bilimoria KY, Stewart AK, Winchester DP, Ko CY. The national cancer data base: a powerful initiative to improve cancer care in the United States. Ann Surg Oncol. 2008;15:683–90.CrossRef

57.

Shah A, Stewart AK, Kolacevski A, Michels D, Miller R. Building a rapid learning health care system for oncology: why CancerLinQ collects identifiable health information to achieve its vision. J Clin Oncol. 2016;34:756–63.CrossRef

58.

D’Amour A, Heller K, Moldovan D, Adlam B, Alipanahi B, Beutel A, et al. Underspecification presents challenges for credibility in modern machine learning. 2020;

59.

Claerhout B, Kalra D, Mueller C, Singh G, Ammour N, Meloni L, et al. Federated electronic health records research technology to support clinical trial protocol optimization: evidence from EHR4CR and the InSite platform. J Biomed Inform. 2019;90:103090.CrossRef

Title: Distributed learning: a reliable privacy-preserving strategy to change multicenter collaborations using AI
Authors: Margarita Kirienko
Martina Sollini
Gaia Ninatti
Daniele Loiacono
Edoardo Giacomello
Noemi Gozzi
Francesco Amigoni
Luca Mainardi
Pier Luca Lanzi
Arturo Chiti
Publication date: 01-11-2021
Publisher: Springer Berlin Heidelberg
Keyword: Artificial Intelligence
Published in: European Journal of Nuclear Medicine and Molecular Imaging / Issue 12/2021
Print ISSN: 1619-7070
Electronic ISSN: 1619-7089
DOI: https://doi.org/10.1007/s00259-021-05339-7

2024 ASCO Annual Meeting

Springer Medicine

Distributed learning: a reliable privacy-preserving strategy to change multicenter collaborations using AI

Abstract

Purpose

Methods

Results

Conclusion

2024 ASCO Annual Meeting

Springer Medicine

Abstract

Purpose

Methods

Results

Conclusion

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