Applying machine learning classifiers to automate quality assessment of paediatric dynamic susceptibility contrast (DSC-) MRI data

Stephen J Powell; Stephanie B Withey; Yu Sun; James T Grist; Jan Novak; Lesley Macpherson; Laurence Abernethy; Barry Pizer; Richard Grundy; Paul S Morgan; Tim Jaspan; Simon Bailey; Dipayan Mitra; Dorothee P Auer; Shivaram Avula; Theodoros N Arvanitis; Andrew Peet

doi:10.1259/bjr.20201465

Applying machine learning classifiers to automate quality assessment of paediatric dynamic susceptibility contrast (DSC-) MRI data

Stephen J Powell, Stephanie B Withey, Yu Sun, James T Grist, Jan Novak, Lesley Macpherson, Laurence Abernethy, Barry Pizer, Richard Grundy, Paul S Morgan, Tim Jaspan, Simon Bailey, Dipayan Mitra, Dorothee P Auer, Shivaram Avula, Theodoros N Arvanitis, Andrew Peet^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

OBJECTIVE: Investigate the performance of qualitative review (QR) for assessing dynamic susceptibility contrast (DSC-) MRI data quality in paediatric normal brain and develop an automated alternative to QR.

METHODS: 1027 signal-time courses were assessed by Reviewer 1 using QR. 243 were additionally assessed by Reviewer 2 and % disagreements and Cohen's κ (κ) were calculated. The signal drop-to-noise ratio (SDNR), root mean square error (RMSE), full width half maximum (FWHM) and percentage signal recovery (PSR) were calculated for the 1027 signal-time courses. Data quality thresholds for each measure were determined using QR results. The measures and QR results trained machine learning classifiers. Sensitivity, specificity, precision, classification error and area under the curve from a receiver operating characteristic curve were calculated for each threshold and classifier.

RESULTS: Comparing reviewers gave 7% disagreements and κ = 0.83. Data quality thresholds of: 7.6 for SDNR; 0.019 for RMSE; 3 s and 19 s for FWHM; and 42.9 and 130.4% for PSR were produced. SDNR gave the best sensitivity, specificity, precision, classification error and area under the curve values of 0.86, 0.86, 0.93, 14.2% and 0.83. Random forest was the best machine learning classifier, giving sensitivity, specificity, precision, classification error and area under the curve of 0.94, 0.83, 0.93, 9.3% and 0.89.

CONCLUSION: The reviewers showed good agreement. Machine learning classifiers trained on signal-time course measures and QR can assess quality. Combining multiple measures reduces misclassification.

ADVANCES IN KNOWLEDGE: A new automated quality control method was developed, which trained machine learning classifiers using QR results.

Original language	English
Article number	20201465
Journal	British Journal of Radiology
Volume	96
Issue number	1145
Early online date	20 Feb 2023
DOIs	https://doi.org/10.1259/bjr.20201465
Publication status	Published - 1 Apr 2023

Keywords

Humans
Child
Sensitivity and Specificity
Machine Learning
ROC Curve
Magnetic Resonance Imaging

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VERITAS: An international multicentre phase II randomised trial evaluating and comparing two intensification treatment strategies for metastatic neuroblastoma patients with a poor response to induction chemotherapy
Kearns, P.
Cancer Research Uk
1/06/18 → 30/11/27
Project: Research
Improving the diagnosis of children's brain tumours by functional radiomics
Peet, A.
CHILDREN'S CANCER AND LEUKAEMIA GROUP
1/10/17 → 31/12/20
Project: Research
NIHR Professorship - Supporting Research into New Imaging Methods for Children
Peet, A.
NIHR TRAINEES COORDINATING CENTRE
1/01/13 → 31/03/18
Project: Other Government Departments

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Powell, S. J., Withey, S. B., Sun, Y., Grist, J. T., Novak, J., Macpherson, L., Abernethy, L., Pizer, B., Grundy, R., Morgan, P. S., Jaspan, T., Bailey, S., Mitra, D., Auer, D. P., Avula, S., Arvanitis, T. N., & Peet, A. (2023). Applying machine learning classifiers to automate quality assessment of paediatric dynamic susceptibility contrast (DSC-) MRI data. British Journal of Radiology, 96(1145), Article 20201465. https://doi.org/10.1259/bjr.20201465

@article{c7c20322e44349db824c6f50328d0426,

title = "Applying machine learning classifiers to automate quality assessment of paediatric dynamic susceptibility contrast (DSC-) MRI data",

abstract = "OBJECTIVE: Investigate the performance of qualitative review (QR) for assessing dynamic susceptibility contrast (DSC-) MRI data quality in paediatric normal brain and develop an automated alternative to QR.METHODS: 1027 signal-time courses were assessed by Reviewer 1 using QR. 243 were additionally assessed by Reviewer 2 and % disagreements and Cohen's κ (κ) were calculated. The signal drop-to-noise ratio (SDNR), root mean square error (RMSE), full width half maximum (FWHM) and percentage signal recovery (PSR) were calculated for the 1027 signal-time courses. Data quality thresholds for each measure were determined using QR results. The measures and QR results trained machine learning classifiers. Sensitivity, specificity, precision, classification error and area under the curve from a receiver operating characteristic curve were calculated for each threshold and classifier.RESULTS: Comparing reviewers gave 7% disagreements and κ = 0.83. Data quality thresholds of: 7.6 for SDNR; 0.019 for RMSE; 3 s and 19 s for FWHM; and 42.9 and 130.4% for PSR were produced. SDNR gave the best sensitivity, specificity, precision, classification error and area under the curve values of 0.86, 0.86, 0.93, 14.2% and 0.83. Random forest was the best machine learning classifier, giving sensitivity, specificity, precision, classification error and area under the curve of 0.94, 0.83, 0.93, 9.3% and 0.89.CONCLUSION: The reviewers showed good agreement. Machine learning classifiers trained on signal-time course measures and QR can assess quality. Combining multiple measures reduces misclassification.ADVANCES IN KNOWLEDGE: A new automated quality control method was developed, which trained machine learning classifiers using QR results.",

keywords = "Humans, Child, Sensitivity and Specificity, Machine Learning, ROC Curve, Magnetic Resonance Imaging",

author = "Powell, {Stephen J} and Withey, {Stephanie B} and Yu Sun and Grist, {James T} and Jan Novak and Lesley Macpherson and Laurence Abernethy and Barry Pizer and Richard Grundy and Morgan, {Paul S} and Tim Jaspan and Simon Bailey and Dipayan Mitra and Auer, {Dorothee P} and Shivaram Avula and Arvanitis, {Theodoros N} and Andrew Peet",

year = "2023",

month = apr,

day = "1",

doi = "10.1259/bjr.20201465",

language = "English",

volume = "96",

journal = "British Journal of Radiology",

issn = "0007-1285",

publisher = "British Institute of Radiology",

number = "1145",

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Powell, SJ, Withey, SB, Sun, Y, Grist, JT, Novak, J, Macpherson, L, Abernethy, L, Pizer, B, Grundy, R, Morgan, PS, Jaspan, T, Bailey, S, Mitra, D, Auer, DP, Avula, S, Arvanitis, TN & Peet, A 2023, 'Applying machine learning classifiers to automate quality assessment of paediatric dynamic susceptibility contrast (DSC-) MRI data', British Journal of Radiology, vol. 96, no. 1145, 20201465. https://doi.org/10.1259/bjr.20201465

TY - JOUR

T1 - Applying machine learning classifiers to automate quality assessment of paediatric dynamic susceptibility contrast (DSC-) MRI data

AU - Powell, Stephen J

AU - Withey, Stephanie B

AU - Sun, Yu

AU - Grist, James T

AU - Novak, Jan

AU - Macpherson, Lesley

AU - Abernethy, Laurence

AU - Pizer, Barry

AU - Grundy, Richard

AU - Morgan, Paul S

AU - Jaspan, Tim

AU - Bailey, Simon

AU - Mitra, Dipayan

AU - Auer, Dorothee P

AU - Avula, Shivaram

AU - Arvanitis, Theodoros N

AU - Peet, Andrew

PY - 2023/4/1

Y1 - 2023/4/1

N2 - OBJECTIVE: Investigate the performance of qualitative review (QR) for assessing dynamic susceptibility contrast (DSC-) MRI data quality in paediatric normal brain and develop an automated alternative to QR.METHODS: 1027 signal-time courses were assessed by Reviewer 1 using QR. 243 were additionally assessed by Reviewer 2 and % disagreements and Cohen's κ (κ) were calculated. The signal drop-to-noise ratio (SDNR), root mean square error (RMSE), full width half maximum (FWHM) and percentage signal recovery (PSR) were calculated for the 1027 signal-time courses. Data quality thresholds for each measure were determined using QR results. The measures and QR results trained machine learning classifiers. Sensitivity, specificity, precision, classification error and area under the curve from a receiver operating characteristic curve were calculated for each threshold and classifier.RESULTS: Comparing reviewers gave 7% disagreements and κ = 0.83. Data quality thresholds of: 7.6 for SDNR; 0.019 for RMSE; 3 s and 19 s for FWHM; and 42.9 and 130.4% for PSR were produced. SDNR gave the best sensitivity, specificity, precision, classification error and area under the curve values of 0.86, 0.86, 0.93, 14.2% and 0.83. Random forest was the best machine learning classifier, giving sensitivity, specificity, precision, classification error and area under the curve of 0.94, 0.83, 0.93, 9.3% and 0.89.CONCLUSION: The reviewers showed good agreement. Machine learning classifiers trained on signal-time course measures and QR can assess quality. Combining multiple measures reduces misclassification.ADVANCES IN KNOWLEDGE: A new automated quality control method was developed, which trained machine learning classifiers using QR results.

AB - OBJECTIVE: Investigate the performance of qualitative review (QR) for assessing dynamic susceptibility contrast (DSC-) MRI data quality in paediatric normal brain and develop an automated alternative to QR.METHODS: 1027 signal-time courses were assessed by Reviewer 1 using QR. 243 were additionally assessed by Reviewer 2 and % disagreements and Cohen's κ (κ) were calculated. The signal drop-to-noise ratio (SDNR), root mean square error (RMSE), full width half maximum (FWHM) and percentage signal recovery (PSR) were calculated for the 1027 signal-time courses. Data quality thresholds for each measure were determined using QR results. The measures and QR results trained machine learning classifiers. Sensitivity, specificity, precision, classification error and area under the curve from a receiver operating characteristic curve were calculated for each threshold and classifier.RESULTS: Comparing reviewers gave 7% disagreements and κ = 0.83. Data quality thresholds of: 7.6 for SDNR; 0.019 for RMSE; 3 s and 19 s for FWHM; and 42.9 and 130.4% for PSR were produced. SDNR gave the best sensitivity, specificity, precision, classification error and area under the curve values of 0.86, 0.86, 0.93, 14.2% and 0.83. Random forest was the best machine learning classifier, giving sensitivity, specificity, precision, classification error and area under the curve of 0.94, 0.83, 0.93, 9.3% and 0.89.CONCLUSION: The reviewers showed good agreement. Machine learning classifiers trained on signal-time course measures and QR can assess quality. Combining multiple measures reduces misclassification.ADVANCES IN KNOWLEDGE: A new automated quality control method was developed, which trained machine learning classifiers using QR results.

KW - Humans

KW - Child

KW - Sensitivity and Specificity

KW - Machine Learning

KW - ROC Curve

KW - Magnetic Resonance Imaging

U2 - 10.1259/bjr.20201465

DO - 10.1259/bjr.20201465

M3 - Article

C2 - 36802769

SN - 0007-1285

VL - 96

JO - British Journal of Radiology

JF - British Journal of Radiology

IS - 1145

M1 - 20201465

ER -

Applying machine learning classifiers to automate quality assessment of paediatric dynamic susceptibility contrast (DSC-) MRI data

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Keywords

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Projects

VERITAS: An international multicentre phase II randomised trial evaluating and comparing two intensification treatment strategies for metastatic neuroblastoma patients with a poor response to induction chemotherapy

Improving the diagnosis of children's brain tumours by functional radiomics

NIHR Professorship - Supporting Research into New Imaging Methods for Children

Cite this