Resilience-aware MLOps for AI-based medical diagnostic system

The healthcare sector demands a higher degree of responsibility, trustworthiness, and accountability when implementing Artificial Intelligence (AI) systems. Machine learning operations (MLOps) for AI-based medical diagnostic systems are primarily focused on aspects such as data quality and confident...

Celý popis

Uložené v:
Podrobná bibliografia
Vydané v:Frontiers in public health Ročník 12; s. 1342937
Hlavní autori: Moskalenko, Viacheslav, Kharchenko, Vyacheslav
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Switzerland Frontiers Media S.A 27.03.2024
Predmet:
Artificial Intelligence
Awareness
Data Accuracy
image recognition
Machine Learning
medical diagnosis
MLOps
Public Health
resilience
Resilience, Psychological
robustness
medical diagnosis
robustness
MLOps
resilience
image recognition
ISSN:2296-2565, 2296-2565
On-line prístup:Získať plný text
Tagy: Pridať tag
Žiadne tagy, Buďte prvý, kto otaguje tento záznam!
Abstract The healthcare sector demands a higher degree of responsibility, trustworthiness, and accountability when implementing Artificial Intelligence (AI) systems. Machine learning operations (MLOps) for AI-based medical diagnostic systems are primarily focused on aspects such as data quality and confidentiality, bias reduction, model deployment, performance monitoring, and continuous improvement. However, so far, MLOps techniques do not take into account the need to provide resilience to disturbances such as adversarial attacks, including fault injections, and drift, including out-of-distribution. This article is concerned with the MLOps methodology that incorporates the steps necessary to increase the resilience of an AI-based medical diagnostic system against various kinds of disruptive influences. resilience optimization, predictive uncertainty calibration, uncertainty monitoring, and graceful degradation are incorporated as additional stages in MLOps. To optimize the resilience of the AI based medical diagnostic system, additional components in the form of adapters and meta-adapters are utilized. These components are fine-tuned during meta-training based on the results of adaptation to synthetic disturbances. Furthermore, an additional model is introduced for calibration of predictive uncertainty. This model is trained using both in-distribution and out-of-distribution data to refine predictive confidence during the inference mode. The structure of resilience-aware MLOps for medical diagnostic systems has been proposed. Experimentally confirmed increase of robustness and speed of adaptation for medical image recognition system during several intervals of the system's life cycle due to the use of resilience optimization and uncertainty calibration stages. The experiments were performed on the DermaMNIST dataset, BloodMNIST and PathMNIST. ResNet-18 as a representative of convolutional networks and MedViT-T as a representative of visual transformers are considered. It is worth noting that transformers exhibited lower resilience than convolutional networks, although this observation may be attributed to potential imperfections in the architecture of adapters and meta-adapters. The main novelty of the suggested resilience-aware MLOps methodology and structure lie in the separating possibilities and activities on creating a basic model for normal operating conditions and ensuring its resilience and trustworthiness. This is significant for the medical applications as the developer of the basic model should devote more time to comprehending medical field and the diagnostic task at hand, rather than specializing in system resilience. Resilience optimization increases robustness to disturbances and speed of adaptation. Calibrated confidences ensure the recognition of a portion of unabsorbed disturbances to mitigate their impact, thereby enhancing trustworthiness.
AbstractList The healthcare sector demands a higher degree of responsibility, trustworthiness, and accountability when implementing Artificial Intelligence (AI) systems. Machine learning operations (MLOps) for AI-based medical diagnostic systems are primarily focused on aspects such as data quality and confidentiality, bias reduction, model deployment, performance monitoring, and continuous improvement. However, so far, MLOps techniques do not take into account the need to provide resilience to disturbances such as adversarial attacks, including fault injections, and drift, including out-of-distribution. This article is concerned with the MLOps methodology that incorporates the steps necessary to increase the resilience of an AI-based medical diagnostic system against various kinds of disruptive influences.BackgroundThe healthcare sector demands a higher degree of responsibility, trustworthiness, and accountability when implementing Artificial Intelligence (AI) systems. Machine learning operations (MLOps) for AI-based medical diagnostic systems are primarily focused on aspects such as data quality and confidentiality, bias reduction, model deployment, performance monitoring, and continuous improvement. However, so far, MLOps techniques do not take into account the need to provide resilience to disturbances such as adversarial attacks, including fault injections, and drift, including out-of-distribution. This article is concerned with the MLOps methodology that incorporates the steps necessary to increase the resilience of an AI-based medical diagnostic system against various kinds of disruptive influences.Post-hoc resilience optimization, post-hoc predictive uncertainty calibration, uncertainty monitoring, and graceful degradation are incorporated as additional stages in MLOps. To optimize the resilience of the AI based medical diagnostic system, additional components in the form of adapters and meta-adapters are utilized. These components are fine-tuned during meta-training based on the results of adaptation to synthetic disturbances. Furthermore, an additional model is introduced for post-hoc calibration of predictive uncertainty. This model is trained using both in-distribution and out-of-distribution data to refine predictive confidence during the inference mode.MethodsPost-hoc resilience optimization, post-hoc predictive uncertainty calibration, uncertainty monitoring, and graceful degradation are incorporated as additional stages in MLOps. To optimize the resilience of the AI based medical diagnostic system, additional components in the form of adapters and meta-adapters are utilized. These components are fine-tuned during meta-training based on the results of adaptation to synthetic disturbances. Furthermore, an additional model is introduced for post-hoc calibration of predictive uncertainty. This model is trained using both in-distribution and out-of-distribution data to refine predictive confidence during the inference mode.The structure of resilience-aware MLOps for medical diagnostic systems has been proposed. Experimentally confirmed increase of robustness and speed of adaptation for medical image recognition system during several intervals of the system's life cycle due to the use of resilience optimization and uncertainty calibration stages. The experiments were performed on the DermaMNIST dataset, BloodMNIST and PathMNIST. ResNet-18 as a representative of convolutional networks and MedViT-T as a representative of visual transformers are considered. It is worth noting that transformers exhibited lower resilience than convolutional networks, although this observation may be attributed to potential imperfections in the architecture of adapters and meta-adapters.ResultsThe structure of resilience-aware MLOps for medical diagnostic systems has been proposed. Experimentally confirmed increase of robustness and speed of adaptation for medical image recognition system during several intervals of the system's life cycle due to the use of resilience optimization and uncertainty calibration stages. The experiments were performed on the DermaMNIST dataset, BloodMNIST and PathMNIST. ResNet-18 as a representative of convolutional networks and MedViT-T as a representative of visual transformers are considered. It is worth noting that transformers exhibited lower resilience than convolutional networks, although this observation may be attributed to potential imperfections in the architecture of adapters and meta-adapters.The main novelty of the suggested resilience-aware MLOps methodology and structure lie in the separating possibilities and activities on creating a basic model for normal operating conditions and ensuring its resilience and trustworthiness. This is significant for the medical applications as the developer of the basic model should devote more time to comprehending medical field and the diagnostic task at hand, rather than specializing in system resilience. Resilience optimization increases robustness to disturbances and speed of adaptation. Calibrated confidences ensure the recognition of a portion of unabsorbed disturbances to mitigate their impact, thereby enhancing trustworthiness.СonclusionThe main novelty of the suggested resilience-aware MLOps methodology and structure lie in the separating possibilities and activities on creating a basic model for normal operating conditions and ensuring its resilience and trustworthiness. This is significant for the medical applications as the developer of the basic model should devote more time to comprehending medical field and the diagnostic task at hand, rather than specializing in system resilience. Resilience optimization increases robustness to disturbances and speed of adaptation. Calibrated confidences ensure the recognition of a portion of unabsorbed disturbances to mitigate their impact, thereby enhancing trustworthiness.
BackgroundThe healthcare sector demands a higher degree of responsibility, trustworthiness, and accountability when implementing Artificial Intelligence (AI) systems. Machine learning operations (MLOps) for AI-based medical diagnostic systems are primarily focused on aspects such as data quality and confidentiality, bias reduction, model deployment, performance monitoring, and continuous improvement. However, so far, MLOps techniques do not take into account the need to provide resilience to disturbances such as adversarial attacks, including fault injections, and drift, including out-of-distribution. This article is concerned with the MLOps methodology that incorporates the steps necessary to increase the resilience of an AI-based medical diagnostic system against various kinds of disruptive influences.MethodsPost-hoc resilience optimization, post-hoc predictive uncertainty calibration, uncertainty monitoring, and graceful degradation are incorporated as additional stages in MLOps. To optimize the resilience of the AI based medical diagnostic system, additional components in the form of adapters and meta-adapters are utilized. These components are fine-tuned during meta-training based on the results of adaptation to synthetic disturbances. Furthermore, an additional model is introduced for post-hoc calibration of predictive uncertainty. This model is trained using both in-distribution and out-of-distribution data to refine predictive confidence during the inference mode.ResultsThe structure of resilience-aware MLOps for medical diagnostic systems has been proposed. Experimentally confirmed increase of robustness and speed of adaptation for medical image recognition system during several intervals of the system’s life cycle due to the use of resilience optimization and uncertainty calibration stages. The experiments were performed on the DermaMNIST dataset, BloodMNIST and PathMNIST. ResNet-18 as a representative of convolutional networks and MedViT-T as a representative of visual transformers are considered. It is worth noting that transformers exhibited lower resilience than convolutional networks, although this observation may be attributed to potential imperfections in the architecture of adapters and meta-adapters.СonclusionThe main novelty of the suggested resilience-aware MLOps methodology and structure lie in the separating possibilities and activities on creating a basic model for normal operating conditions and ensuring its resilience and trustworthiness. This is significant for the medical applications as the developer of the basic model should devote more time to comprehending medical field and the diagnostic task at hand, rather than specializing in system resilience. Resilience optimization increases robustness to disturbances and speed of adaptation. Calibrated confidences ensure the recognition of a portion of unabsorbed disturbances to mitigate their impact, thereby enhancing trustworthiness.
The healthcare sector demands a higher degree of responsibility, trustworthiness, and accountability when implementing Artificial Intelligence (AI) systems. Machine learning operations (MLOps) for AI-based medical diagnostic systems are primarily focused on aspects such as data quality and confidentiality, bias reduction, model deployment, performance monitoring, and continuous improvement. However, so far, MLOps techniques do not take into account the need to provide resilience to disturbances such as adversarial attacks, including fault injections, and drift, including out-of-distribution. This article is concerned with the MLOps methodology that incorporates the steps necessary to increase the resilience of an AI-based medical diagnostic system against various kinds of disruptive influences. resilience optimization, predictive uncertainty calibration, uncertainty monitoring, and graceful degradation are incorporated as additional stages in MLOps. To optimize the resilience of the AI based medical diagnostic system, additional components in the form of adapters and meta-adapters are utilized. These components are fine-tuned during meta-training based on the results of adaptation to synthetic disturbances. Furthermore, an additional model is introduced for calibration of predictive uncertainty. This model is trained using both in-distribution and out-of-distribution data to refine predictive confidence during the inference mode. The structure of resilience-aware MLOps for medical diagnostic systems has been proposed. Experimentally confirmed increase of robustness and speed of adaptation for medical image recognition system during several intervals of the system's life cycle due to the use of resilience optimization and uncertainty calibration stages. The experiments were performed on the DermaMNIST dataset, BloodMNIST and PathMNIST. ResNet-18 as a representative of convolutional networks and MedViT-T as a representative of visual transformers are considered. It is worth noting that transformers exhibited lower resilience than convolutional networks, although this observation may be attributed to potential imperfections in the architecture of adapters and meta-adapters. The main novelty of the suggested resilience-aware MLOps methodology and structure lie in the separating possibilities and activities on creating a basic model for normal operating conditions and ensuring its resilience and trustworthiness. This is significant for the medical applications as the developer of the basic model should devote more time to comprehending medical field and the diagnostic task at hand, rather than specializing in system resilience. Resilience optimization increases robustness to disturbances and speed of adaptation. Calibrated confidences ensure the recognition of a portion of unabsorbed disturbances to mitigate their impact, thereby enhancing trustworthiness.
Author Kharchenko, Vyacheslav
Moskalenko, Viacheslav
AuthorAffiliation 2 Department of Computer Systems, Network and Cybersecurity, Faculty of Radio-Electronics, Computer Systems and Infocommunications, National Aerospace University “KhAI” , Kharkiv , Ukraine
1 Department of Computer Science, Faculty of Electronics and Information Technologies, Sumy State University , Sumy , Ukraine
AuthorAffiliation_xml – name: 1 Department of Computer Science, Faculty of Electronics and Information Technologies, Sumy State University , Sumy , Ukraine
– name: 2 Department of Computer Systems, Network and Cybersecurity, Faculty of Radio-Electronics, Computer Systems and Infocommunications, National Aerospace University “KhAI” , Kharkiv , Ukraine
Author_xml – sequence: 1
  givenname: Viacheslav
  surname: Moskalenko
  fullname: Moskalenko, Viacheslav
– sequence: 2
  givenname: Vyacheslav
  surname: Kharchenko
  fullname: Kharchenko, Vyacheslav
BackLink https://www.ncbi.nlm.nih.gov/pubmed/38601490$$D View this record in MEDLINE/PubMed
BookMark eNp9UU1v1DAQtVARLaV_gAPKkUuW8Uec-IBQVfGx0qJKCM7WxBlvXWXjxc6C-u_xdpeq5cDBsjV-896beS_ZyRQnYuw1h4WUnXnnt7v-ZiFAqAWXShjZPmNnQhhdi0Y3J4_ep-wi51sA4CAVCP6CncpOA1cGztj7b5TDGGhyVONvTFR9XV1vc-Vjqi6XdY-ZhmpDQ3A4VkPA9RTzHFyV7_JMm1fsuccx08XxPmc_Pn38fvWlXl1_Xl5drmqntJlrbIqu68XeLRqS2HaSNCH0GjpfpmndoAdJAOi86XrXdL4zispBpUjIc7Y88A4Rb-02hQ2mOxsx2PtCTGuLqdgayUottOBOSnBKNdCj1uA9DJ4MiUFC4fpw4CoLLIM5muaE4xPSpz9TuLHr-MtyDqCE1IXh7ZEhxZ87yrPdhOxoHHGiuMu2iLTStK2SBfrmsdiDyt8ACkAcAC7FnBP5BwgHuw_a3gdt96uzx6BLU_dPkwszziHuDYfxf61_AE3orYg
CitedBy_id crossref_primary_10_1007_s00330_025_11654_6
crossref_primary_10_3390_info16020087
crossref_primary_10_1109_ACCESS_2025_3606838
crossref_primary_10_3390_s24185951
crossref_primary_10_2196_66559
crossref_primary_10_1002_pros_24871
crossref_primary_10_1016_j_engappai_2024_109649
crossref_primary_10_3390_app15052628
Cites_doi 10.1109/comst.2020.3036778
10.3390/app12199851
10.1109/tii.2022.3149935
10.1109/tkde.2022.3178128
10.1007/s10994-023-06336-7
10.1016/B978-0-12-824020-5.00028-4
10.1016/j.media.2021.102141
10.54517/m.v4i1.2156
10.3389/frai.2022.950659
10.32620/reks.2020.3.05
10.1007/s11219-022-09601-5
10.1016/j.compbiomed.2023.106848
10.1109/jsait.2020.2991430
10.1371/journal.pone.0265723
10.1007/978-3-030-40245-7_15
10.1007/978-3-030-86365-4_54
10.1016/j.artmed.2023.102718
10.1109/tnnls.2022.3183120
10.3390/app12031353
10.3390/a16030165
10.30844/wi_2020_c1-baier
10.15588/1607-3274-2023-2-9
10.3233/jifs-179677
10.1038/s42256-023-00626-4
10.1016/j.cose.2021.102367
10.1109/tai.2022.3159510
10.32620/reks.2020.1.02
10.1109/tpami.2022.3191696
10.1016/j.compbiomed.2023.106791
10.1148/radiol.2020200038
10.2478/s13537-011-0025-x
10.1109/access.2022.3181730
ContentType Journal Article
Copyright Copyright © 2024 Moskalenko and Kharchenko.
Copyright © 2024 Moskalenko and Kharchenko. 2024 Moskalenko and Kharchenko
Copyright_xml – notice: Copyright © 2024 Moskalenko and Kharchenko.
– notice: Copyright © 2024 Moskalenko and Kharchenko. 2024 Moskalenko and Kharchenko
DBID AAYXX
CITATION
CGR
CUY
CVF
ECM
EIF
NPM
7X8
5PM
DOA
DOI 10.3389/fpubh.2024.1342937
DatabaseName CrossRef
Medline
MEDLINE
MEDLINE (Ovid)
MEDLINE
MEDLINE
PubMed
MEDLINE - Academic
PubMed Central (Full Participant titles)
DOAJ Directory of Open Access Journals
DatabaseTitle CrossRef
MEDLINE
Medline Complete
MEDLINE with Full Text
PubMed
MEDLINE (Ovid)
MEDLINE - Academic
DatabaseTitleList MEDLINE - Academic

MEDLINE
Database_xml – sequence: 1
  dbid: DOA
  name: DOAJ Directory of Open Access Journals
  url: https://www.doaj.org/
  sourceTypes: Open Website
– sequence: 2
  dbid: NPM
  name: PubMed
  url: http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed
  sourceTypes: Index Database
– sequence: 3
  dbid: 7X8
  name: MEDLINE - Academic
  url: https://search.proquest.com/medline
  sourceTypes: Aggregation Database
DeliveryMethod fulltext_linktorsrc
Discipline Public Health
EISSN 2296-2565
ExternalDocumentID oai_doaj_org_article_362621c330c4450ba660ff0dfe9e2d30
PMC11004236
38601490
10_3389_fpubh_2024_1342937
Genre Journal Article
GroupedDBID 53G
5VS
9T4
AAFWJ
AAYXX
ACGFO
ACGFS
ADBBV
ADRAZ
AFPKN
ALMA_UNASSIGNED_HOLDINGS
AOIJS
BAWUL
BCNDV
CITATION
DIK
EMOBN
GROUPED_DOAJ
GX1
HYE
KQ8
M48
M~E
OK1
RNS
RPM
ACXDI
CGR
CUY
CVF
ECM
EIF
IPNFZ
NPM
RIG
7X8
5PM
ID FETCH-LOGICAL-c469t-a5402cb22024a9e3a783e6ea0b608f3897cd6d3e00acf98bc58f894e894a44e23
IEDL.DBID DOA
ISICitedReferencesCount 9
ISICitedReferencesURI http://www.webofscience.com/api/gateway?GWVersion=2&SrcApp=Summon&SrcAuth=ProQuest&DestLinkType=CitingArticles&DestApp=WOS_CPL&KeyUT=001198920600001&url=https%3A%2F%2Fcvtisr.summon.serialssolutions.com%2F%23%21%2Fsearch%3Fho%3Df%26include.ft.matches%3Dt%26l%3Dnull%26q%3D
ISSN 2296-2565
IngestDate Fri Oct 03 12:41:22 EDT 2025
Thu Aug 21 18:34:28 EDT 2025
Fri Sep 05 06:04:42 EDT 2025
Mon Jul 21 05:55:53 EDT 2025
Sat Nov 29 04:16:39 EST 2025
Tue Nov 18 22:35:19 EST 2025
IsDoiOpenAccess true
IsOpenAccess true
IsPeerReviewed true
IsScholarly true
Keywords medical diagnosis
robustness
MLOps
resilience
image recognition
Language English
License Copyright © 2024 Moskalenko and Kharchenko.
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
LinkModel DirectLink
MergedId FETCHMERGED-LOGICAL-c469t-a5402cb22024a9e3a783e6ea0b608f3897cd6d3e00acf98bc58f894e894a44e23
Notes ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
John Plodinec, Independent Researcher, Aiken, SC, United States
Edited by: Tetyana Chumachenko, Kharkiv National Medical University, Ukraine
Reviewed by: Gilbert Yong San Lim, SingHealth, Singapore
OpenAccessLink https://doaj.org/article/362621c330c4450ba660ff0dfe9e2d30
PMID 38601490
PQID 3037397743
PQPubID 23479
ParticipantIDs doaj_primary_oai_doaj_org_article_362621c330c4450ba660ff0dfe9e2d30
pubmedcentral_primary_oai_pubmedcentral_nih_gov_11004236
proquest_miscellaneous_3037397743
pubmed_primary_38601490
crossref_primary_10_3389_fpubh_2024_1342937
crossref_citationtrail_10_3389_fpubh_2024_1342937
PublicationCentury 2000
PublicationDate 2024-03-27
PublicationDateYYYYMMDD 2024-03-27
PublicationDate_xml – month: 03
  year: 2024
  text: 2024-03-27
  day: 27
PublicationDecade 2020
PublicationPlace Switzerland
PublicationPlace_xml – name: Switzerland
PublicationTitle Frontiers in public health
PublicationTitleAlternate Front Public Health
PublicationYear 2024
Publisher Frontiers Media S.A
Publisher_xml – name: Frontiers Media S.A
References Huang (ref24) 2020; 1
Li (ref34) 2020
Wang (ref21) 2022; 35
Gupta (ref4) 2019
Duddu (ref14) 2020; 38
Stirbu (ref2) 2022; 31
Olowononi (ref13) 2021; 23
Niemelä (ref5) 2022
Khattak (ref6) 2023
Xu (ref10) 2020
Islam (ref25) 2022; 12
Zhang (ref12) 2022
Vassilev (ref36) 2023
Nirmala (ref17) 2022; 5
Bortsova (ref18) 2021; 73
Lusenko (ref49) 2020; 1
Qiu (ref33) 2020
Abusnaina (ref22) 2021
Ponochovnyi (ref48) 2020; 3
Pianykh (ref30) 2020; 297
Testi (ref1) 2022; 10
Kalin (ref9) 2022
Shen (ref39) 2022
Xu (ref35) 2019
Moskalenko (ref16) 2023; 16
Moskalenko (ref41) 2023; 2
Dymond (ref46) 2021
Silva Filho (ref44) 2023; 112
Kotyan (ref45) 2022; 17
Liu (ref31) 2023; 147
Song (ref50) 2020
Chen (ref38) 2023
Li (ref42) 2018
Jiao (ref32) 2024; 35
Hou (ref40) 2021
Ding (ref37) 2023; 5
Pourpanah (ref26) 2022; 45
Yang (ref11) 2021; 12893
Subramanya (ref3) 2022; 12
Manzari (ref51) 2023; 157
Peng (ref43) 2023; 19
Khalid (ref7) 2023; 158
Guelfi (ref47) 2011; 1
Fang (ref8) 2023; 4
Achddou (ref28) 2021
Baier (ref27) 2020
Shapeev (ref29) 2020; 968
Duy (ref15) 2021; 109
Karimi (ref23) 2023; 4
Awais (ref19) 2021
Gongye (ref20) 2020
References_xml – volume: 23
  start-page: 524
  year: 2021
  ident: ref13
  article-title: Resilient machine learning for networked cyber physical systems: a survey for machine learning security to securing machine learning for CPS
  publication-title: IEEE Commun Surv Tutor
  doi: 10.1109/comst.2020.3036778
– volume: 12
  start-page: 9851
  year: 2022
  ident: ref3
  article-title: From dev ops to MLOps: overview and application to electricity market forecasting
  publication-title: Appl Sci
  doi: 10.3390/app12199851
– year: 2022
  ident: ref39
– volume: 19
  start-page: 2463
  year: 2023
  ident: ref43
  article-title: Open-set fault diagnosis via supervised contrastive learning with negative out-of-distribution data augmentation
  publication-title: IEEE Trans Industr Inform
  doi: 10.1109/tii.2022.3149935
– volume: 35
  start-page: 1
  year: 2022
  ident: ref21
  article-title: Generalizing to unseen domains: a survey on domain generalization
  publication-title: IEEE Trans Knowl Data Eng
  doi: 10.1109/tkde.2022.3178128
– volume: 112
  start-page: 3211
  year: 2023
  ident: ref44
  article-title: Classifier calibration: a survey on how to assess and improve predicted class probabilities
  publication-title: Mach Learn
  doi: 10.1007/s10994-023-06336-7
– year: 2019
  ident: ref35
– year: 2021
  ident: ref40
– start-page: 183
  volume-title: Adversarial Robustness for Machine Learning
  year: 2023
  ident: ref38
  article-title: Adversarial robustness in meta-learning and contrastive learning
  doi: 10.1016/B978-0-12-824020-5.00028-4
– volume: 73
  start-page: 102141
  year: 2021
  ident: ref18
  article-title: Adversarial attack vulnerability of medical image analysis systems: unexplored factors
  publication-title: Med Image Anal
  doi: 10.1016/j.media.2021.102141
– volume: 4
  start-page: 17
  year: 2023
  ident: ref8
  article-title: A survey on adversarial attack and defense of deep learning models for medical image recognition
  publication-title: Meta
  doi: 10.54517/m.v4i1.2156
– volume: 5
  start-page: 950659
  year: 2022
  ident: ref17
  article-title: A novel technique for detecting sudden concept drift in healthcare data using multi-linear artificial intelligence techniques
  publication-title: Front Artific Intellig
  doi: 10.3389/frai.2022.950659
– volume: 3
  start-page: 43
  year: 2020
  ident: ref48
  article-title: Dependability assurance methodology of information and control systems using multipurpose service strategies
  publication-title: Radioelectron Comput Syst
  doi: 10.32620/reks.2020.3.05
– year: 2021
  ident: ref46
– volume: 31
  start-page: 307
  year: 2022
  ident: ref2
  article-title: Continuous design control for machine learning in certified medical systems
  publication-title: Softw Qual J
  doi: 10.1007/s11219-022-09601-5
– volume: 158
  start-page: 106848
  year: 2023
  ident: ref7
  article-title: Privacy-preserving artificial intelligence in healthcare: techniques and applications
  publication-title: Comput Biol Med
  doi: 10.1016/j.compbiomed.2023.106848
– volume: 1
  start-page: 267
  year: 2020
  ident: ref24
  article-title: Functional error correction for robust neural networks
  publication-title: IEEE J Select Areas Info Theory
  doi: 10.1109/jsait.2020.2991430
– volume: 17
  start-page: e0265723
  year: 2022
  ident: ref45
  article-title: Adversarial robustness assessment: why in evaluation both L0 and L∞ attacks are necessary
  publication-title: PLoS One
  doi: 10.1371/journal.pone.0265723
– year: 2020
  ident: ref10
– volume: 968
  start-page: 309
  year: 2020
  ident: ref29
  article-title: Active learning and uncertainty estimation
  publication-title: Mach Learn Meets Quant Phys
  doi: 10.1007/978-3-030-40245-7_15
– volume: 12893
  start-page: 671
  year: 2021
  ident: ref11
  article-title: Uncertainty quantification and estimation in medical image classification
  publication-title: Lect Notes Comput Sci
  doi: 10.1007/978-3-030-86365-4_54
– year: 2021
  ident: ref22
– volume: 147
  start-page: 102718
  year: 2023
  ident: ref31
  article-title: A few-shot disease diagnosis decision making model based on meta-learning for general practice
  publication-title: Artif Intell Med
  doi: 10.1016/j.artmed.2023.102718
– volume: 35
  start-page: 1278
  year: 2024
  ident: ref32
  article-title: Dynamic ensemble selection for imbalanced data streams with concept drift
  publication-title: IEEE Trans Neural Netw Learn Syst
  doi: 10.1109/tnnls.2022.3183120
– year: 2020
  ident: ref34
– volume: 12
  start-page: 1353
  year: 2022
  ident: ref25
  article-title: A systematic review of explainable artificial intelligence in terms of different application domains and tasks
  publication-title: Appl Sci
  doi: 10.3390/app12031353
– year: 2018
  ident: ref42
– year: 2020
  ident: ref20
– year: 2023
  ident: ref6
– volume: 16
  start-page: 165
  year: 2023
  ident: ref16
  article-title: Resilience and resilient systems of artificial intelligence: taxonomy, models and methods
  publication-title: Algorithms
  doi: 10.3390/a16030165
– year: 2021
  ident: ref19
– start-page: 210
  volume-title: WI2020 Zentrale Tracks.
  year: 2020
  ident: ref27
  article-title: Handling concept drifts in regression problems—the error intersection approach
  doi: 10.30844/wi_2020_c1-baier
– year: 2020
  ident: ref33
– year: 2021
  ident: ref28
– year: 2020
  ident: ref50
– volume: 2
  start-page: 79
  year: 2023
  ident: ref41
  article-title: Model-agnostic Meta-learning for resilience optimization of artificial intelligence system
  publication-title: Radio Electron Comput Sci Control
  doi: 10.15588/1607-3274-2023-2-9
– year: 2022
  ident: ref5
– volume: 38
  start-page: 5897
  year: 2020
  ident: ref14
  article-title: Fault tolerance of neural networks in adversarial settings
  publication-title: IFS
  doi: 10.3233/jifs-179677
– year: 2022
  ident: ref12
– volume: 5
  start-page: 220
  year: 2023
  ident: ref37
  article-title: Parameter-efficient fine-tuning of large-scale pre-trained language models
  publication-title: Nat Mach Intellig
  doi: 10.1038/s42256-023-00626-4
– volume: 109
  start-page: 102367
  year: 2021
  ident: ref15
  article-title: DIGFuPAS: deceive IDS with GAN and function-preserving on adversarial samples in SDN-enabled networks
  publication-title: Comput Secur
  doi: 10.1016/j.cose.2021.102367
– volume: 4
  start-page: 383
  year: 2023
  ident: ref23
  article-title: Improving calibration and out-of-distribution detection in deep models for medical image segmentation
  publication-title: IEEE Trans Artific Intellig
  doi: 10.1109/tai.2022.3159510
– year: 2023
  ident: ref36
– year: 2019
  ident: ref4
– volume: 1
  start-page: 17
  year: 2020
  ident: ref49
  article-title: Computer systems resilience in the presence of cyber threats: Taxonomy and ontology
  publication-title: Radioelectron Comput Syst
  doi: 10.32620/reks.2020.1.02
– volume: 45
  start-page: 1
  year: 2022
  ident: ref26
  article-title: A review of generalized zero-shot learning methods
  publication-title: IEEE Trans Pattern Anal Mach Intell
  doi: 10.1109/tpami.2022.3191696
– year: 2022
  ident: ref9
– volume: 157
  start-page: 106791
  year: 2023
  ident: ref51
  article-title: Med ViT: a robust vision transformer for generalized medical image classification
  publication-title: Comput Biol Med
  doi: 10.1016/j.compbiomed.2023.106791
– volume: 297
  start-page: 6
  year: 2020
  ident: ref30
  article-title: Continuous learning AI in radiology: implementation principles and early applications
  publication-title: Radiology
  doi: 10.1148/radiol.2020200038
– volume: 1
  start-page: 294
  year: 2011
  ident: ref47
  article-title: A formal framework for dependability and resilience from a software engineering perspective
  publication-title: Open Comput Sci
  doi: 10.2478/s13537-011-0025-x
– volume: 10
  start-page: 63606
  year: 2022
  ident: ref1
  article-title: MLOps: a taxonomy and a methodology
  publication-title: IEEE Access
  doi: 10.1109/access.2022.3181730
SSID ssj0001034021
Score 2.31567
Snippet The healthcare sector demands a higher degree of responsibility, trustworthiness, and accountability when implementing Artificial Intelligence (AI) systems....
BackgroundThe healthcare sector demands a higher degree of responsibility, trustworthiness, and accountability when implementing Artificial Intelligence (AI)...
SourceID doaj
pubmedcentral
proquest
pubmed
crossref
SourceType Open Website
Open Access Repository
Aggregation Database
Index Database
Enrichment Source
StartPage 1342937
SubjectTerms Artificial Intelligence
Awareness
Data Accuracy
image recognition
Machine Learning
medical diagnosis
MLOps
Public Health
resilience
Resilience, Psychological
robustness
Title Resilience-aware MLOps for AI-based medical diagnostic system
URI https://www.ncbi.nlm.nih.gov/pubmed/38601490
https://www.proquest.com/docview/3037397743
https://pubmed.ncbi.nlm.nih.gov/PMC11004236
https://doaj.org/article/362621c330c4450ba660ff0dfe9e2d30
Volume 12
WOSCitedRecordID wos001198920600001&url=https%3A%2F%2Fcvtisr.summon.serialssolutions.com%2F%23%21%2Fsearch%3Fho%3Df%26include.ft.matches%3Dt%26l%3Dnull%26q%3D
hasFullText 1
inHoldings 1
isFullTextHit
isPrint
journalDatabaseRights – providerCode: PRVAON
  databaseName: DOAJ Directory of Open Access Journals
  customDbUrl:
  eissn: 2296-2565
  dateEnd: 99991231
  omitProxy: false
  ssIdentifier: ssj0001034021
  issn: 2296-2565
  databaseCode: DOA
  dateStart: 20130101
  isFulltext: true
  titleUrlDefault: https://www.doaj.org/
  providerName: Directory of Open Access Journals
– providerCode: PRVHPJ
  databaseName: ROAD: Directory of Open Access Scholarly Resources
  customDbUrl:
  eissn: 2296-2565
  dateEnd: 99991231
  omitProxy: false
  ssIdentifier: ssj0001034021
  issn: 2296-2565
  databaseCode: M~E
  dateStart: 20130101
  isFulltext: true
  titleUrlDefault: https://road.issn.org
  providerName: ISSN International Centre
link http://cvtisr.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwrV1Lb9QwEB5BxQEJId4sj8pI3JCpY3sd-8ChoFYgtQUhQHuzHHsiVipptbuFG7-dsZ2udhGCC4fkkDjJeGacmbFnPgM8V60N5OhKntAprpNV3OooudShpwGILZaqtC9H7cmJnc3ch42tvnJOWIUHrozby3ApsokUdketp6ILxoi-F6lHhzKpEq2T17MRTJXZFaEoMGpqlQxFYW4vl1vlxQepXzaKfsJ54_MNS1QA-__kZf6eLLlhfQ5vwc3RbWT7ldzbcAWHO3CjzrmxWkp0F159xOX8tIxVHn6EBbLjo_fnS0Z-Kdt_x7PBSuxbXZlhqebY0ftYRXO-B58PDz69ecvH7RF4pJh2xQM5WzJ2MvcpOFShtQoNBtEZYXvqcxuTSQqFCLF3totT21unkY6gNUp1H3aGswEfArPShY56KE3oddJT50ISIlHbJqYozASaS1b5OGKH5y0sTj3FEJm9vrDXZ1L8yN4JvFg_c16RM_7a-nWWwLplRr0uF0gX_KgL_l-6MIFnl_LzNEry0kcY8Oxi6clQt8XVVRN4UOW5_pSyJseJ9LTdkvQWLdt3hvnXgsRd8PakMo_-B_WP4XrmSE5wk-0T2FktLvApXIvfV_PlYheutjO7W7Sczsc_D34B5Z8AZg
linkProvider Directory of Open Access Journals
openUrl ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=Resilience-aware+MLOps+for+AI-based+medical+diagnostic+system&rft.jtitle=Frontiers+in+public+health&rft.au=Moskalenko%2C+Viacheslav&rft.au=Kharchenko%2C+Vyacheslav&rft.date=2024-03-27&rft.issn=2296-2565&rft.eissn=2296-2565&rft.volume=12&rft.spage=1342937&rft_id=info:doi/10.3389%2Ffpubh.2024.1342937&rft.externalDBID=NO_FULL_TEXT
thumbnail_l http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=2296-2565&client=summon
thumbnail_m http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=2296-2565&client=summon
thumbnail_s http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=2296-2565&client=summon