CT Cervical Spine Fracture Detection Using a Convolutional Neural Network

J.E. Small; P. Osler; A.B. Paul; M. Kunst

doi:10.3174/ajnr.A7094

References

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1. Adams M,
2. Chen W,
3. Holcdorf D, et al
. Computer vs human: Deep learning versus perceptual training for the detection of neck of femur fractures. J Med Imaging Radiat Oncol 2019;63:27–32 doi:10.1111/1754-9485.12828 pmid:30407743
CrossRef PubMed
2.
1. Urakawa T,
2. Tanaka Y,
3. Goto S, et al
. Detecting intertrochanteric hip fractures with orthopedist-level accuracy using a deep convolutional neural network. Skeletal Radiol 2019;48:239–44 doi:10.1007/s00256-018-3016-3 pmid:29955910
CrossRef PubMed
3.↵
1. Cheng CT,
2. Ho TY,
3. Lee TY, et al
. Application of a deep learning algorithm for detection and visualization of hip fractures on plain pelvic radiographs. Eur Radiol 2019;29:5469–77 doi:10.1007/s00330-019-06167-y pmid:30937588
CrossRef PubMed
4.↵
1. Chung SW,
2. Han SS,
3. Lee JW, et al
. Automated detection and classification of the proximal humerus fracture by using deep learning algorithm. Acta Orthop 2018;89:468–73 doi:10.1080/17453674.2018.1453714 pmid:29577791
CrossRef PubMed
5.↵
1. Gan K,
2. Xu D,
3. Lin Y, et al
. Artificial intelligence detection of distal radius fractures: a comparison between the convolutional neural network and professional assessments. Acta Orthop 2019;90:394–400 doi:10.1080/17453674.2019.1600125 pmid:30942136
CrossRef PubMed
6.↵
1. Kim DH,
2. MacKinnon T
. Artificial intelligence in fracture detection: transfer learning from deep convolutional neural networks. Clin Radiol 2018;73:439–45 doi:10.1016/j.crad.2017.11.015 pmid:29269036
CrossRef PubMed
7.↵
1. Lindsey R,
2. Daluiski A,
3. Chopra S, et al
. Deep neural network improves fracture detection by clinicians. Proc Natl Acad Sci U S A 2018;115:11591–96 doi:10.1073/pnas.1806905115 pmid:30348771
Abstract/FREE Full Text
8.↵
1. Olczak J,
2. Fahlberg N,
3. Maki A, et al
. Artificial intelligence for analyzing orthopedic trauma radiographs. Acta Orthop 2017;88:581–86 doi:10.1080/17453674.2017.1344459 pmid:28681679
CrossRef PubMed
9.↵
1. Derkatch S,
2. Kirby C,
3. Kimelman D, et al
. Identification of vertebral fractures by convolutional neural networks to predict nonvertebral and hip fractures: a registry-based cohort study of dual x-ray absorptiometry. Radiology 2019;293:405–11 doi:10.1148/radiol.2019190201 pmid:31526255
CrossRef PubMed
10.↵
1. Pranata YD,
2. Wang KC,
3. Wang JC, et al
. Deep learning and SURF for automated classification and detection of calcaneus fractures in CT images. Comput Methods Programs Biomed 2019;171:27–37 doi:10.1016/j.cmpb.2019.02.006 pmid:30902248
CrossRef PubMed
11.↵
1. Burns JE,
2. Yao J,
3. Summers RM
. Vertebral body compression fractures and bone density: automated detection and classification on CT images. Radiology 2017;284:788–97 doi:10.1148/radiol.2017162100 pmid:28301777
CrossRef PubMed
12.↵
1. Tomita N,
2. Cheung YY,
3. Hassanpour S
. Deep neural networks for automatic detection of osteoporotic vertebral fractures on CT scans. Comput Biol Med 2018;98:8–15 doi:10.1016/j.compbiomed.2018.05.011 pmid:29758455
CrossRef PubMed
13.↵
1. Muehlematter UJ,
2. Mannil M,
3. Becker AS, et al
. Vertebral body insufficiency fractures: detection of vertebrae at risk on standard CT images using texture analysis and machine learning. Eur Radiol 2019;29:2207–17 doi:10.1007/s00330-018-5846-8 pmid:30519934
CrossRef PubMed
14.↵
1. Milby AH,
2. Halpern CH,
3. Guo W, et al
. Prevalence of cervical spinal injury in trauma. Neurosurg Focus 2008;25:E10 doi:10.3171/FOC.2008.25.11.E10 pmid:18980470
CrossRef PubMed
15.↵
1. Minja FJ,
2. Mehta KY,
3. Mian AY
. Current challenges in the use of computed tomography and MR imaging in suspected cervical spine trauma. Neuroimaging Clin N Am 2018;28:483–93 doi:10.1016/j.nic.2018.03.009 pmid:30007757
CrossRef PubMed
16.↵
1. Inaba K,
2. Byerly S,
3. Bush LD, et al
. Cervical spinal clearance: a prospective Western Trauma Association multi-institutional trial. J Trauma Acute Care Surg 2016;81:1122–30 doi:10.1097/TA.0000000000001194 pmid:27438681
CrossRef PubMed
17.↵
1. Poonnoose PM,
2. Ravichandran G,
3. McClelland MR
. Missed and mismanaged injuries of the spinal cord. J Trauma 2002;53:314–20 doi:10.1097/00005373-200208000-00021 pmid:12169940
CrossRef PubMed Web of Science
18.↵
1. Izzo R,
2. Popolizio T,
3. Balzano RF, et al
. Imaging of cervical spine traumas. Eur J Radiol 2019;117:75–88 doi:10.1016/j.ejrad.2019.05.007 pmid:31307656
CrossRef PubMed
19.↵
1. Khanpara S,
2. Ruiz-Pardo D,
3. Spence SC, et al
. Incidence of cervical spine fractures on CT: a study in a large level I trauma center. Emerg Radiol 2020;27:1–8 doi:10.1007/s10140-019-01717-9 pmid:31463806
CrossRef PubMed
20.↵
1. Alessandrino F,
2. Bono CM,
3. Potter CA, et al
. Spectrum of diagnostic errors in cervical spine trauma imaging and their clinical significance. Emerg Radiol 2019;26:409–16 doi:10.1007/s10140-019-01685-0 pmid:30929146
CrossRef PubMed
21.↵
1. Bernstein MP,
2. Young MG,
3. Baxter AB
. Imaging of spine trauma. Radiol Clin North Am 2019;57:767–85 doi:10.1016/j.rcl.2019.02.007 pmid:31076031
CrossRef PubMed

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More in this TOC Section

Show more Spine

[1] 1.↵
Adams M,
Chen W,
Holcdorf D, et al
. Computer vs human: Deep learning versus perceptual training for the detection of neck of femur fractures. J Med Imaging Radiat Oncol 2019;63:27–32 doi:10.1111/1754-9485.12828 pmid:30407743
CrossRef PubMed

[2] Adams M,

[3] Chen W,

[4] Holcdorf D, et al

[5] 2.
Urakawa T,
Tanaka Y,
Goto S, et al
. Detecting intertrochanteric hip fractures with orthopedist-level accuracy using a deep convolutional neural network. Skeletal Radiol 2019;48:239–44 doi:10.1007/s00256-018-3016-3 pmid:29955910
CrossRef PubMed

[6] Urakawa T,

[7] Tanaka Y,

[8] Goto S, et al

[9] 3.↵
Cheng CT,
Ho TY,
Lee TY, et al
. Application of a deep learning algorithm for detection and visualization of hip fractures on plain pelvic radiographs. Eur Radiol 2019;29:5469–77 doi:10.1007/s00330-019-06167-y pmid:30937588
CrossRef PubMed

[10] Cheng CT,

[11] Ho TY,

[12] Lee TY, et al

[13] 4.↵
Chung SW,
Han SS,
Lee JW, et al
. Automated detection and classification of the proximal humerus fracture by using deep learning algorithm. Acta Orthop 2018;89:468–73 doi:10.1080/17453674.2018.1453714 pmid:29577791
CrossRef PubMed

[14] Chung SW,

[15] Han SS,

[16] Lee JW, et al

[17] 5.↵
Gan K,
Xu D,
Lin Y, et al
. Artificial intelligence detection of distal radius fractures: a comparison between the convolutional neural network and professional assessments. Acta Orthop 2019;90:394–400 doi:10.1080/17453674.2019.1600125 pmid:30942136
CrossRef PubMed

[18] Gan K,

[19] Xu D,

[20] Lin Y, et al

[21] 6.↵
Kim DH,
MacKinnon T
. Artificial intelligence in fracture detection: transfer learning from deep convolutional neural networks. Clin Radiol 2018;73:439–45 doi:10.1016/j.crad.2017.11.015 pmid:29269036
CrossRef PubMed

[22] Kim DH,

[23] MacKinnon T

[24] 7.↵
Lindsey R,
Daluiski A,
Chopra S, et al
. Deep neural network improves fracture detection by clinicians. Proc Natl Acad Sci U S A 2018;115:11591–96 doi:10.1073/pnas.1806905115 pmid:30348771
Abstract/FREE Full Text

[25] Lindsey R,

[26] Daluiski A,

[27] Chopra S, et al

[28] 8.↵
Olczak J,
Fahlberg N,
Maki A, et al
. Artificial intelligence for analyzing orthopedic trauma radiographs. Acta Orthop 2017;88:581–86 doi:10.1080/17453674.2017.1344459 pmid:28681679
CrossRef PubMed

[29] Olczak J,

[30] Fahlberg N,

[31] Maki A, et al

[32] 9.↵
Derkatch S,
Kirby C,
Kimelman D, et al
. Identification of vertebral fractures by convolutional neural networks to predict nonvertebral and hip fractures: a registry-based cohort study of dual x-ray absorptiometry. Radiology 2019;293:405–11 doi:10.1148/radiol.2019190201 pmid:31526255
CrossRef PubMed

[33] Derkatch S,

[34] Kirby C,

[35] Kimelman D, et al

[36] 10.↵
Pranata YD,
Wang KC,
Wang JC, et al
. Deep learning and SURF for automated classification and detection of calcaneus fractures in CT images. Comput Methods Programs Biomed 2019;171:27–37 doi:10.1016/j.cmpb.2019.02.006 pmid:30902248
CrossRef PubMed

[37] Pranata YD,

[38] Wang KC,

[39] Wang JC, et al

[40] 11.↵
Burns JE,
Yao J,
Summers RM
. Vertebral body compression fractures and bone density: automated detection and classification on CT images. Radiology 2017;284:788–97 doi:10.1148/radiol.2017162100 pmid:28301777
CrossRef PubMed

[41] Burns JE,

[42] Yao J,

[43] Summers RM

[44] 12.↵
Tomita N,
Cheung YY,
Hassanpour S
. Deep neural networks for automatic detection of osteoporotic vertebral fractures on CT scans. Comput Biol Med 2018;98:8–15 doi:10.1016/j.compbiomed.2018.05.011 pmid:29758455
CrossRef PubMed

[45] Tomita N,

[46] Cheung YY,

[47] Hassanpour S

[48] 13.↵
Muehlematter UJ,
Mannil M,
Becker AS, et al
. Vertebral body insufficiency fractures: detection of vertebrae at risk on standard CT images using texture analysis and machine learning. Eur Radiol 2019;29:2207–17 doi:10.1007/s00330-018-5846-8 pmid:30519934
CrossRef PubMed

[49] Muehlematter UJ,

[50] Mannil M,

[51] Becker AS, et al

[52] 14.↵
Milby AH,
Halpern CH,
Guo W, et al
. Prevalence of cervical spinal injury in trauma. Neurosurg Focus 2008;25:E10 doi:10.3171/FOC.2008.25.11.E10 pmid:18980470
CrossRef PubMed

[53] Milby AH,

[54] Halpern CH,

[55] Guo W, et al

[56] 15.↵
Minja FJ,
Mehta KY,
Mian AY
. Current challenges in the use of computed tomography and MR imaging in suspected cervical spine trauma. Neuroimaging Clin N Am 2018;28:483–93 doi:10.1016/j.nic.2018.03.009 pmid:30007757
CrossRef PubMed

[57] Minja FJ,

[58] Mehta KY,

[59] Mian AY

[60] 16.↵
Inaba K,
Byerly S,
Bush LD, et al
. Cervical spinal clearance: a prospective Western Trauma Association multi-institutional trial. J Trauma Acute Care Surg 2016;81:1122–30 doi:10.1097/TA.0000000000001194 pmid:27438681
CrossRef PubMed

[61] Inaba K,

[62] Byerly S,

[63] Bush LD, et al

[64] 17.↵
Poonnoose PM,
Ravichandran G,
McClelland MR
. Missed and mismanaged injuries of the spinal cord. J Trauma 2002;53:314–20 doi:10.1097/00005373-200208000-00021 pmid:12169940
CrossRef PubMed Web of Science

[65] Poonnoose PM,

[66] Ravichandran G,

[67] McClelland MR

[68] 18.↵
Izzo R,
Popolizio T,
Balzano RF, et al
. Imaging of cervical spine traumas. Eur J Radiol 2019;117:75–88 doi:10.1016/j.ejrad.2019.05.007 pmid:31307656
CrossRef PubMed

[69] Izzo R,

[70] Popolizio T,

[71] Balzano RF, et al

[72] 19.↵
Khanpara S,
Ruiz-Pardo D,
Spence SC, et al
. Incidence of cervical spine fractures on CT: a study in a large level I trauma center. Emerg Radiol 2020;27:1–8 doi:10.1007/s10140-019-01717-9 pmid:31463806
CrossRef PubMed

[73] Khanpara S,

[74] Ruiz-Pardo D,

[75] Spence SC, et al

[76] 20.↵
Alessandrino F,
Bono CM,
Potter CA, et al
. Spectrum of diagnostic errors in cervical spine trauma imaging and their clinical significance. Emerg Radiol 2019;26:409–16 doi:10.1007/s10140-019-01685-0 pmid:30929146
CrossRef PubMed

[77] Alessandrino F,

[78] Bono CM,

[79] Potter CA, et al

[80] 21.↵
Bernstein MP,
Young MG,
Baxter AB
. Imaging of spine trauma. Radiol Clin North Am 2019;57:767–85 doi:10.1016/j.rcl.2019.02.007 pmid:31076031
CrossRef PubMed

[81] Bernstein MP,

[82] Young MG,

[83] Baxter AB

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