The impact of transfer learning on 3D deep learning convolutional neural network segmentation of the hippocampus in mild cognitive impairment and Alzheimer disease subjects

Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent br...

Full description

Saved in:
Bibliographic Details
Published inHuman brain mapping Vol. 43; no. 11; pp. 3427 - 3438
Main Authors Balboni, Erica, Nocetti, Luca, Carbone, Chiara, Dinsdale, Nicola, Genovese, Maurilio, Guidi, Gabriele, Malagoli, Marcella, Chiari, Annalisa, Namburete, Ana I. L., Jenkinson, Mark, Zamboni, Giovanna
Format Journal Article
LanguageEnglish
Published Hoboken, USA John Wiley & Sons, Inc 01.08.2022
Subjects
Abnormalities
Alzheimer disease
Alzheimer's disease
Artificial neural networks
Biomarkers
Cognitive ability
Datasets
Deep learning
Domains
Hippocampus
Image processing
Image segmentation
Impairment
Magnetic resonance imaging
Medical imaging
mild cognitive impairment
Neural networks
Neurodegenerative diseases
Training
Transfer learning
deep learning
transfer learning
magnetic resonance imaging
hippocampus
Alzheimer disease
neural networks
mild cognitive impairment
Online AccessGet full text
ISSN1065-9471
1097-0193
1097-0193
DOI10.1002/hbm.25858

Cover

Abstract Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent brain changes associated with Alzheimer disease (AD). However, CNNs typically achieve the highest accuracy on datasets acquired from the same domain as the training dataset. Transfer learning allows domain adaptation through further training on a limited dataset. In this study, we applied transfer learning on a network called spatial warping network segmentation (SWANS), developed and trained in a previous study. We used MR images of patients with clinical diagnoses of mild cognitive impairment (MCI) and AD, segmented by two different raters. By using transfer learning techniques, we developed four new models, using different training methods. Testing was performed using 26% of the original dataset, which was excluded from training as a hold‐out test set. In addition, 10% of the overall training dataset was used as a hold‐out validation set. Results showed that all the new models achieved better hippocampal segmentation quality than the baseline SWANS model (ps < .001), with high similarity to the manual segmentations (mean dice [best model] = 0.878 ± 0.003). The best model was chosen based on visual assessment and volume percentage error (VPE). The increased precision in estimating hippocampal volumes allows the detection of small hippocampal abnormalities already present in the MCI phase (SD = [3.9 ± 0.6]%), which may be crucial for early diagnosis. In this study, we used transfer learning technique for the segmentation of the hippocampus, considering three datasets of patients with a clinical diagnosis of mild cognitive impairment and Alzheimer disease, scanned with different protocols. We started from a previously developed deep learning algorithm, trained with a different dataset, and we quantified the benefits given by the transfer learning, both in a numerical and visual way, using manual segmentations from two raters as a gold standard.
AbstractList Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent brain changes associated with Alzheimer disease (AD). However, CNNs typically achieve the highest accuracy on datasets acquired from the same domain as the training dataset. Transfer learning allows domain adaptation through further training on a limited dataset. In this study, we applied transfer learning on a network called spatial warping network segmentation (SWANS), developed and trained in a previous study. We used MR images of patients with clinical diagnoses of mild cognitive impairment (MCI) and AD, segmented by two different raters. By using transfer learning techniques, we developed four new models, using different training methods. Testing was performed using 26% of the original dataset, which was excluded from training as a hold‐out test set. In addition, 10% of the overall training dataset was used as a hold‐out validation set. Results showed that all the new models achieved better hippocampal segmentation quality than the baseline SWANS model (ps < .001), with high similarity to the manual segmentations (mean dice [best model] = 0.878 ± 0.003). The best model was chosen based on visual assessment and volume percentage error (VPE). The increased precision in estimating hippocampal volumes allows the detection of small hippocampal abnormalities already present in the MCI phase (SD = [3.9 ± 0.6]%), which may be crucial for early diagnosis. In this study, we used transfer learning technique for the segmentation of the hippocampus, considering three datasets of patients with a clinical diagnosis of mild cognitive impairment and Alzheimer disease, scanned with different protocols. We started from a previously developed deep learning algorithm, trained with a different dataset, and we quantified the benefits given by the transfer learning, both in a numerical and visual way, using manual segmentations from two raters as a gold standard.
Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent brain changes associated with Alzheimer disease (AD). However, CNNs typically achieve the highest accuracy on datasets acquired from the same domain as the training dataset. Transfer learning allows domain adaptation through further training on a limited dataset. In this study, we applied transfer learning on a network called spatial warping network segmentation (SWANS), developed and trained in a previous study. We used MR images of patients with clinical diagnoses of mild cognitive impairment (MCI) and AD, segmented by two different raters. By using transfer learning techniques, we developed four new models, using different training methods. Testing was performed using 26% of the original dataset, which was excluded from training as a hold-out test set. In addition, 10% of the overall training dataset was used as a hold-out validation set. Results showed that all the new models achieved better hippocampal segmentation quality than the baseline SWANS model (p  < .001), with high similarity to the manual segmentations (mean dice [best model] = 0.878 ± 0.003). The best model was chosen based on visual assessment and volume percentage error (VPE). The increased precision in estimating hippocampal volumes allows the detection of small hippocampal abnormalities already present in the MCI phase (SD = [3.9 ± 0.6]%), which may be crucial for early diagnosis.
Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent brain changes associated with Alzheimer disease (AD). However, CNNs typically achieve the highest accuracy on datasets acquired from the same domain as the training dataset. Transfer learning allows domain adaptation through further training on a limited dataset. In this study, we applied transfer learning on a network called spatial warping network segmentation (SWANS), developed and trained in a previous study. We used MR images of patients with clinical diagnoses of mild cognitive impairment (MCI) and AD, segmented by two different raters. By using transfer learning techniques, we developed four new models, using different training methods. Testing was performed using 26% of the original dataset, which was excluded from training as a hold‐out test set. In addition, 10% of the overall training dataset was used as a hold‐out validation set. Results showed that all the new models achieved better hippocampal segmentation quality than the baseline SWANS model (ps < .001), with high similarity to the manual segmentations (mean dice [best model] = 0.878 ± 0.003). The best model was chosen based on visual assessment and volume percentage error (VPE). The increased precision in estimating hippocampal volumes allows the detection of small hippocampal abnormalities already present in the MCI phase (SD = [3.9 ± 0.6]%), which may be crucial for early diagnosis.
Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent brain changes associated with Alzheimer disease (AD). However, CNNs typically achieve the highest accuracy on datasets acquired from the same domain as the training dataset. Transfer learning allows domain adaptation through further training on a limited dataset. In this study, we applied transfer learning on a network called spatial warping network segmentation (SWANS), developed and trained in a previous study. We used MR images of patients with clinical diagnoses of mild cognitive impairment (MCI) and AD, segmented by two different raters. By using transfer learning techniques, we developed four new models, using different training methods. Testing was performed using 26% of the original dataset, which was excluded from training as a hold‐out test set. In addition, 10% of the overall training dataset was used as a hold‐out validation set. Results showed that all the new models achieved better hippocampal segmentation quality than the baseline SWANS model ( p s  < .001), with high similarity to the manual segmentations (mean dice [best model] = 0.878 ± 0.003). The best model was chosen based on visual assessment and volume percentage error (VPE). The increased precision in estimating hippocampal volumes allows the detection of small hippocampal abnormalities already present in the MCI phase ( SD  = [3.9 ± 0.6]%), which may be crucial for early diagnosis.
Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent brain changes associated with Alzheimer disease (AD). However, CNNs typically achieve the highest accuracy on datasets acquired from the same domain as the training dataset. Transfer learning allows domain adaptation through further training on a limited dataset. In this study, we applied transfer learning on a network called spatial warping network segmentation (SWANS), developed and trained in a previous study. We used MR images of patients with clinical diagnoses of mild cognitive impairment (MCI) and AD, segmented by two different raters. By using transfer learning techniques, we developed four new models, using different training methods. Testing was performed using 26% of the original dataset, which was excluded from training as a hold‐out test set. In addition, 10% of the overall training dataset was used as a hold‐out validation set. Results showed that all the new models achieved better hippocampal segmentation quality than the baseline SWANS model ( p s  < .001), with high similarity to the manual segmentations (mean dice [best model] = 0.878 ± 0.003). The best model was chosen based on visual assessment and volume percentage error (VPE). The increased precision in estimating hippocampal volumes allows the detection of small hippocampal abnormalities already present in the MCI phase ( SD  = [3.9 ± 0.6]%), which may be crucial for early diagnosis. In this study, we used transfer learning technique for the segmentation of the hippocampus, considering three datasets of patients with a clinical diagnosis of mild cognitive impairment and Alzheimer disease, scanned with different protocols. We started from a previously developed deep learning algorithm, trained with a different dataset, and we quantified the benefits given by the transfer learning, both in a numerical and visual way, using manual segmentations from two raters as a gold standard.
Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent brain changes associated with Alzheimer disease (AD). However, CNNs typically achieve the highest accuracy on datasets acquired from the same domain as the training dataset. Transfer learning allows domain adaptation through further training on a limited dataset. In this study, we applied transfer learning on a network called spatial warping network segmentation (SWANS), developed and trained in a previous study. We used MR images of patients with clinical diagnoses of mild cognitive impairment (MCI) and AD, segmented by two different raters. By using transfer learning techniques, we developed four new models, using different training methods. Testing was performed using 26% of the original dataset, which was excluded from training as a hold-out test set. In addition, 10% of the overall training dataset was used as a hold-out validation set. Results showed that all the new models achieved better hippocampal segmentation quality than the baseline SWANS model (ps  < .001), with high similarity to the manual segmentations (mean dice [best model] = 0.878 ± 0.003). The best model was chosen based on visual assessment and volume percentage error (VPE). The increased precision in estimating hippocampal volumes allows the detection of small hippocampal abnormalities already present in the MCI phase (SD = [3.9 ± 0.6]%), which may be crucial for early diagnosis.Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results, suggesting that these methods can identify small structural abnormalities of the hippocampus, which are among the earliest and most frequent brain changes associated with Alzheimer disease (AD). However, CNNs typically achieve the highest accuracy on datasets acquired from the same domain as the training dataset. Transfer learning allows domain adaptation through further training on a limited dataset. In this study, we applied transfer learning on a network called spatial warping network segmentation (SWANS), developed and trained in a previous study. We used MR images of patients with clinical diagnoses of mild cognitive impairment (MCI) and AD, segmented by two different raters. By using transfer learning techniques, we developed four new models, using different training methods. Testing was performed using 26% of the original dataset, which was excluded from training as a hold-out test set. In addition, 10% of the overall training dataset was used as a hold-out validation set. Results showed that all the new models achieved better hippocampal segmentation quality than the baseline SWANS model (ps  < .001), with high similarity to the manual segmentations (mean dice [best model] = 0.878 ± 0.003). The best model was chosen based on visual assessment and volume percentage error (VPE). The increased precision in estimating hippocampal volumes allows the detection of small hippocampal abnormalities already present in the MCI phase (SD = [3.9 ± 0.6]%), which may be crucial for early diagnosis.
Author Nocetti, Luca
Zamboni, Giovanna
Guidi, Gabriele
Namburete, Ana I. L.
Malagoli, Marcella
Jenkinson, Mark
Dinsdale, Nicola
Balboni, Erica
Carbone, Chiara
Genovese, Maurilio
Chiari, Annalisa
AuthorAffiliation 7 Australian Institute for Machine Learning, School of Computer Science University of Adelaide Adelaide South Australia Australia
6 Neuroradiology Unit Azienda Ospedaliera di Modena Modena Italy
2 Department of Biomedical, Metabolic and Neural Sciences University of Modena and Reggio Emilia Modena Italy
3 Center for Neurosciences and Neurotechnology Università di Modena e Reggio Emilia Modena Italy
5 Oxford Machine Learning in NeuroImaging Lab Department of Computer Science Oxford UK
1 Health Physics Unit Azienda Ospedaliera di Modena Modena Italy
4 Wellcome Centre for Integrative Neuroimaging, FMRIB, Nuffield Department of Clinical Neurosciences, University of Oxford Oxford UK
8 South Australian Health and Medical Research Institute (SAHMRI) Adelaide South Australia Australia
AuthorAffiliation_xml – name: 5 Oxford Machine Learning in NeuroImaging Lab Department of Computer Science Oxford UK
– name: 1 Health Physics Unit Azienda Ospedaliera di Modena Modena Italy
– name: 7 Australian Institute for Machine Learning, School of Computer Science University of Adelaide Adelaide South Australia Australia
– name: 3 Center for Neurosciences and Neurotechnology Università di Modena e Reggio Emilia Modena Italy
– name: 8 South Australian Health and Medical Research Institute (SAHMRI) Adelaide South Australia Australia
– name: 4 Wellcome Centre for Integrative Neuroimaging, FMRIB, Nuffield Department of Clinical Neurosciences, University of Oxford Oxford UK
– name: 2 Department of Biomedical, Metabolic and Neural Sciences University of Modena and Reggio Emilia Modena Italy
– name: 6 Neuroradiology Unit Azienda Ospedaliera di Modena Modena Italy
Author_xml – sequence: 1
  givenname: Erica
  orcidid: 0000-0001-5484-2113
  surname: Balboni
  fullname: Balboni, Erica
  email: erica.balboni@unimore.it
  organization: University of Modena and Reggio Emilia
– sequence: 2
  givenname: Luca
  surname: Nocetti
  fullname: Nocetti, Luca
  organization: Azienda Ospedaliera di Modena
– sequence: 3
  givenname: Chiara
  surname: Carbone
  fullname: Carbone, Chiara
  organization: Università di Modena e Reggio Emilia
– sequence: 4
  givenname: Nicola
  surname: Dinsdale
  fullname: Dinsdale, Nicola
  organization: Department of Computer Science
– sequence: 5
  givenname: Maurilio
  surname: Genovese
  fullname: Genovese, Maurilio
  organization: Azienda Ospedaliera di Modena
– sequence: 6
  givenname: Gabriele
  surname: Guidi
  fullname: Guidi, Gabriele
  organization: Azienda Ospedaliera di Modena
– sequence: 7
  givenname: Marcella
  surname: Malagoli
  fullname: Malagoli, Marcella
  organization: Azienda Ospedaliera di Modena
– sequence: 8
  givenname: Annalisa
  surname: Chiari
  fullname: Chiari, Annalisa
  organization: Azienda Ospedaliera di Modena
– sequence: 9
  givenname: Ana I. L.
  surname: Namburete
  fullname: Namburete, Ana I. L.
  organization: Department of Computer Science
– sequence: 10
  givenname: Mark
  surname: Jenkinson
  fullname: Jenkinson, Mark
  organization: South Australian Health and Medical Research Institute (SAHMRI)
– sequence: 11
  givenname: Giovanna
  surname: Zamboni
  fullname: Zamboni, Giovanna
  organization: Wellcome Centre for Integrative Neuroimaging, FMRIB, Nuffield Department of Clinical Neurosciences, University of Oxford
BackLink https://www.ncbi.nlm.nih.gov/pubmed/35373881$$D View this record in MEDLINE/PubMed
BookMark eNp1kstu1TAQhi1URC-w4AWQJTawSOtLLs4GqS2XIhWxKWvLScbn-ODYwU5OVZ6Jh8Q5OeVSwWoszzf__PbMMTpw3gFCzyk5pYSws3XTn7JCFOIROqKkrjJCa34wn8siq_OKHqLjGDeEUFoQ-gQd8oJXXAh6hH7crAGbflDtiL3GY1AuagjYggrOuBX2DvO3uAMYft-13m29nUbjnbLYwRR2Ybz14SuOsOrBjWrO7iRTg7UZBt-qfpgiNg73xnZJZOXMaLZLexPmIqxch8_t9zWYPpnoTAQVAcep2UA7xqfosVY2wrN9PEFf3r-7ubzKrj9_-Hh5fp21ec5FlmtRctI0TFecACtzWhJBtK50owoFkJddp7kWhDOoc11WmolakBq6piuqivET9GbRHaamh65NztIL5RBMr8Kd9MrIvzPOrOXKb2XNcsFJmQRe7QWC_zZBHGVvYgvWKgd-ijJ5Kus8jW5GXz5AN34K6V9nSrCKJU2SqBd_Ovpl5X6QCThbgDb4GANo2ZplBsmgsZISOa-KTKsid6uSKl4_qLgX_Re7V781Fu7-D8qri09LxU-9EtIB
CitedBy_id crossref_primary_10_1002_hsr2_70025
crossref_primary_10_3389_fnins_2023_1238646
crossref_primary_10_1002_rcs_2634
crossref_primary_10_32604_cmc_2023_034796
crossref_primary_10_3389_fnimg_2022_981642
crossref_primary_10_4108_eetpht_10_5550
crossref_primary_10_1007_s10462_023_10644_8
crossref_primary_10_1186_s42492_024_00169_4
crossref_primary_10_1016_j_prp_2024_155671
crossref_primary_10_1109_ACCESS_2024_3454709
crossref_primary_10_1016_j_nicl_2022_103273
crossref_primary_10_1093_bjr_tqae002
crossref_primary_10_3390_bioengineering10040397
Cites_doi 10.1002/hbm.10062
10.1016/s1361-8415(01)00036-6
10.1098/rspa.1937.0109
10.1016/j.jalz.2013.03.001
10.1002/hbm.24803
10.1016/j.jcm.2016.02.012
10.1016/s1076-6332(03)00671-8
10.1109/TKDE.2009.191
10.1016/j.neurobiolaging.2016.05.024
10.1148/radiology.216.3.r00au37672
10.1016/j.media.2019.03.009
10.1016/j.biopsych.2013.04.015
10.1212/01.wnl.0000252358.03285.9d
10.1007/s12065-020-00540-3
10.1007/11866763_8
10.1016/j.neurobiolaging.2011.05.018
10.3389/fnbeh.2018.00100
10.1002/hipo.22417
10.1002/hbm.25210
10.1016/j.neuroimage.2020.117689
10.1016/j.jalz.2011.03.008
10.1016/j.jalz.2011.03.005
10.1523/JNEUROSCI.23-03-00994.2003
10.1002/alz.12177
10.1056/NEJMoa050151
10.1002/hbm.23772
10.1196/annals.1379.017
10.1016/j.jalz.2014.05.1761
10.1371/journal.pone.0186595
10.1093/brain/awq277
10.1111/j.1365‐2796.2004.01380.x
10.1177/1073858410395147
10.1016/j.neuroimage.2011.09.015
10.1159/000089515
10.1016/j.neuroimage.2015.01.004
10.1007/978-3-030-32248-9_32
10.1016/j.neuroimage.2009.06.060
10.1016/s1053-8119(02)91132-8
ContentType Journal Article
Copyright 2022 The Authors. published by Wiley Periodicals LLC.
2022 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.
2022. This article is published under http://creativecommons.org/licenses/by-nc-nd/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
Copyright_xml – notice: 2022 The Authors. published by Wiley Periodicals LLC.
– notice: 2022 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.
– notice: 2022. This article is published under http://creativecommons.org/licenses/by-nc-nd/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
DBID 24P
AAYXX
CITATION
NPM
7QR
7TK
7U7
8FD
C1K
FR3
K9.
P64
7X8
5PM
DOI 10.1002/hbm.25858
DatabaseName Wiley Online Library Open Access
CrossRef
PubMed
Chemoreception Abstracts
Neurosciences Abstracts
Toxicology Abstracts
Technology Research Database
Environmental Sciences and Pollution Management
Engineering Research Database
ProQuest Health & Medical Complete (Alumni)
Biotechnology and BioEngineering Abstracts
MEDLINE - Academic
PubMed Central (Full Participant titles)
DatabaseTitle CrossRef
PubMed
Technology Research Database
Toxicology Abstracts
ProQuest Health & Medical Complete (Alumni)
Chemoreception Abstracts
Engineering Research Database
Neurosciences Abstracts
Biotechnology and BioEngineering Abstracts
Environmental Sciences and Pollution Management
MEDLINE - Academic
DatabaseTitleList
PubMed
Technology Research Database
CrossRef

MEDLINE - Academic
Database_xml – sequence: 1
  dbid: 24P
  name: Wiley Online Library Open Access
  url: https://authorservices.wiley.com/open-science/open-access/browse-journals.html
  sourceTypes: Publisher
– sequence: 2
  dbid: NPM
  name: PubMed
  url: https://proxy.k.utb.cz/login?url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed
  sourceTypes: Index Database
DeliveryMethod fulltext_linktorsrc
Discipline Medicine
Anatomy & Physiology
DocumentTitleAlternate Balboni et al
EISSN 1097-0193
EndPage 3438
ExternalDocumentID PMC9248306
35373881
10_1002_hbm_25858
HBM25858
Genre article
Journal Article
GrantInformation_xml – fundername: Royal Academy of Engineering
  funderid: Development Research Fellowships
– fundername: Ministero dell'Istruzione, dell'Università e della Ricerca
  funderid: Dipartimenti di eccellenza 2018‐2022
– fundername: Ministero dell'Istruzione, dell'Università e della Ricerca
  grantid: Dipartimenti di eccellenza 2018-2022
– fundername: Royal Academy of Engineering
  grantid: Development Research Fellowships
– fundername: Ministero dell'Istruzione, dell'Università e della Ricerca
  grantid: Dipartimenti di eccellenza 2018‐2022
– fundername: ;
  grantid: Development Research Fellowships
GroupedDBID ---
.3N
.GA
05W
0R~
10A
1L6
1OB
1OC
1ZS
24P
33P
3SF
3WU
4.4
4ZD
50Y
50Z
51W
51X
52M
52N
52O
52P
52S
52T
52U
52W
52X
53G
5GY
5VS
66C
702
7PT
7X7
8-0
8-1
8-3
8-4
8-5
8FI
8FJ
8UM
930
A03
AAESR
AAEVG
AAHHS
AAONW
AAYCA
AAZKR
ABCQN
ABCUV
ABIJN
ABIVO
ABPVW
ABUWG
ACCFJ
ACCMX
ACGFS
ACIWK
ACPOU
ACPRK
ACXQS
ADBBV
ADEOM
ADIZJ
ADMGS
ADPDF
ADXAS
ADZOD
AEEZP
AEIMD
AENEX
AEQDE
AEUQT
AFBPY
AFGKR
AFKRA
AFPWT
AFRAH
AFZJQ
AHMBA
AIURR
AIWBW
AJBDE
AJXKR
ALAGY
ALIPV
ALMA_UNASSIGNED_HOLDINGS
ALUQN
AMBMR
ATUGU
AUFTA
AZBYB
AZVAB
BAFTC
BDRZF
BENPR
BHBCM
BMNLL
BMXJE
BNHUX
BROTX
BRXPI
BY8
C45
CCPQU
CS3
D-E
D-F
DCZOG
DPXWK
DR1
DR2
DU5
EBD
EBS
EMOBN
F00
F01
F04
F5P
FYUFA
G-S
G.N
GNP
GODZA
GROUPED_DOAJ
H.T
H.X
HBH
HHY
HHZ
HMCUK
HZ~
IAO
IHR
ITC
IX1
J0M
JPC
KQQ
L7B
LAW
LC2
LC3
LH4
LITHE
LOXES
LP6
LP7
LUTES
LYRES
MK4
MRFUL
MRSTM
MSFUL
MSSTM
MXFUL
MXSTM
N04
N05
N9A
NF~
NNB
O66
O9-
OIG
OK1
OVD
OVEED
P2P
P2W
P2X
P4D
PALCI
PIMPY
PQQKQ
Q.N
Q11
QB0
QRW
R.K
ROL
RPM
RWD
RWI
RX1
RYL
SUPJJ
SV3
TEORI
UB1
UKHRP
V2E
W8V
W99
WBKPD
WIB
WIH
WIK
WIN
WJL
WNSPC
WOHZO
WQJ
WRC
WUP
WYISQ
XG1
XSW
XV2
ZZTAW
~IA
~WT
.Y3
31~
AAFWJ
AANHP
AAYXX
ABEML
ABJNI
ACBWZ
ACRPL
ACSCC
ACYXJ
ADNMO
AFPKN
AGQPQ
ASPBG
AVWKF
AZFZN
BFHJK
CITATION
EJD
FEDTE
GAKWD
HF~
HVGLF
LW6
M6M
PHGZM
PHGZT
RIWAO
RJQFR
SAMSI
WXSBR
NPM
7QR
7TK
7U7
8FD
AAMMB
AEFGJ
AGXDD
AIDQK
AIDYY
C1K
FR3
K9.
P64
7X8
5PM
ID FETCH-LOGICAL-c4438-4f8630bb2f730e26416080ff7fba5aee46ddf3f8032e94f67f289809edbd57723
IEDL.DBID DR2
ISSN 1065-9471
1097-0193
IngestDate Thu Aug 21 14:32:04 EDT 2025
Thu Jul 10 23:32:56 EDT 2025
Sat Jul 26 02:04:04 EDT 2025
Wed Feb 19 02:26:39 EST 2025
Tue Jul 01 01:11:07 EDT 2025
Thu Apr 24 23:12:30 EDT 2025
Wed Jan 22 16:24:23 EST 2025
IsDoiOpenAccess true
IsOpenAccess true
IsPeerReviewed true
IsScholarly true
Issue 11
Keywords deep learning
transfer learning
magnetic resonance imaging
hippocampus
Alzheimer disease
neural networks
mild cognitive impairment
Language English
License Attribution-NonCommercial-NoDerivs
2022 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.
This is an open access article under the terms of the http://creativecommons.org/licenses/by-nc-nd/4.0/ License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non‐commercial and no modifications or adaptations are made.
LinkModel DirectLink
MergedId FETCHMERGED-LOGICAL-c4438-4f8630bb2f730e26416080ff7fba5aee46ddf3f8032e94f67f289809edbd57723
Notes Funding information
Mark Jenkinson and Giovanna Zamboni are joint senior authors.
Ministero dell'Istruzione, dell'Università e della Ricerca, Grant/Award Number: Dipartimenti di eccellenza 2018‐2022; Royal Academy of Engineering, Grant/Award Number: Development Research Fellowships
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 14
content type line 23
Funding information Ministero dell'Istruzione, dell'Università e della Ricerca, Grant/Award Number: Dipartimenti di eccellenza 2018‐2022; Royal Academy of Engineering, Grant/Award Number: Development Research Fellowships
ORCID 0000-0001-5484-2113
OpenAccessLink https://proxy.k.utb.cz/login?url=https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fhbm.25858
PMID 35373881
PQID 2682729240
PQPubID 996345
PageCount 12
ParticipantIDs pubmedcentral_primary_oai_pubmedcentral_nih_gov_9248306
proquest_miscellaneous_2646940026
proquest_journals_2682729240
pubmed_primary_35373881
crossref_citationtrail_10_1002_hbm_25858
crossref_primary_10_1002_hbm_25858
wiley_primary_10_1002_hbm_25858_HBM25858
ProviderPackageCode CITATION
AAYXX
PublicationCentury 2000
PublicationDate August 1, 2022
PublicationDateYYYYMMDD 2022-08-01
PublicationDate_xml – month: 08
  year: 2022
  text: August 1, 2022
  day: 01
PublicationDecade 2020
PublicationPlace Hoboken, USA
PublicationPlace_xml – name: Hoboken, USA
– name: United States
– name: San Antonio
PublicationTitle Human brain mapping
PublicationTitleAlternate Hum Brain Mapp
PublicationYear 2022
Publisher John Wiley & Sons, Inc
Publisher_xml – name: John Wiley & Sons, Inc
References 2015; 2
2002; 17
2005; 352
2020; 41
2019; 54
2000; 216
2015; 11
2006; 9
2021; 228
2012; 18
2016; 15
2012; 33
2011; 7
2009; 48
2010; 22
2004; 11
2015; 25
2021; 15
2017; 52
2007; 1097
2004; 256
2001; 5
2006; 21
2021
2020
2017; 38
2015; 111
2021; 17
2017; 12
2013; 74
2019
2010; 133
2015
2020; 43
2018; 12
1937; 160
2007; 68
2012; 62
2003; 23
e_1_2_12_4_1
Ronneberger O. (e_1_2_12_32_1) 2015
e_1_2_12_3_1
e_1_2_12_6_1
Jaderberg M. (e_1_2_12_16_1) 2015; 2
e_1_2_12_5_1
e_1_2_12_19_1
e_1_2_12_18_1
e_1_2_12_2_1
e_1_2_12_17_1
e_1_2_12_38_1
e_1_2_12_39_1
e_1_2_12_42_1
e_1_2_12_20_1
e_1_2_12_41_1
e_1_2_12_21_1
e_1_2_12_44_1
e_1_2_12_22_1
e_1_2_12_43_1
e_1_2_12_23_1
e_1_2_12_46_1
e_1_2_12_24_1
e_1_2_12_45_1
e_1_2_12_25_1
e_1_2_12_26_1
e_1_2_12_40_1
e_1_2_12_27_1
e_1_2_12_28_1
e_1_2_12_29_1
e_1_2_12_30_1
e_1_2_12_31_1
e_1_2_12_33_1
e_1_2_12_34_1
e_1_2_12_35_1
e_1_2_12_36_1
e_1_2_12_37_1
e_1_2_12_15_1
e_1_2_12_14_1
e_1_2_12_13_1
e_1_2_12_12_1
e_1_2_12_8_1
e_1_2_12_11_1
e_1_2_12_7_1
e_1_2_12_10_1
e_1_2_12_9_1
References_xml – volume: 22
  start-page: 1345
  issue: 10
  year: 2010
  end-page: 1359
  article-title: A survey on transfer learning
  publication-title: IEEE Transactions on Knowledge and Data Engineering
– volume: 38
  start-page: 5890
  issue: 12
  year: 2017
  end-page: 5904
  article-title: Gray matter asymmetries in aging and neurodegeneration: A review and meta‐analysis
  publication-title: Human Brain Mapping
– volume: 160
  start-page: 268
  issue: 901
  year: 1937
  end-page: 282
  article-title: Properties of sufficiency and statistical tests
  publication-title: Proceedings of the Royal Society of London. Series A: Mathematical and Physical Sciences
– volume: 2
  start-page: 2017
  year: 2015
  end-page: 2025
  article-title: Spatial transformer networks
  publication-title: Advances in Neural Information Processing Systems 28 (NIPS 2015)
– volume: 11
  start-page: 184
  issue: 2
  year: 2015
  end-page: 194
  article-title: Operationalizing protocol differences for EADC‐ADNI manual hippocampal segmentation
  publication-title: Alzheimers Dement
– volume: 17
  start-page: 81
  issue: 1
  year: 2021
  end-page: 88
  article-title: Epidemiology of early onset dementia and its clinical presentations in the province of Modena, Italy
  publication-title: Alzheimers Dement
– year: 2021
– volume: 11
  start-page: 178
  issue: 2
  year: 2004
  end-page: 189
  article-title: Statistical validation of image segmentation quality based on a spatial overlap index
  publication-title: Academic Radiology
– volume: 74
  start-page: 375
  issue: 5
  year: 2013
  end-page: 383
  article-title: Resting functional connectivity reveals residual functional activity in Alzheimer's disease
  publication-title: Biological Psychiatry
– volume: 228
  year: 2021
  article-title: Deep learning‐based unlearning of dataset bias for MRI harmonisation and confound removal
  publication-title: NeuroImage
– volume: 54
  start-page: 280
  year: 2019
  end-page: 296
  article-title: Not‐so‐supervised: A survey of semi‐supervised, multi‐instance, and transfer learning in medical image analysis
  publication-title: Medical Image Analysis
– volume: 23
  start-page: 994
  issue: 3
  year: 2003
  end-page: 1005
  article-title: Dynamics of gray matter loss in Alzheimer's disease
  publication-title: The Journal of Neuroscience
– volume: 1097
  start-page: 183
  year: 2007
  end-page: 214
  article-title: Tracking Alzheimer's disease
  publication-title: Annals of the New York Academy of Sciences
– volume: 11
  start-page: 107
  issue: 2
  year: 2015
  end-page: 110
  article-title: HarP: The EADC‐ADNI harmonized protocol for manual hippocampal segmentation. A standard of reference from a global working group
  publication-title: Alzheimers Dement
– volume: 33
  start-page: 825.e25
  issue: 4
  year: 2012
  end-page: 825.e36
  article-title: Structural MRI changes detectable up to ten years before clinical Alzheimer's disease
  publication-title: Neurobiology of Aging
– volume: 48
  start-page: 63
  issue: 1
  year: 2009
  end-page: 72
  article-title: Accurate and robust brain image alignment using boundary‐based registration
  publication-title: NeuroImage
– volume: 216
  start-page: 672
  issue: 3
  year: 2000
  end-page: 682
  article-title: Normal brain development and aging: Quantitative analysis at in vivo MR imaging in healthy volunteers
  publication-title: Radiology
– volume: 17
  start-page: 143
  issue: 3
  year: 2002
  end-page: 155
  article-title: Fast robust automated brain extraction
  publication-title: Human Brain Mapping
– volume: 41
  start-page: 309
  issue: 2
  year: 2020
  end-page: 327
  article-title: Accurate and robust segmentation of neuroanatomy in T1‐weighted MRI by combining spatial priors with deep convolutional neural networks
  publication-title: Human Brain Mapping
– volume: 352
  start-page: 2379
  issue: 23
  year: 2005
  end-page: 2388
  article-title: Vitamin E and donepezil for the treatment of mild cognitive impairment
  publication-title: The New England Journal of Medicine
– volume: 7
  start-page: 270
  issue: 3
  year: 2011
  end-page: 279
  article-title: The diagnosis of mild cognitive impairment due to Alzheimer's disease: Recommendations from the National Institute on Aging‐Alzheimer's Association workgroups on diagnostic guidelines for Alzheimer's disease
  publication-title: Alzheimers Dement
– volume: 17
  start-page: 825
  issue: 2
  year: 2002
  end-page: 841
  article-title: Improved optimization for the robust and accurate linear registration and motion correction of brain images
  publication-title: NeuroImage
– volume: 15
  start-page: 155
  issue: 2
  year: 2016
  end-page: 163
  article-title: A guideline of selecting and reporting intraclass correlation coefficients for reliability research
  publication-title: Journal of Chiropractic Medicine
– volume: 111
  start-page: 526
  year: 2015
  end-page: 541
  article-title: Quantitative comparison of 21 protocols for labeling hippocampal subfields and parahippocampal subregions in in vivo MRI: Towards a harmonized segmentation protocol
  publication-title: NeuroImage
– volume: 18
  start-page: 180
  issue: 2
  year: 2012
  end-page: 200
  article-title: Hippocampal volume reduction in first‐episode and chronic schizophrenia: A review and meta‐analysis
  publication-title: The Neuroscientist
– volume: 7
  start-page: 263
  issue: 3
  year: 2011
  end-page: 269
  article-title: The diagnosis of dementia due to Alzheimer's disease: Recommendations from the National Institute on Aging‐Alzheimer's Association workgroups on diagnostic guidelines for Alzheimer's disease
  publication-title: Alzheimers Dement
– volume: 15
  start-page: 1
  year: 2021
  end-page: 22
  article-title: Convolutional neural networks in medical image understanding: A survey
  publication-title: Evolutionary Intelligence
– volume: 62
  start-page: 782
  issue: 2
  year: 2012
  end-page: 790
  article-title: FSL
  publication-title: NeuroImage
– year: 2020
– volume: 256
  start-page: 240
  issue: 3
  year: 2004
  end-page: 246
  article-title: Mild cognitive impairment‐‐beyond controversies, towards a consensus: Report of the international working group on mild cognitive impairment
  publication-title: Journal of Internal Medicine
– volume: 12
  issue: 10
  year: 2017
  article-title: MRI‐assessed atrophy subtypes in Alzheimer's disease and the cognitive reserve hypothesis
  publication-title: PLoS One
– volume: 52
  start-page: 167
  year: 2017
  end-page: 182.e1
  article-title: Clinical validity of medial temporal atrophy as a biomarker for Alzheimer's disease in the context of a structured 5‐phase development framework
  publication-title: Neurobiology of Aging
– volume: 9
  start-page: 58
  issue: Pt 2
  year: 2006
  end-page: 66
  article-title: Symmetric atlasing and model based segmentation: An application to the hippocampus in older adults
  publication-title: Medical Image Computing and Computer‐Assisted Intervention
– volume: 68
  start-page: 288
  issue: 4
  year: 2007
  end-page: 291
  article-title: Conversion from subtypes of mild cognitive impairment to Alzheimer dementia
  publication-title: Neurology
– volume: 43
  start-page: 234
  year: 2020
  end-page: 243
  article-title: Testing a convolutional neural network‐based hippocampal segmentation method in a stroke population
  publication-title: Human Brain Mapping
– year: 2019
– volume: 5
  start-page: 143
  issue: 2
  year: 2001
  end-page: 156
  article-title: A global optimisation method for robust affine registration of brain images
  publication-title: Medical Image Analysis
– year: 2015
– volume: 25
  start-page: 939
  issue: 8
  year: 2015
  end-page: 951
  article-title: Diagnostic differentiation of mild cognitive impairment due to Alzheimer's disease using a hippocampus‐dependent test of spatial memory
  publication-title: Hippocampus
– volume: 21
  start-page: 51
  issue: 1
  year: 2006
  end-page: 58
  article-title: Conversion of mild cognitive impairment to dementia: Predictive role of mild cognitive impairment subtypes and vascular risk factors
  publication-title: Dementia and Geriatric Cognitive Disorders
– volume: 133
  start-page: 3336
  issue: 11
  year: 2010
  end-page: 3348
  article-title: Brain beta‐amyloid measures and magnetic resonance imaging atrophy both predict time‐to‐progression from mild cognitive impairment to Alzheimer's disease
  publication-title: Brain
– volume: 12
  year: 2018
  article-title: Neural correlates of anosognosia in Alzheimer's disease and mild cognitive impairment: A multi‐method assessment
  publication-title: Frontiers in Behavioral Neuroscience
– ident: e_1_2_12_35_1
  doi: 10.1002/hbm.10062
– ident: e_1_2_12_19_1
  doi: 10.1016/s1361-8415(01)00036-6
– ident: e_1_2_12_4_1
  doi: 10.1098/rspa.1937.0109
– ident: e_1_2_12_5_1
  doi: 10.1016/j.jalz.2013.03.001
– ident: e_1_2_12_26_1
  doi: 10.1002/hbm.24803
– ident: e_1_2_12_22_1
  doi: 10.1016/j.jcm.2016.02.012
– ident: e_1_2_12_46_1
  doi: 10.1016/s1076-6332(03)00671-8
– ident: e_1_2_12_27_1
  doi: 10.1109/TKDE.2009.191
– ident: e_1_2_12_36_1
  doi: 10.1016/j.neurobiolaging.2016.05.024
– ident: e_1_2_12_21_1
– ident: e_1_2_12_8_1
  doi: 10.1148/radiology.216.3.r00au37672
– ident: e_1_2_12_6_1
  doi: 10.1016/j.media.2019.03.009
– ident: e_1_2_12_44_1
  doi: 10.1016/j.biopsych.2013.04.015
– ident: e_1_2_12_11_1
  doi: 10.1212/01.wnl.0000252358.03285.9d
– ident: e_1_2_12_34_1
  doi: 10.1007/s12065-020-00540-3
– ident: e_1_2_12_13_1
  doi: 10.1007/11866763_8
– ident: e_1_2_12_41_1
  doi: 10.1016/j.neurobiolaging.2011.05.018
– volume: 2
  start-page: 2017
  year: 2015
  ident: e_1_2_12_16_1
  article-title: Spatial transformer networks
  publication-title: Advances in Neural Information Processing Systems 28 (NIPS 2015)
– ident: e_1_2_12_40_1
  doi: 10.3389/fnbeh.2018.00100
– ident: e_1_2_12_25_1
  doi: 10.1002/hipo.22417
– ident: e_1_2_12_45_1
  doi: 10.1002/hbm.25210
– ident: e_1_2_12_20_1
– ident: e_1_2_12_31_1
– ident: e_1_2_12_10_1
  doi: 10.1016/j.neuroimage.2020.117689
– ident: e_1_2_12_3_1
  doi: 10.1016/j.jalz.2011.03.008
– ident: e_1_2_12_23_1
  doi: 10.1016/j.jalz.2011.03.005
– ident: e_1_2_12_38_1
  doi: 10.1523/JNEUROSCI.23-03-00994.2003
– ident: e_1_2_12_7_1
  doi: 10.1002/alz.12177
– ident: e_1_2_12_29_1
  doi: 10.1056/NEJMoa050151
– ident: e_1_2_12_24_1
  doi: 10.1002/hbm.23772
– volume-title: U‐Net: Convolutional Networks for Biomedical Image Segmentation
  year: 2015
  ident: e_1_2_12_32_1
– ident: e_1_2_12_37_1
– ident: e_1_2_12_39_1
  doi: 10.1196/annals.1379.017
– ident: e_1_2_12_12_1
  doi: 10.1016/j.jalz.2014.05.1761
– ident: e_1_2_12_28_1
  doi: 10.1371/journal.pone.0186595
– ident: e_1_2_12_15_1
  doi: 10.1093/brain/awq277
– ident: e_1_2_12_42_1
  doi: 10.1111/j.1365‐2796.2004.01380.x
– ident: e_1_2_12_2_1
  doi: 10.1177/1073858410395147
– ident: e_1_2_12_18_1
  doi: 10.1016/j.neuroimage.2011.09.015
– ident: e_1_2_12_30_1
  doi: 10.1159/000089515
– ident: e_1_2_12_33_1
– ident: e_1_2_12_43_1
  doi: 10.1016/j.neuroimage.2015.01.004
– ident: e_1_2_12_9_1
  doi: 10.1007/978-3-030-32248-9_32
– ident: e_1_2_12_14_1
  doi: 10.1016/j.neuroimage.2009.06.060
– ident: e_1_2_12_17_1
  doi: 10.1016/s1053-8119(02)91132-8
SSID ssj0011501
Score 2.494589
Snippet Research on segmentation of the hippocampus in magnetic resonance images through deep learning convolutional neural networks (CNNs) shows promising results,...
SourceID pubmedcentral
proquest
pubmed
crossref
wiley
SourceType Open Access Repository
Aggregation Database
Index Database
Enrichment Source
Publisher
StartPage 3427
SubjectTerms Abnormalities
Alzheimer disease
Alzheimer's disease
Artificial neural networks
Biomarkers
Cognitive ability
Datasets
Deep learning
Domains
Hippocampus
Image processing
Image segmentation
Impairment
Magnetic resonance imaging
Medical imaging
mild cognitive impairment
Neural networks
Neurodegenerative diseases
Training
Transfer learning
Title The impact of transfer learning on 3D deep learning convolutional neural network segmentation of the hippocampus in mild cognitive impairment and Alzheimer disease subjects
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fhbm.25858
https://www.ncbi.nlm.nih.gov/pubmed/35373881
https://www.proquest.com/docview/2682729240
https://www.proquest.com/docview/2646940026
https://pubmed.ncbi.nlm.nih.gov/PMC9248306
Volume 43
hasFullText 1
inHoldings 1
isFullTextHit
isPrint
link http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV3db9MwED-NISFeGGx8ZIzKIIR4SZc6TuKIpw42VUidpolJfUCK4tpeI5o0apoH9jfxR3J2PkYZSIiXNGousaOcz7-z734H8DZM5ZwGgrq-ioXLUIVcrrTvojvkzU21Y24z5Kbn4eSKfZ4Fsx340OXCNPwQ_YKbGRnWXpsBnorq-JY0dCHyIUWwaxJ9TayWAUSXPXWUATrW2cIp1o3RAnesQh497u_cnovuAMy7cZK_4lc7AZ3twdeu603cybdhvRHD-c1vrI7_-W6P4VELTMm40aQnsKOKfTgYF-iU59_JO2JDRe0a_D48mLY78gfwA_WMNKmWZKXJxuJgtSZtNYprsiqI_4lIpcrb_0yoe6vy2KSh1LQ_NiCdVOo6bxOiCvtIbGCRlSVOunlZVyQrSJ4tJekDn2zz2drcRNJCkvHyZqGyHDvR7j6RqhZmual6Cldnp18-Tty2AoQ7ZwwtMdM89D0hqEZDpBC7jUJEuFpHWqRBqhQLpdS-5p5PVcx0GGn0H7kXKylkgH6D_wx2i1WhXgBBO6X8OIh5KhXTIuIy5ohNcDaWI6GV78D7TheSeUuPbqp0LJOG2Jkm-FES-1EceNOLlg0nyJ-EjjqFSlqzUCU05BS9GURRDrzuL-OANrs0aaFWtZFhoalWT0MHnjf617fiB4aIio8ciLY0sxcwZOHbV4psYUnDsVGO7iG-plW8v3c8mZxM7cnhv4u-hIfUpIXYwMgj2N2sa_UKwdpGDOAeZRd4jGbRAO6fnJ5fXA7swsfAjtef2uxDlA
linkProvider Wiley-Blackwell
linkToHtml http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV3db9MwED-NIQEvfGwMAgMMQoiXdKmdpI7ES_mYCqx7QJu0FxTFsb1GNG7VNA_sb-KP5Ox8jDKQEE-tmkvPUc7n39l3vwN4GWcyp5GgPlOJ8EM0IZ8rzXwMh4LcdjvmrkJuehxPTsNPZ9HZFrzpamEafoh-w83ODOev7QS3G9IHl6yhM1EOKKJdfg2u247eLqD60pNHWajjwi1cZP0EfXDHKxTQg_7WzdXoCsS8min5K4J1S9DhHfjaDb7JPPk2qNdikF_8xuv4v093F2632JSMG2O6B1vK7MDu2GBcXn4nr4jLFnXb8DtwY9oeyu_CDzQ10lRbkoUmaweF1Yq0DSnOycIQ9p5IpZaXv9ls99bqUaVl1XQfLiedVOq8bGuijPtLVDArlktcd8tlXZHCkLKYS9LnPjn1xcreRDIjyXh-MVNFiYNoD6BIVQu741Tdh9PDDyfvJn7bBMLPwxCdcah5zAIhqEZfpBC-DWMEuVqPtMiiTKkwllIzzQNGVRLqeKQxhORBoqSQEYYObA-2zcKoh0DQVSmWRAnPpAq1GHGZcIQnuCDLodCKefC6M4Y0bxnSbaOOedpwO9MUX0rqXooHL3rRZUML8ieh_c6i0tYzVCmNOcWABoGUB8_7yzin7UFNZtSitjJhbBvW09iDB40B9lpYZLmo-NCD0YZp9gKWL3zziilmjjcclXKMEPExneX9feDp5O3UfXn076LP4ObkZHqUHn08_vwYblFbJeLyJPdhe72q1RPEbmvx1E3Rn_EqQ2I
linkToPdf http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV3db9MwED-NIU288LHBCAwwCCFe0qV2kjriqVCq8tEJISbtASmKY3uNaNKoaR7Y38Qfydn5GGUgIZ5SJZeeI5_vw777HcDzMJEpDQR1mYqE66MIuVxp5mI45KWm2zG3FXLzk3B26r8_C8524FVXC9PgQ_QbbmZlWH1tFngp9fElaOhC5AOKzi6_Btf90ONGpCefe-wo4-nYaAttrBuhCu5ghTx63L-6bYyueJhXEyV_dWCtBZregq_d2JvEk2-DeiMG6cVvsI7_-XG34WbrmZJxI0p3YEcV-3AwLjAqz7-TF8TmitpN-H3Ym7dH8gfwAwWNNLWWZKXJxjrCak3adhTnZFUQNiFSqfLynsl1b2UeWRpMTXuxGemkUud5WxFV2L9EBousLNHq5mVdkawgebaUpM98suyztXmJJIUk4-XFQmU5DqI9fiJVLcx-U3UXTqdvv7yZuW0LCDf1fVTFvuYh84SgGjWRQudtiDPtaT3SIgkSpfxQSs009xhVka_DkcYAknuRkkIGGDiwe7BbrAp1HwgqKsWiIOKJVL4WIy4jjs4JmmM5FFoxB152shCnLT66adOxjBtkZxrjpMR2Uhx41pOWDSjIn4iOOoGKW71QxTTkFMMZdKMceNo_xhVtjmmSQq1qQ-OHpl09DR04bOSv58ICg0TFhw6MtiSzJzBo4dtPimxhUcORKcf4ED_TCt7fBx7PXs_tjwf_TvoE9j5NpvHHdycfHsINakpEbJLkEexu1rV6hI7bRjy2C_QnJB1CGg
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=The+impact+of+transfer+learning+on+3D+deep+learning+convolutional+neural+network+segmentation+of+the+hippocampus+in+mild+cognitive+impairment+and+Alzheimer+disease+subjects&rft.jtitle=Human+brain+mapping&rft.au=Balboni%2C+Erica&rft.au=Nocetti%2C+Luca&rft.au=Carbone%2C+Chiara&rft.au=Dinsdale%2C+Nicola&rft.date=2022-08-01&rft.issn=1065-9471&rft.eissn=1097-0193&rft.volume=43&rft.issue=11&rft.spage=3427&rft.epage=3438&rft_id=info:doi/10.1002%2Fhbm.25858&rft.externalDBID=n%2Fa&rft.externalDocID=10_1002_hbm_25858
thumbnail_l http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=1065-9471&client=summon
thumbnail_m http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=1065-9471&client=summon
thumbnail_s http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=1065-9471&client=summon