Data‐driven self‐calibration and reconstruction for non‐cartesian wave‐encoded single‐shot fast spin echo using deep learning

Background Current self‐calibration and reconstruction methods for wave‐encoded single‐shot fast spin echo imaging (SSFSE) requires long computational time, especially when high accuracy is needed. Purpose To develop and investigate the clinical feasibility of data‐driven self‐calibration and recons...

Full description

Saved in:
Bibliographic Details
Published inJournal of magnetic resonance imaging Vol. 51; no. 3; pp. 841 - 853
Main Authors Chen, Feiyu, Cheng, Joseph Y., Taviani, Valentina, Sheth, Vipul R., Brunsing, Ryan L., Pauly, John M., Vasanawala, Shreyas S.
Format Journal Article
LanguageEnglish
Published Hoboken, USA John Wiley & Sons, Inc 01.03.2020
Wiley Subscription Services, Inc
Subjects
Abdomen
Acceleration
Adult
Aged
Artificial neural networks
Calibration
Cartesian coordinates
Coding
Computer applications
Computing time
Confidence
Data acquisition
data‐driven
Deep Learning
Female
Females
Field strength
Humans
Image Processing, Computer-Assisted
Image quality
Image reconstruction
Iterative methods
Magnetic Resonance Imaging
Male
Males
Middle Aged
Neural networks
Noise
Noise levels
parallel imaging and compressed sensing
Prospective Studies
Quality assessment
Quality control
Rank tests
Sharpness
Shot
single‐shot fast spin echo
Statistical analysis
Statistical tests
wave encoding
Young Adult
single-shot fast spin echo
deep learning
wave encoding
data-driven
parallel imaging and compressed sensing
Online AccessGet full text
ISSN1053-1807
1522-2586
1522-2586
DOI10.1002/jmri.26871

Cover

Abstract Background Current self‐calibration and reconstruction methods for wave‐encoded single‐shot fast spin echo imaging (SSFSE) requires long computational time, especially when high accuracy is needed. Purpose To develop and investigate the clinical feasibility of data‐driven self‐calibration and reconstruction of wave‐encoded SSFSE imaging for computation time reduction and quality improvement. Study Type Prospective controlled clinical trial. Subjects With Institutional Review Board approval, the proposed method was assessed on 29 consecutive adult patients (18 males, 11 females, range, 24–77 years). Field Strength/Sequence A wave‐encoded variable‐density SSFSE sequence was developed for clinical 3.0T abdominal scans to enable 3.5× acceleration with full‐Fourier acquisitions. Data‐driven calibration of wave‐encoding point‐spread function (PSF) was developed using a trained deep neural network. Data‐driven reconstruction was developed with another set of neural networks based on the calibrated wave‐encoding PSF. Training of the calibration and reconstruction networks was performed on 15,783 2D wave‐encoded SSFSE abdominal images. Assessment Image quality of the proposed data‐driven approach was compared independently and blindly with a conventional approach using iterative self‐calibration and reconstruction with parallel imaging and compressed sensing by three radiologists on a scale from –2 to 2 for noise, contrast, sharpness, artifacts, and confidence. Computation time of these two approaches was also compared. Statistical Tests Wilcoxon signed‐rank tests were used to compare image quality and two‐tailed t‐tests were used to compare computation time with P values of under 0.05 considered statistically significant. Results An average 2.1‐fold speedup in computation was achieved using the proposed method. The proposed data‐driven self‐calibration and reconstruction approach significantly reduced the perceived noise level (mean scores 0.82, P < 0.0001). Data Conclusion The proposed data‐driven calibration and reconstruction achieved twice faster computation with reduced perceived noise, providing a fast and robust self‐calibration and reconstruction for clinical abdominal SSFSE imaging. Level of Evidence: 1 Technical Efficacy: Stage 1 J. Magn. Reson. Imaging 2020;51:841–853.
AbstractList Current self-calibration and reconstruction methods for wave-encoded single-shot fast spin echo imaging (SSFSE) requires long computational time, especially when high accuracy is needed.BACKGROUNDCurrent self-calibration and reconstruction methods for wave-encoded single-shot fast spin echo imaging (SSFSE) requires long computational time, especially when high accuracy is needed.To develop and investigate the clinical feasibility of data-driven self-calibration and reconstruction of wave-encoded SSFSE imaging for computation time reduction and quality improvement.PURPOSETo develop and investigate the clinical feasibility of data-driven self-calibration and reconstruction of wave-encoded SSFSE imaging for computation time reduction and quality improvement.Prospective controlled clinical trial.STUDY TYPEProspective controlled clinical trial.With Institutional Review Board approval, the proposed method was assessed on 29 consecutive adult patients (18 males, 11 females, range, 24-77 years).SUBJECTSWith Institutional Review Board approval, the proposed method was assessed on 29 consecutive adult patients (18 males, 11 females, range, 24-77 years).A wave-encoded variable-density SSFSE sequence was developed for clinical 3.0T abdominal scans to enable 3.5× acceleration with full-Fourier acquisitions. Data-driven calibration of wave-encoding point-spread function (PSF) was developed using a trained deep neural network. Data-driven reconstruction was developed with another set of neural networks based on the calibrated wave-encoding PSF. Training of the calibration and reconstruction networks was performed on 15,783 2D wave-encoded SSFSE abdominal images.FIELD STRENGTH/SEQUENCEA wave-encoded variable-density SSFSE sequence was developed for clinical 3.0T abdominal scans to enable 3.5× acceleration with full-Fourier acquisitions. Data-driven calibration of wave-encoding point-spread function (PSF) was developed using a trained deep neural network. Data-driven reconstruction was developed with another set of neural networks based on the calibrated wave-encoding PSF. Training of the calibration and reconstruction networks was performed on 15,783 2D wave-encoded SSFSE abdominal images.Image quality of the proposed data-driven approach was compared independently and blindly with a conventional approach using iterative self-calibration and reconstruction with parallel imaging and compressed sensing by three radiologists on a scale from -2 to 2 for noise, contrast, sharpness, artifacts, and confidence. Computation time of these two approaches was also compared.ASSESSMENTImage quality of the proposed data-driven approach was compared independently and blindly with a conventional approach using iterative self-calibration and reconstruction with parallel imaging and compressed sensing by three radiologists on a scale from -2 to 2 for noise, contrast, sharpness, artifacts, and confidence. Computation time of these two approaches was also compared.Wilcoxon signed-rank tests were used to compare image quality and two-tailed t-tests were used to compare computation time with P values of under 0.05 considered statistically significant.STATISTICAL TESTSWilcoxon signed-rank tests were used to compare image quality and two-tailed t-tests were used to compare computation time with P values of under 0.05 considered statistically significant.An average 2.1-fold speedup in computation was achieved using the proposed method. The proposed data-driven self-calibration and reconstruction approach significantly reduced the perceived noise level (mean scores 0.82, P < 0.0001).RESULTSAn average 2.1-fold speedup in computation was achieved using the proposed method. The proposed data-driven self-calibration and reconstruction approach significantly reduced the perceived noise level (mean scores 0.82, P < 0.0001).The proposed data-driven calibration and reconstruction achieved twice faster computation with reduced perceived noise, providing a fast and robust self-calibration and reconstruction for clinical abdominal SSFSE imaging.DATA CONCLUSIONThe proposed data-driven calibration and reconstruction achieved twice faster computation with reduced perceived noise, providing a fast and robust self-calibration and reconstruction for clinical abdominal SSFSE imaging.1 Technical Efficacy: Stage 1 J. Magn. Reson. Imaging 2020;51:841-853.LEVEL OF EVIDENCE1 Technical Efficacy: Stage 1 J. Magn. Reson. Imaging 2020;51:841-853.
BackgroundCurrent self‐calibration and reconstruction methods for wave‐encoded single‐shot fast spin echo imaging (SSFSE) requires long computational time, especially when high accuracy is needed.PurposeTo develop and investigate the clinical feasibility of data‐driven self‐calibration and reconstruction of wave‐encoded SSFSE imaging for computation time reduction and quality improvement.Study TypeProspective controlled clinical trial.SubjectsWith Institutional Review Board approval, the proposed method was assessed on 29 consecutive adult patients (18 males, 11 females, range, 24–77 years).Field Strength/SequenceA wave‐encoded variable‐density SSFSE sequence was developed for clinical 3.0T abdominal scans to enable 3.5× acceleration with full‐Fourier acquisitions. Data‐driven calibration of wave‐encoding point‐spread function (PSF) was developed using a trained deep neural network. Data‐driven reconstruction was developed with another set of neural networks based on the calibrated wave‐encoding PSF. Training of the calibration and reconstruction networks was performed on 15,783 2D wave‐encoded SSFSE abdominal images.AssessmentImage quality of the proposed data‐driven approach was compared independently and blindly with a conventional approach using iterative self‐calibration and reconstruction with parallel imaging and compressed sensing by three radiologists on a scale from –2 to 2 for noise, contrast, sharpness, artifacts, and confidence. Computation time of these two approaches was also compared.Statistical TestsWilcoxon signed‐rank tests were used to compare image quality and two‐tailed t‐tests were used to compare computation time with P values of under 0.05 considered statistically significant.ResultsAn average 2.1‐fold speedup in computation was achieved using the proposed method. The proposed data‐driven self‐calibration and reconstruction approach significantly reduced the perceived noise level (mean scores 0.82, P < 0.0001).Data ConclusionThe proposed data‐driven calibration and reconstruction achieved twice faster computation with reduced perceived noise, providing a fast and robust self‐calibration and reconstruction for clinical abdominal SSFSE imaging.Level of Evidence: 1Technical Efficacy: Stage 1J. Magn. Reson. Imaging 2020;51:841–853.
Current self-calibration and reconstruction methods for wave-encoded single-shot fast spin echo imaging (SSFSE) requires long computational time, especially when high accuracy is needed. To develop and investigate the clinical feasibility of data-driven self-calibration and reconstruction of wave-encoded SSFSE imaging for computation time reduction and quality improvement. Prospective controlled clinical trial. With Institutional Review Board approval, the proposed method was assessed on 29 consecutive adult patients (18 males, 11 females, range, 24-77 years). A wave-encoded variable-density SSFSE sequence was developed for clinical 3.0T abdominal scans to enable 3.5× acceleration with full-Fourier acquisitions. Data-driven calibration of wave-encoding point-spread function (PSF) was developed using a trained deep neural network. Data-driven reconstruction was developed with another set of neural networks based on the calibrated wave-encoding PSF. Training of the calibration and reconstruction networks was performed on 15,783 2D wave-encoded SSFSE abdominal images. Image quality of the proposed data-driven approach was compared independently and blindly with a conventional approach using iterative self-calibration and reconstruction with parallel imaging and compressed sensing by three radiologists on a scale from -2 to 2 for noise, contrast, sharpness, artifacts, and confidence. Computation time of these two approaches was also compared. Wilcoxon signed-rank tests were used to compare image quality and two-tailed t-tests were used to compare computation time with P values of under 0.05 considered statistically significant. An average 2.1-fold speedup in computation was achieved using the proposed method. The proposed data-driven self-calibration and reconstruction approach significantly reduced the perceived noise level (mean scores 0.82, P < 0.0001). The proposed data-driven calibration and reconstruction achieved twice faster computation with reduced perceived noise, providing a fast and robust self-calibration and reconstruction for clinical abdominal SSFSE imaging. 1 Technical Efficacy: Stage 1 J. Magn. Reson. Imaging 2020;51:841-853.
Background Current self‐calibration and reconstruction methods for wave‐encoded single‐shot fast spin echo imaging (SSFSE) requires long computational time, especially when high accuracy is needed. Purpose To develop and investigate the clinical feasibility of data‐driven self‐calibration and reconstruction of wave‐encoded SSFSE imaging for computation time reduction and quality improvement. Study Type Prospective controlled clinical trial. Subjects With Institutional Review Board approval, the proposed method was assessed on 29 consecutive adult patients (18 males, 11 females, range, 24–77 years). Field Strength/Sequence A wave‐encoded variable‐density SSFSE sequence was developed for clinical 3.0T abdominal scans to enable 3.5× acceleration with full‐Fourier acquisitions. Data‐driven calibration of wave‐encoding point‐spread function (PSF) was developed using a trained deep neural network. Data‐driven reconstruction was developed with another set of neural networks based on the calibrated wave‐encoding PSF. Training of the calibration and reconstruction networks was performed on 15,783 2D wave‐encoded SSFSE abdominal images. Assessment Image quality of the proposed data‐driven approach was compared independently and blindly with a conventional approach using iterative self‐calibration and reconstruction with parallel imaging and compressed sensing by three radiologists on a scale from –2 to 2 for noise, contrast, sharpness, artifacts, and confidence. Computation time of these two approaches was also compared. Statistical Tests Wilcoxon signed‐rank tests were used to compare image quality and two‐tailed t‐tests were used to compare computation time with P values of under 0.05 considered statistically significant. Results An average 2.1‐fold speedup in computation was achieved using the proposed method. The proposed data‐driven self‐calibration and reconstruction approach significantly reduced the perceived noise level (mean scores 0.82, P < 0.0001). Data Conclusion The proposed data‐driven calibration and reconstruction achieved twice faster computation with reduced perceived noise, providing a fast and robust self‐calibration and reconstruction for clinical abdominal SSFSE imaging. Level of Evidence: 1 Technical Efficacy: Stage 1 J. Magn. Reson. Imaging 2020;51:841–853.
Author Vasanawala, Shreyas S.
Pauly, John M.
Taviani, Valentina
Cheng, Joseph Y.
Sheth, Vipul R.
Brunsing, Ryan L.
Chen, Feiyu
AuthorAffiliation 1 Department of Electrical Engineering, Stanford University, Stanford, California, USA
3 Global MR Applications and Workflow, GE Healthcare, Menlo Park, California, USA
2 Department of Radiology, Stanford University, Stanford, California, USA
AuthorAffiliation_xml – name: 3 Global MR Applications and Workflow, GE Healthcare, Menlo Park, California, USA
– name: 2 Department of Radiology, Stanford University, Stanford, California, USA
– name: 1 Department of Electrical Engineering, Stanford University, Stanford, California, USA
Author_xml – sequence: 1
  givenname: Feiyu
  orcidid: 0000-0002-2259-698X
  surname: Chen
  fullname: Chen, Feiyu
  email: feiyuc@stanford.edu
  organization: Stanford University, Stanford
– sequence: 2
  givenname: Joseph Y.
  surname: Cheng
  fullname: Cheng, Joseph Y.
  organization: Stanford University, Stanford
– sequence: 3
  givenname: Valentina
  surname: Taviani
  fullname: Taviani, Valentina
  organization: Global MR Applications and Workflow, GE Healthcare
– sequence: 4
  givenname: Vipul R.
  surname: Sheth
  fullname: Sheth, Vipul R.
  organization: Stanford University, Stanford
– sequence: 5
  givenname: Ryan L.
  orcidid: 0000-0003-0116-3517
  surname: Brunsing
  fullname: Brunsing, Ryan L.
  organization: Stanford University, Stanford
– sequence: 6
  givenname: John M.
  surname: Pauly
  fullname: Pauly, John M.
  organization: Stanford University, Stanford
– sequence: 7
  givenname: Shreyas S.
  surname: Vasanawala
  fullname: Vasanawala, Shreyas S.
  organization: Stanford University, Stanford
BackLink https://www.ncbi.nlm.nih.gov/pubmed/31322799$$D View this record in MEDLINE/PubMed
BookMark eNp9kcluFDEQhlsoiCxw4QGQJS4I1MF2b-4LEgpbUBASgrPlpZzxyGN37O4ZzY0bV56RJ8EzHbYI5WRX1Velv_46Lg588FAUDwk-JRjT58tVtKe0ZR25UxyRhtKSNqw9yH_cVCVhuDssjlNaYoz7vm7uFYcVqSjt-v6o-PZKjOLH1-862jV4lMCZHCnhrIxitMEj4TWKoIJPY5zUPmVCRFnDHowjJCs82og15AR4FTRolKy_dLtEWoQRGZFGlAbrEahFQNOuijTAgByI6HN0v7hrhEvw4Po9Kb68ef357F158fHt-dnLi1LVNSOlrPpOd0bKvlKSNHUvGy0x1Aoz2lJTs57kGlQVMVhiqiQ1pmllg43QmihZnRTP5rmTH8R2I5zjQ7QrEbecYL6zk-_s5Hs7M_1ipodJrkAr8GMUfzqCsPzfircLfhnWnGHCGKnzgCfXA2K4miCNfGWTAueEhzAlTmlLsnDKqow-voEuwxR9NoPTqqFN12OGM_Xob0W_pfy6aAbwDKgYUopguLLj_pJZoHX_3_LpjZZbLSEzvLEOtreQ_P2HT-dzz09569qZ
CitedBy_id crossref_primary_10_1097_RCT_0000000000001491
crossref_primary_10_1016_j_desal_2024_117353
crossref_primary_10_1109_JPROC_2022_3141367
crossref_primary_10_3390_diagnostics12102370
crossref_primary_10_1002_mrm_30105
crossref_primary_10_3390_diagnostics12092164
crossref_primary_10_1002_mp_16425
crossref_primary_10_3390_electronics11040586
crossref_primary_10_1007_s12312_024_01374_1
crossref_primary_10_1007_s00330_021_08008_3
crossref_primary_10_1088_1361_6560_acc003
crossref_primary_10_1109_TMI_2020_3022968
crossref_primary_10_1002_mrm_28912
crossref_primary_10_1002_jmri_28453
crossref_primary_10_1002_mrm_28446
crossref_primary_10_1109_TCI_2025_3544019
crossref_primary_10_1016_j_ejrad_2022_110588
crossref_primary_10_1148_radiol_2021202624
crossref_primary_10_1038_s41598_020_70551_8
Cites_doi 10.1002/mrm.25290
10.1002/mrm.27488
10.1002/mrm.25615
10.1002/jmri.1880060420
10.1002/mrm.21680
10.1016/j.mri.2014.10.006
10.1148/radiol.2018180445
10.1148/radiol.2016151574
10.1002/mrm.26977
10.1002/mrm.25347
10.1002/jmri.25853
10.1002/mrm.26567
10.1002/jmri.21463
10.1109/TMI.2018.2799231
10.1002/jmri.24941
10.1148/radiology.161.2.3763926
10.1002/jmri.24542
10.1002/mrm.21391
10.1002/mrm.26499
10.1080/00401706.1975.10489269
10.1002/mrm.24751
10.1007/978-3-319-24574-4_28
ContentType Journal Article
Copyright 2019 International Society for Magnetic Resonance in Medicine
2019 International Society for Magnetic Resonance in Medicine.
2020 International Society for Magnetic Resonance in Medicine
Copyright_xml – notice: 2019 International Society for Magnetic Resonance in Medicine
– notice: 2019 International Society for Magnetic Resonance in Medicine.
– notice: 2020 International Society for Magnetic Resonance in Medicine
DBID AAYXX
CITATION
CGR
CUY
CVF
ECM
EIF
NPM
7QO
7TK
8FD
FR3
K9.
P64
7X8
5PM
ADTOC
UNPAY
DOI 10.1002/jmri.26871
DatabaseName CrossRef
Medline
MEDLINE
MEDLINE (Ovid)
MEDLINE
MEDLINE
PubMed
Biotechnology Research Abstracts
Neurosciences Abstracts
Technology Research Database
Engineering Research Database
ProQuest Health & Medical Complete (Alumni)
Biotechnology and BioEngineering Abstracts
MEDLINE - Academic
PubMed Central (Full Participant titles)
Unpaywall for CDI: Periodical Content
Unpaywall
DatabaseTitle CrossRef
MEDLINE
Medline Complete
MEDLINE with Full Text
PubMed
MEDLINE (Ovid)
ProQuest Health & Medical Complete (Alumni)
Engineering Research Database
Biotechnology Research Abstracts
Technology Research Database
Neurosciences Abstracts
Biotechnology and BioEngineering Abstracts
MEDLINE - Academic
DatabaseTitleList MEDLINE - Academic
ProQuest Health & Medical Complete (Alumni)
MEDLINE
Database_xml – sequence: 1
  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
– sequence: 2
  dbid: EIF
  name: MEDLINE
  url: https://proxy.k.utb.cz/login?url=https://www.webofscience.com/wos/medline/basic-search
  sourceTypes: Index Database
– sequence: 3
  dbid: UNPAY
  name: Unpaywall
  url: https://proxy.k.utb.cz/login?url=https://unpaywall.org/
  sourceTypes: Open Access Repository
DeliveryMethod fulltext_linktorsrc
Discipline Medicine
EISSN 1522-2586
EndPage 853
ExternalDocumentID oai:pubmedcentral.nih.gov:8018814
PMC8018814
31322799
10_1002_jmri_26871
JMRI26871
Genre article
Controlled Clinical Trial
Research Support, Non-U.S. Gov't
Journal Article
Research Support, N.I.H., Extramural
GrantInformation_xml – fundername: NIH/NIBIB
  funderid: R01 EB009690; R01 EB019241; R01 HL136965 01a1
– fundername: GE Healthcare
– fundername: NHLBI NIH HHS
  grantid: R01 HL136965
– fundername: NIBIB NIH HHS
  grantid: R01 EB019241
– fundername: NIBIB NIH HHS
  grantid: R01 EB009690
GroupedDBID ---
-DZ
.3N
.GA
.GJ
.Y3
05W
0R~
10A
1L6
1OB
1OC
1ZS
24P
31~
33P
3O-
3SF
3WU
4.4
4ZD
50Y
50Z
51W
51X
52M
52N
52O
52P
52R
52S
52T
52U
52V
52W
52X
53G
5GY
5RE
5VS
66C
702
7PT
8-0
8-1
8-3
8-4
8-5
8UM
930
A01
A03
AAESR
AAEVG
AAHHS
AAHQN
AAIPD
AAMNL
AANHP
AANLZ
AAONW
AASGY
AAWTL
AAXRX
AAYCA
AAZKR
ABCQN
ABCUV
ABEML
ABIJN
ABJNI
ABLJU
ABOCM
ABPVW
ABQWH
ABXGK
ACAHQ
ACBWZ
ACCFJ
ACCZN
ACGFO
ACGFS
ACGOF
ACIWK
ACMXC
ACPOU
ACPRK
ACRPL
ACSCC
ACXBN
ACXQS
ACYXJ
ADBBV
ADBTR
ADEOM
ADIZJ
ADKYN
ADMGS
ADNMO
ADOZA
ADXAS
ADZMN
AEEZP
AEGXH
AEIGN
AEIMD
AENEX
AEQDE
AEUQT
AEUYR
AFBPY
AFFPM
AFGKR
AFPWT
AFRAH
AFWVQ
AFZJQ
AHBTC
AHMBA
AIACR
AIAGR
AITYG
AIURR
AIWBW
AJBDE
ALAGY
ALMA_UNASSIGNED_HOLDINGS
ALUQN
ALVPJ
AMBMR
AMYDB
ASPBG
ATUGU
AVWKF
AZBYB
AZFZN
AZVAB
BAFTC
BDRZF
BFHJK
BHBCM
BMXJE
BROTX
BRXPI
BY8
C45
CS3
D-6
D-7
D-E
D-F
DCZOG
DPXWK
DR2
DRFUL
DRMAN
DRSTM
DU5
EBD
EBS
EJD
EMOBN
F00
F01
F04
F5P
FEDTE
FUBAC
G-S
G.N
GNP
GODZA
H.X
HBH
HDBZQ
HF~
HGLYW
HHY
HHZ
HVGLF
HZ~
IX1
J0M
JPC
KBYEO
KQQ
LATKE
LAW
LC2
LC3
LEEKS
LH4
LITHE
LOXES
LP6
LP7
LUTES
LW6
LYRES
M65
MEWTI
MK4
MRFUL
MRMAN
MRSTM
MSFUL
MSMAN
MSSTM
MXFUL
MXMAN
MXSTM
N04
N05
N9A
NF~
NNB
O66
O9-
OIG
OVD
P2P
P2W
P2X
P2Z
P4B
P4D
PALCI
PQQKQ
Q.N
Q11
QB0
QRW
R.K
RGB
RIWAO
RJQFR
ROL
RWI
RX1
RYL
SAMSI
SUPJJ
SV3
TEORI
TWZ
UB1
V2E
V8K
V9Y
W8V
W99
WBKPD
WHWMO
WIB
WIH
WIJ
WIK
WIN
WJL
WOHZO
WQJ
WRC
WUP
WVDHM
WXI
WXSBR
XG1
XV2
ZXP
ZZTAW
~IA
~WT
AAMMB
AAYXX
AEFGJ
AEYWJ
AGHNM
AGQPQ
AGXDD
AGYGG
AIDQK
AIDYY
AIQQE
CITATION
CGR
CUY
CVF
ECM
EIF
NPM
7QO
7TK
8FD
FR3
K9.
P64
7X8
5PM
ADTOC
UNPAY
ID FETCH-LOGICAL-c4481-b397d7fbb93cb1549b5db0e4c08262f4891bb9e331f0b02cb2ff56b50fadd1cb3
IEDL.DBID UNPAY
ISSN 1053-1807
1522-2586
IngestDate Sun Oct 26 03:43:52 EDT 2025
Thu Aug 21 13:57:55 EDT 2025
Thu Oct 02 07:09:39 EDT 2025
Tue Oct 07 06:17:26 EDT 2025
Mon Jul 21 05:56:06 EDT 2025
Wed Oct 01 04:37:04 EDT 2025
Thu Apr 24 23:07:57 EDT 2025
Wed Jan 22 16:35:07 EST 2025
IsDoiOpenAccess true
IsOpenAccess true
IsPeerReviewed true
IsScholarly true
Issue 3
Keywords single-shot fast spin echo
deep learning
wave encoding
data-driven
parallel imaging and compressed sensing
Language English
License 2019 International Society for Magnetic Resonance in Medicine.
LinkModel DirectLink
MergedId FETCHMERGED-LOGICAL-c4481-b397d7fbb93cb1549b5db0e4c08262f4891bb9e331f0b02cb2ff56b50fadd1cb3
Notes ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 14
ObjectType-Article-2
ObjectType-Feature-1
content type line 23
ORCID 0000-0002-2259-698X
0000-0003-0116-3517
OpenAccessLink https://proxy.k.utb.cz/login?url=https://www.ncbi.nlm.nih.gov/pmc/articles/8018814
PMID 31322799
PQID 2352579080
PQPubID 1006400
PageCount 13
ParticipantIDs unpaywall_primary_10_1002_jmri_26871
pubmedcentral_primary_oai_pubmedcentral_nih_gov_8018814
proquest_miscellaneous_2261262283
proquest_journals_2352579080
pubmed_primary_31322799
crossref_citationtrail_10_1002_jmri_26871
crossref_primary_10_1002_jmri_26871
wiley_primary_10_1002_jmri_26871_JMRI26871
ProviderPackageCode CITATION
AAYXX
PublicationCentury 2000
PublicationDate March 2020
PublicationDateYYYYMMDD 2020-03-01
PublicationDate_xml – month: 03
  year: 2020
  text: March 2020
PublicationDecade 2020
PublicationPlace Hoboken, USA
PublicationPlace_xml – name: Hoboken, USA
– name: United States
– name: Nashville
PublicationSubtitle JMRI
PublicationTitle Journal of magnetic resonance imaging
PublicationTitleAlternate J Magn Reson Imaging
PublicationYear 2020
Publisher John Wiley & Sons, Inc
Wiley Subscription Services, Inc
Publisher_xml – name: John Wiley & Sons, Inc
– name: Wiley Subscription Services, Inc
References 2019; 81
2012
2015; 73
1986; 161
2015; 42
2018; 289
1975; 17
2015; 33
2008; 28
2017; 78
2019
2018
2017; 282
2017
2015
2014; 39
2008; 60
2014; 71
2007; 58
2018; 37
1996; 6
2018; 47
2018; 79
e_1_2_6_32_1
e_1_2_6_10_1
Mardani M (e_1_2_6_29_1) 2018
e_1_2_6_31_1
e_1_2_6_30_1
Krizhevsky A (e_1_2_6_25_1) 2012
e_1_2_6_19_1
e_1_2_6_13_1
e_1_2_6_14_1
e_1_2_6_11_1
e_1_2_6_12_1
Yang Y (e_1_2_6_20_1) 2017
e_1_2_6_17_1
e_1_2_6_18_1
e_1_2_6_15_1
e_1_2_6_16_1
e_1_2_6_21_1
e_1_2_6_9_1
e_1_2_6_8_1
e_1_2_6_5_1
e_1_2_6_4_1
e_1_2_6_7_1
e_1_2_6_6_1
e_1_2_6_24_1
e_1_2_6_3_1
e_1_2_6_23_1
e_1_2_6_2_1
e_1_2_6_22_1
e_1_2_6_28_1
e_1_2_6_27_1
e_1_2_6_26_1
References_xml – start-page: 234
  year: 2015
  end-page: 241
– volume: 37
  start-page: 1322
  year: 2018
  end-page: 1332
  article-title: Learned primal‐dual reconstruction
  publication-title: IEEE Trans Med Imaging
– volume: 79
  start-page: 3055
  year: 2018
  end-page: 3071
  article-title: Learning a variational network for reconstruction of accelerated MRI data
  publication-title: Magn Reson Med
– volume: 28
  start-page: 1219
  year: 2008
  end-page: 1225
  article-title: 128‐channel body MRI with a flexible high‐density receiver‐coil array
  publication-title: J Magn Reson Imaging
– volume: 71
  start-page: 990
  year: 2014
  end-page: 1001
  article-title: ESPIRiT: An eigenvalue approach to autocalibrating parallel MRI: Where SENSE meets GRAPPA
  publication-title: Magn Reson Med
– volume: 282
  start-page: 561
  year: 2017
  end-page: 568
  article-title: Increased speed and image quality for pelvic single‐shot fast spin‐echo imaging with variable refocusing flip angles and full‐Fourier acquisition
  publication-title: Radiology
– start-page: 9573
  year: 2018
  end-page: 9583
  article-title: Neural proximal gradient descent for compressive imaging
  publication-title: Adv Neural Inform Process Syst
– volume: 47
  start-page: 954
  year: 2018
  end-page: 966
  article-title: Self‐calibrating wave‐encoded variable‐density single‐shot fast spin echo imaging
  publication-title: J Magn Reson Imaging
– volume: 73
  start-page: 2152
  year: 2015
  end-page: 2162
  article-title: Wave‐CAIPI for highly accelerated 3D imaging
  publication-title: Magn Reson Med
– start-page: 2486
  year: 2015
– volume: 42
  start-page: 1747
  year: 2015
  end-page: 1758
  article-title: Increased speed and image quality in single‐shot fast spin echo imaging via variable refocusing flip angles
  publication-title: J Magn Reson Imaging
– volume: 78
  start-page: 1093
  year: 2017
  end-page: 1099
  article-title: Autocalibrated wave‐CAIPI reconstruction; Joint optimization of k‐space trajectory and parallel imaging reconstruction
  publication-title: Magn Reson Med
– start-page: 4649
  year: 2019
– volume: 58
  start-page: 1182
  year: 2007
  end-page: 1195
  article-title: Sparse MRI: The application of compressed sensing for rapid MR imaging
  publication-title: Magn Reson Med
– volume: 78
  start-page: 1757
  year: 2017
  end-page: 1766
  article-title: Auto‐calibrating motion‐corrected wave‐encoding for highly accelerated free‐breathing abdominal MRI
  publication-title: Magn Reson Med
– volume: 161
  start-page: 527
  year: 1986
  end-page: 531
  article-title: Halving MR imaging time by conjugation: Demonstration at 3.5 kG
  publication-title: Radiology
– volume: 73
  start-page: 929
  year: 2015
  end-page: 938
  article-title: RARE/turbo spin echo imaging with simultaneous multislice wave‐CAIPI
  publication-title: Magn Reson Med
– volume: 33
  start-page: 240
  year: 2015
  end-page: 245
  article-title: Accelerated model‐based proton resonance frequency shift temperature mapping using echo‐based GRAPPA reconstruction
  publication-title: Magn Reson Imaging
– volume: 289
  start-page: 366
  year: 2018
  end-page: 373
  article-title: Variable‐density single‐shot fast spin‐echo MRI with deep learning reconstruction by using variational networks
  publication-title: Radiology.
– volume: 81
  start-page: 1181
  year: 2019
  end-page: 1190
  article-title: Motion‐robust reconstruction of multishot diffusion‐weighted images without phase estimation through locally low‐rank regularization
  publication-title: Magn Reson Med
– volume: 17
  start-page: 45
  year: 1975
  end-page: 51
  article-title: The Nelder‐Mead simplex procedure for function minimization
  publication-title: Technometrics
– volume: 60
  start-page: 640
  year: 2008
  end-page: 649
  article-title: Effects of refocusing flip angle modulation and view ordering in 3D fast spin echo
  publication-title: Magn Reson Med
– volume: 73
  start-page: 1775
  year: 2015
  end-page: 1785
  article-title: Parallel imaging and compressed sensing combined framework for accelerating high‐resolution diffusion tensor imaging using inter‐image correlation
  publication-title: Magn Reson Med
– start-page: 1097
  year: 2012
  end-page: 1105
  article-title: Imagenet classification with deep convolutional neural networks
  publication-title: Adv Neural Inform Process Syst
– volume: 6
  start-page: 698
  year: 1996
  end-page: 699
  article-title: HASTE MR imaging: Description of technique and preliminary results in the abdomen
  publication-title: J Magn Reson Imaging
– volume: 39
  start-page: 745
  year: 2014
  end-page: 767
  article-title: Optimized three‐dimensional fast‐spin‐echo MRI
  publication-title: J Magn Reson Imaging
– start-page: 10
  year: 2017
  end-page: 18
  article-title: ADMM‐Net: A deep learning approach for compressive sensing MRI
  publication-title: NIPS
– ident: e_1_2_6_17_1
  doi: 10.1002/mrm.25290
– ident: e_1_2_6_32_1
  doi: 10.1002/mrm.27488
– ident: e_1_2_6_11_1
  doi: 10.1002/mrm.25615
– ident: e_1_2_6_2_1
  doi: 10.1002/jmri.1880060420
– ident: e_1_2_6_9_1
  doi: 10.1002/mrm.21680
– ident: e_1_2_6_18_1
– ident: e_1_2_6_31_1
  doi: 10.1016/j.mri.2014.10.006
– ident: e_1_2_6_23_1
  doi: 10.1148/radiol.2018180445
– ident: e_1_2_6_28_1
– ident: e_1_2_6_5_1
  doi: 10.1148/radiol.2016151574
– ident: e_1_2_6_22_1
  doi: 10.1002/mrm.26977
– ident: e_1_2_6_19_1
– ident: e_1_2_6_10_1
  doi: 10.1002/mrm.25347
– ident: e_1_2_6_7_1
  doi: 10.1002/jmri.25853
– ident: e_1_2_6_30_1
– ident: e_1_2_6_27_1
– ident: e_1_2_6_12_1
  doi: 10.1002/mrm.26567
– start-page: 10
  year: 2017
  ident: e_1_2_6_20_1
  article-title: ADMM‐Net: A deep learning approach for compressive sensing MRI
  publication-title: NIPS
– ident: e_1_2_6_8_1
  doi: 10.1002/jmri.21463
– ident: e_1_2_6_13_1
– ident: e_1_2_6_21_1
  doi: 10.1109/TMI.2018.2799231
– ident: e_1_2_6_6_1
  doi: 10.1002/jmri.24941
– ident: e_1_2_6_3_1
  doi: 10.1148/radiology.161.2.3763926
– start-page: 9573
  year: 2018
  ident: e_1_2_6_29_1
  article-title: Neural proximal gradient descent for compressive imaging
  publication-title: Adv Neural Inform Process Syst
– ident: e_1_2_6_4_1
  doi: 10.1002/jmri.24542
– ident: e_1_2_6_16_1
  doi: 10.1002/mrm.21391
– ident: e_1_2_6_14_1
  doi: 10.1002/mrm.26499
– start-page: 1097
  year: 2012
  ident: e_1_2_6_25_1
  article-title: Imagenet classification with deep convolutional neural networks
  publication-title: Adv Neural Inform Process Syst
– ident: e_1_2_6_24_1
  doi: 10.1080/00401706.1975.10489269
– ident: e_1_2_6_15_1
  doi: 10.1002/mrm.24751
– ident: e_1_2_6_26_1
  doi: 10.1007/978-3-319-24574-4_28
SSID ssj0009945
Score 2.4306417
Snippet Background Current self‐calibration and reconstruction methods for wave‐encoded single‐shot fast spin echo imaging (SSFSE) requires long computational time,...
Current self-calibration and reconstruction methods for wave-encoded single-shot fast spin echo imaging (SSFSE) requires long computational time, especially...
BackgroundCurrent self‐calibration and reconstruction methods for wave‐encoded single‐shot fast spin echo imaging (SSFSE) requires long computational time,...
SourceID unpaywall
pubmedcentral
proquest
pubmed
crossref
wiley
SourceType Open Access Repository
Aggregation Database
Index Database
Enrichment Source
Publisher
StartPage 841
SubjectTerms Abdomen
Acceleration
Adult
Aged
Artificial neural networks
Calibration
Cartesian coordinates
Coding
Computer applications
Computing time
Confidence
Data acquisition
data‐driven
Deep Learning
Female
Females
Field strength
Humans
Image Processing, Computer-Assisted
Image quality
Image reconstruction
Iterative methods
Magnetic Resonance Imaging
Male
Males
Middle Aged
Neural networks
Noise
Noise levels
parallel imaging and compressed sensing
Prospective Studies
Quality assessment
Quality control
Rank tests
Sharpness
Shot
single‐shot fast spin echo
Statistical analysis
Statistical tests
wave encoding
Young Adult
SummonAdditionalLinks – databaseName: Wiley Online Library - Core collection (SURFmarket)
  dbid: DR2
  link: http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1Lb9QwELaqHoAL5d1AQUb0AlK2iZ2HLXFBQFUqLYeKSr2gyGM77UKaXW2yVHDixpXfyC9h7GSzWooqwS2xJ3Fiz4y_cZxvCNmFBHIuBYapkZBhAhizqlSbEHTGubJgEp_rcPw-OzhODk_Skw3ycvkvTMcPMSy4Ocvw_toZuIJmb0Ua-ul8PhmxTPgfyGOe-XjqaMUdJaXPUIz4gYexiPKBm5TtrS5dn40uQczLOyWvL-qZ-nqhqmodzfrpaH-LfFy-SLcL5fNo0cJIf_uD4_F_3_QWudnjVPqqU6zbZMPWd8i1cf8l_i758Ua16tf3n2bu3CVtbFXiGQ64a8kNNlW1oT7cHihqKQJkWk9rLzhHjIuqSS_UF4sFjk_TWEPd0kXlCpqzaUtL1bS0mU1qatFNU7dJ_5Qaa2e0z3Zxeo8c77_98Pog7JM6hBojwTgEBEAmLwEk1-D44SA1ENlEIxbJWJkIGWOd5TwuI4iYBlaWaQZpVKInjjXw-2QTn9RuE4rhtbSlAz0gEpkJiffRAIILdMOJMQF5vhzcQveM5y7xRlV0XM2scD1b-J4NyLNBdtbxfPxVamepI0Vv603BPKOsROgdkKdDNVqp-_SiajtdoIxjassc1VBAHnQqNTTjyDNZLmVA8jVlGwQcA_h6TT0580zgCC-EiJOA7A5qeeXTv_BqdoVIcTg-euePHv6L8CNyg7l1CL83b4dsol7ZxwjWWnjijfI32FlEaw
  priority: 102
  providerName: Wiley-Blackwell
Title Data‐driven self‐calibration and reconstruction for non‐cartesian wave‐encoded single‐shot fast spin echo using deep learning
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fjmri.26871
https://www.ncbi.nlm.nih.gov/pubmed/31322799
https://www.proquest.com/docview/2352579080
https://www.proquest.com/docview/2261262283
https://pubmed.ncbi.nlm.nih.gov/PMC8018814
https://www.ncbi.nlm.nih.gov/pmc/articles/8018814
UnpaywallVersion submittedVersion
Volume 51
hasFullText 1
inHoldings 1
isFullTextHit
isPrint
journalDatabaseRights – providerCode: PRVWIB
  databaseName: Wiley Online Library - Core collection (SURFmarket)
  issn: 1522-2586
  databaseCode: DR2
  dateStart: 19990101
  customDbUrl:
  isFulltext: true
  eissn: 1522-2586
  dateEnd: 99991231
  omitProxy: false
  ssIdentifier: ssj0009945
  providerName: Wiley-Blackwell
link http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwlV1Lb9NAEF5VqQRcyrs1lGoRvYBkx16_1scKqEqlVCgiUjlZnt11G3AcK3ao4MSNK7-RX8Ls-iGFogpuiXfkbDTfzn7jHX9DyCEEEPsJxzTV5YkdAOasWSikDSLy_UyBDEyvw8lZdDILTs_D8y3i9e_CmKJ9AXOnLBZOOb80tZXVQoz7OrExhlTOdevq7ShE-j0i27Oz90cfzalm6Nte-4o0bkvMZiGPBklSNv60WM0dFvHY29yErjHL6wWSt9dllX29yopik8SaXej4Lpn282-LTz476wYc8e0Pacf_-oP3yE7HSelRO3SfbKnyAbk16U7dH5Ifb7Im-_X9p1zp0EhrVeT4DZ2rU23tWJqVkprUepCjpUiGabksjeEK-SzCkF5lXxRe0NqZUkmqH1MU-kJ9uWxontUNrat5SRWGZKoL8i-oVKqiXWeLi0dkdvz2w-sTu2vgYAvM-jwbkOzIOAdIfAFaCw5CCa4KBPKOiOUBTzwcU77v5S64TADL8zCC0M0x6noC_MdkhDNVe4RiKp2oXBMc4EES8QTvIwC4zzHkBlJa5GXv0VR06ua6yUaRtrrMLNXeT433LfJisK1aTY-_Wu33wEi7dV2nzKjHJkizLfJ8GMYVqY9ZslIt12ijVdkiLStkkd0WR8PPaKFMFieJReINhA0GWu17cwQxYlS_O1hY5HDA4o2zf2VgeoNJejqZvjOfnvzbPZ-SO0w_bTAVePtkhIhSz5CSNXCAyciUHXRL8TdcVj8_
linkProvider Unpaywall
linkToHtml http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1Lb9QwELZQkSgX3pRAASN6ASnbPJysfURAtS3dHqpW6i3yxE67ELKrTZYKTty48hv5Jcw4aVZLUSW4JfHkZc9MvnHG3zC2BQKGsZIYpgZS-QIwZtVJbnzI0zjWFoxwtQ7HB-noWOydJCddbg6thWn5IfoJN7IM56_JwGlCenvJGvrx83wyiFJJK8ivixQDFcJEh0v2KKVcjWJEELEfymDYs5NG28tzV79Hl0Dm5VzJ9UU101_PdVmu4ln3Qdq53VZdrR2PIeWhfBosGhjk3_5gefzvd73DbnVQlb9pdesuu2are-zGuPsZf5_9eKcb_ev7TzMnj8lrWxa4h2NOt6Lx5roy3EXcPUstR4zMq2nlBOcIc1E7-bn-YvEAUWoaazjNXpR0oD6bNrzQdcPr2aTiFj01pzz9U26snfGu4MXpA3a88_7o7cjv6jr4OQaDoQ-IgcywAFBxDkQRB4mBwIoc4UgaFUKqENtsHIdFAEGUQ1QUSQpJUKAzDnOIH7I1fFL7iHGMsJUtCPeAFCqVCq-TA8hYoicWxnjs1cXoZnlHek61N8qspWuOMurZzPWsx172srOW6uOvUpsXSpJ15l5nkSOVVYi-Pfaib0ZDpb8vurLTBcoQWVtKbEMe22h1qr8N8WdGQ6U8NlzRtl6ASMBXW6rJmSMDR4QhZSg8ttXr5ZVP_9rp2RUi2d74cNdtPf4X4edsfXQ03s_2dw8-PGE3I5qWcKl6m2wNdcw-RezWwDNnob8B5VdIjA
linkToPdf http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1Lb9QwELZQkQoX3pSUAkb0AlK2eThZ-4hYVm1hK1RRqbcofrULaTbaZKngxI0rv5FfwoyTZrUUVYJbEk9e9szkG2f8DSHbkslhLDiEqQEXPpMQs-aJ0r5UaRznRmrmah1ODtLdI7Z_nBx3uTm4Fqblh-gn3NAynL9GAzeVtjtL1tBPZ_PpIEo5riC_zhLBMaNvdLhkjxLC1SgGBBH7IQ-GPTtptLM8d_V7dAlkXs6VvLEoq_zreV4Uq3jWfZDGt9uqq7XjMcQ8lM-DRSMH6tsfLI___a53yK0OqtLXrW7dJddMeY-sT7qf8ffJj1He5L--_9Rz9Ji0NoWFPRhzvBWON81LTV3E3bPUUsDItJyVTnAOMBe0k57nXwwcQEpNbTTF2YsCD9Sns4bavG5oXU1LasBTU8zTP6HamIp2BS9OHpCj8duPb3b9rq6DryAYDH0JGEgPrZQiVhIp4mSiZWCYAjiSRpZxEUKbiePQBjKIlIysTVKZBBaccahk_JCswZOaR4RChC2MRdwjORMpF3AdJSWPOXhiprVHXl6MbqY60nOsvVFkLV1zlGHPZq5nPfKil61aqo-_Sm1dKEnWmXudRY5UVgD69sjzvhkMFf--5KWZLUAGydpSZBvyyEarU_1tkD8zGgrhkeGKtvUCSAK-2lJOTx0ZOCAMzkPmke1eL698-ldOz64QyfYnh3tua_NfhJ-R9Q-jcfZ-7-DdY3IzwlkJl6m3RdZAxcwTgG6NfOoM9DcwAUgQ
linkToUnpaywall http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwlV1Lb9QwELaqrQRcyhtSCjKiF5Cymzgv51gBVam0FapYqZwij-20C9lstMlSwYkbV34jv4Sx85CWogpuu_Eo69V8Hn8TT74hZB9CSIKUY5rq8dQNAXNWEUnlgoyDQGhQoe11OD2Jj2bh8Vl0tkX8_l0YW7QvYT4ui8W4nF_Y2spqISd9ndgEQyrnpnX1dhwh_R6R7dnJ-4OP9lQzCly_fUUatyXmsojHgyQpm3xarOZjFvPE39yErjDLqwWSN9dlJb5eiqLYJLF2Fzq8TU77-bfFJ5_H6wbG8tsf0o7_9QfvkJ2Ok9KDdugu2dLlPXJj2p263yc_3ohG_Pr-U61MaKS1LnL8hs41qbZxLBWloja1HuRoKZJhWi5La7hCPoswpJfii8YLRjtTaUXNY4rCXKgvlg3NRd3QupqXVGNIpqYg_5wqrSvadbY4f0Bmh28_vD5yuwYOrsSsz3cByY5KcoA0kGC04CBS4OlQIu-IWR7y1McxHQR-7oHHJLA8j2KIvByjri8heEhGOFP9mFBMpVOdG4IDPExjnuJ9JAAPOIbcUCmHvOw9mslO3dw02SiyVpeZZcb7mfW-Q14MtlWr6fFXq70eGFm3ruuMWfXYFGm2Q54Pw7gizTGLKPVyjTZGlS02skIOedTiaPgZI5TJkjR1SLKBsMHAqH1vjiBGrOp3BwuH7A9YvHb2ryxMrzHJjqen7-yn3X-75xNyi5mnDbYCb4-MEFH6KVKyBp51i_A35qo-Vg
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=Data-driven+self-calibration+and+reconstruction+for+non-cartesian+wave-encoded+single-shot+fast+spin+echo+using+deep+learning&rft.jtitle=Journal+of+magnetic+resonance+imaging&rft.au=Chen%2C+Feiyu&rft.au=Cheng%2C+Joseph+Y&rft.au=Taviani%2C+Valentina&rft.au=Sheth%2C+Vipul+R&rft.date=2020-03-01&rft.issn=1522-2586&rft.eissn=1522-2586&rft.volume=51&rft.issue=3&rft.spage=841&rft_id=info:doi/10.1002%2Fjmri.26871&rft.externalDBID=NO_FULL_TEXT
thumbnail_l http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=1053-1807&client=summon
thumbnail_m http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=1053-1807&client=summon
thumbnail_s http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=1053-1807&client=summon