Automated quality control of small animal MR neuroimaging data

Aref Kalantari; Mehrab Shahbazi; Marc Schneider; Adam C. Raikes; Victor Vera Frazão; Avnish Bhattrai; Lorenzo Carnevale; Yujian Diao; Bart A.A. Franx; Francesco Gammaraccio; Lisa Marie Goncalves; Susan Lee; Esther M. van Leeuwen; Annika Michalek; Susanne Mueller; Alejandro Rivera Olvera; Daniel Padro; Mohamed Kotb Selim; Annette van der Toorn; Federico Varriano; Roël Vrooman; Patricia Wenk; H. Elliott Albers; Philipp Boehm-Sturm; Eike Budinger; Santiago Canals; Silvia De Santis; Roberta Diaz Brinton; Rick M. Dijkhuizen; Elisenda Eixarch; Gianluigi Forloni; Joanes Grandjean; Khan Hekmatyar; Russell E. Jacobs; Ileana Jelescu; Nyoman D. Kurniawan; Giuseppe Lembo; Dario Livio Longo; Naomi S.Sta Maria; Edoardo Micotti; Emma Muñoz-Moreno; Pedro Ramos-Cabrer; Wilfried Reichardt; Guadalupe Soria; Giovanna D. Ielacqua; Markus Aswendt

doi:10.1162/imag_a_00317

Automated quality control of small animal MR neuroimaging data

Aref Kalantari, Mehrab Shahbazi, Marc Schneider, Adam C. Raikes, Victor Vera Frazão, Avnish Bhattrai, Lorenzo Carnevale, Yujian Diao, Bart A.A. Franx, Francesco Gammaraccio, Lisa Marie Goncalves, Susan Lee, Esther M. van Leeuwen, Annika Michalek, Susanne Mueller, Alejandro Rivera Olvera, Daniel Padro, Mohamed Kotb Selim, Annette van der Toorn, Federico VarrianoRoël Vrooman, Patricia Wenk, H. Elliott Albers, Philipp Boehm-Sturm, Eike Budinger, Santiago Canals, Silvia De Santis, Roberta Diaz Brinton, Rick M. Dijkhuizen, Elisenda Eixarch, Gianluigi Forloni, Joanes Grandjean, Khan Hekmatyar, Russell E. Jacobs, Ileana Jelescu, Nyoman D. Kurniawan, Giuseppe Lembo, Dario Livio Longo, Naomi S.Sta Maria, Edoardo Micotti, Emma Muñoz-Moreno, Pedro Ramos-Cabrer, Wilfried Reichardt, Guadalupe Soria, Giovanna D. Ielacqua, Markus Aswendt^*

^*Corresponding author for this work

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

Abstract

Magnetic resonance imaging (MRI) is a valuable tool for studying brain structure and function in animal and clinical studies. With the growth of public MRI repositories, access to data has finally become easier. However, filtering large datasets for potential poor-quality outliers can be a challenge. We present AIDAqc, a machine-learning-assisted automated Python-based command-line tool for small animal MRI quality assessment. Quality control features include signal-to-noise ratio (SNR), temporal SNR, and motion. All features are automatically calculated and no regions of interest are needed. Automated outlier detection for a given dataset combines the interquartile range and the machine-learning methods one-class support vector machine, isolation forest, local outlier factor, and elliptic envelope. To evaluate the reliability of individual quality control metrics, a simulation of noise (Gaussian, salt and pepper, speckle) and motion was performed. In outlier detection, single scans with induced artifacts were successfully identified by AIDAqc. AIDAqc was challenged in a large heterogeneous dataset collected from 19 international laboratories, including data from mice, rats, rabbits, hamsters, and gerbils, obtained with different hardware and at different field strengths. The results show that the manual inter-rater agreement (mean Fleiss Kappa score 0.17) is low when identifying poor-quality data. A direct comparison of AIDAqc results, therefore, showed only low-to-moderate concordance. In a manual post hoc validation of AIDAqc output, precision was high (>70%). The outlier data can have a significant impact on further postprocessing, as shown in representative functional and structural connectivity analysis. In summary, this pipeline optimized for small animal MRI provides researchers with a valuable tool to efficiently and effectively assess the quality of their MRI data, which is essential for improved reliability and reproducibility.

Original language	English
Number of pages	23
Journal	Imaging Neuroscience
Volume	2
DOIs	https://doi.org/10.1162/imag_a_00317
Publication status	Published - 17 Oct 2024

Keywords

image artifacts
machine learning
majority voting
motion detection
reproducibility
standardization

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imag_a_00317Final published version, 7.93 MBLicence: CC BY

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Kalantari, A., Shahbazi, M., Schneider, M., Raikes, A. C., Frazão, V. V., Bhattrai, A., Carnevale, L., Diao, Y., Franx, B. A. A., Gammaraccio, F., Goncalves, L. M., Lee, S., van Leeuwen, E. M., Michalek, A., Mueller, S., Olvera, A. R., Padro, D., Selim, M. K., van der Toorn, A., ... Aswendt, M. (2024). Automated quality control of small animal MR neuroimaging data. Imaging Neuroscience, 2. https://doi.org/10.1162/imag_a_00317

@article{abf4df758b934985938210205fb10683,

title = "Automated quality control of small animal MR neuroimaging data",

abstract = "Magnetic resonance imaging (MRI) is a valuable tool for studying brain structure and function in animal and clinical studies. With the growth of public MRI repositories, access to data has finally become easier. However, filtering large datasets for potential poor-quality outliers can be a challenge. We present AIDAqc, a machine-learning-assisted automated Python-based command-line tool for small animal MRI quality assessment. Quality control features include signal-to-noise ratio (SNR), temporal SNR, and motion. All features are automatically calculated and no regions of interest are needed. Automated outlier detection for a given dataset combines the interquartile range and the machine-learning methods one-class support vector machine, isolation forest, local outlier factor, and elliptic envelope. To evaluate the reliability of individual quality control metrics, a simulation of noise (Gaussian, salt and pepper, speckle) and motion was performed. In outlier detection, single scans with induced artifacts were successfully identified by AIDAqc. AIDAqc was challenged in a large heterogeneous dataset collected from 19 international laboratories, including data from mice, rats, rabbits, hamsters, and gerbils, obtained with different hardware and at different field strengths. The results show that the manual inter-rater agreement (mean Fleiss Kappa score 0.17) is low when identifying poor-quality data. A direct comparison of AIDAqc results, therefore, showed only low-to-moderate concordance. In a manual post hoc validation of AIDAqc output, precision was high (>70%). The outlier data can have a significant impact on further postprocessing, as shown in representative functional and structural connectivity analysis. In summary, this pipeline optimized for small animal MRI provides researchers with a valuable tool to efficiently and effectively assess the quality of their MRI data, which is essential for improved reliability and reproducibility.",

keywords = "image artifacts, machine learning, majority voting, motion detection, reproducibility, standardization",

author = "Aref Kalantari and Mehrab Shahbazi and Marc Schneider and Raikes, {Adam C.} and Fraz{\~a}o, {Victor Vera} and Avnish Bhattrai and Lorenzo Carnevale and Yujian Diao and Franx, {Bart A.A.} and Francesco Gammaraccio and Goncalves, {Lisa Marie} and Susan Lee and {van Leeuwen}, {Esther M.} and Annika Michalek and Susanne Mueller and Olvera, {Alejandro Rivera} and Daniel Padro and Selim, {Mohamed Kotb} and {van der Toorn}, Annette and Federico Varriano and Ro{\"e}l Vrooman and Patricia Wenk and Albers, {H. Elliott} and Philipp Boehm-Sturm and Eike Budinger and Santiago Canals and {De Santis}, Silvia and Brinton, {Roberta Diaz} and Dijkhuizen, {Rick M.} and Elisenda Eixarch and Gianluigi Forloni and Joanes Grandjean and Khan Hekmatyar and Jacobs, {Russell E.} and Ileana Jelescu and Kurniawan, {Nyoman D.} and Giuseppe Lembo and Longo, {Dario Livio} and Maria, {Naomi S.Sta} and Edoardo Micotti and Emma Mu{\~n}oz-Moreno and Pedro Ramos-Cabrer and Wilfried Reichardt and Guadalupe Soria and Ielacqua, {Giovanna D.} and Markus Aswendt",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors. Published under a Creative Commons Attribution 4.0 International (CC BY 4.0) license.",

year = "2024",

month = oct,

day = "17",

doi = "10.1162/imag_a_00317",

language = "English",

volume = "2",

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Kalantari, A, Shahbazi, M, Schneider, M, Raikes, AC, Frazão, VV, Bhattrai, A, Carnevale, L, Diao, Y, Franx, BAA, Gammaraccio, F, Goncalves, LM, Lee, S, van Leeuwen, EM, Michalek, A, Mueller, S, Olvera, AR, Padro, D, Selim, MK, van der Toorn, A, Varriano, F, Vrooman, R, Wenk, P, Albers, HE, Boehm-Sturm, P, Budinger, E, Canals, S, De Santis, S, Brinton, RD, Dijkhuizen, RM, Eixarch, E, Forloni, G, Grandjean, J, Hekmatyar, K, Jacobs, RE, Jelescu, I, Kurniawan, ND, Lembo, G, Longo, DL, Maria, NSS, Micotti, E, Muñoz-Moreno, E, Ramos-Cabrer, P, Reichardt, W, Soria, G, Ielacqua, GD & Aswendt, M 2024, 'Automated quality control of small animal MR neuroimaging data', Imaging Neuroscience, vol. 2. https://doi.org/10.1162/imag_a_00317

TY - JOUR

T1 - Automated quality control of small animal MR neuroimaging data

AU - Kalantari, Aref

AU - Shahbazi, Mehrab

AU - Schneider, Marc

AU - Raikes, Adam C.

AU - Frazão, Victor Vera

AU - Bhattrai, Avnish

AU - Carnevale, Lorenzo

AU - Diao, Yujian

AU - Franx, Bart A.A.

AU - Gammaraccio, Francesco

AU - Goncalves, Lisa Marie

AU - Lee, Susan

AU - van Leeuwen, Esther M.

AU - Michalek, Annika

AU - Mueller, Susanne

AU - Olvera, Alejandro Rivera

AU - Padro, Daniel

AU - Selim, Mohamed Kotb

AU - van der Toorn, Annette

AU - Varriano, Federico

AU - Vrooman, Roël

AU - Wenk, Patricia

AU - Albers, H. Elliott

AU - Boehm-Sturm, Philipp

AU - Budinger, Eike

AU - Canals, Santiago

AU - De Santis, Silvia

AU - Brinton, Roberta Diaz

AU - Dijkhuizen, Rick M.

AU - Eixarch, Elisenda

AU - Forloni, Gianluigi

AU - Grandjean, Joanes

AU - Hekmatyar, Khan

AU - Jacobs, Russell E.

AU - Jelescu, Ileana

AU - Kurniawan, Nyoman D.

AU - Lembo, Giuseppe

AU - Longo, Dario Livio

AU - Maria, Naomi S.Sta

AU - Micotti, Edoardo

AU - Muñoz-Moreno, Emma

AU - Ramos-Cabrer, Pedro

AU - Reichardt, Wilfried

AU - Soria, Guadalupe

AU - Ielacqua, Giovanna D.

AU - Aswendt, Markus

PY - 2024/10/17

Y1 - 2024/10/17

N2 - Magnetic resonance imaging (MRI) is a valuable tool for studying brain structure and function in animal and clinical studies. With the growth of public MRI repositories, access to data has finally become easier. However, filtering large datasets for potential poor-quality outliers can be a challenge. We present AIDAqc, a machine-learning-assisted automated Python-based command-line tool for small animal MRI quality assessment. Quality control features include signal-to-noise ratio (SNR), temporal SNR, and motion. All features are automatically calculated and no regions of interest are needed. Automated outlier detection for a given dataset combines the interquartile range and the machine-learning methods one-class support vector machine, isolation forest, local outlier factor, and elliptic envelope. To evaluate the reliability of individual quality control metrics, a simulation of noise (Gaussian, salt and pepper, speckle) and motion was performed. In outlier detection, single scans with induced artifacts were successfully identified by AIDAqc. AIDAqc was challenged in a large heterogeneous dataset collected from 19 international laboratories, including data from mice, rats, rabbits, hamsters, and gerbils, obtained with different hardware and at different field strengths. The results show that the manual inter-rater agreement (mean Fleiss Kappa score 0.17) is low when identifying poor-quality data. A direct comparison of AIDAqc results, therefore, showed only low-to-moderate concordance. In a manual post hoc validation of AIDAqc output, precision was high (>70%). The outlier data can have a significant impact on further postprocessing, as shown in representative functional and structural connectivity analysis. In summary, this pipeline optimized for small animal MRI provides researchers with a valuable tool to efficiently and effectively assess the quality of their MRI data, which is essential for improved reliability and reproducibility.

AB - Magnetic resonance imaging (MRI) is a valuable tool for studying brain structure and function in animal and clinical studies. With the growth of public MRI repositories, access to data has finally become easier. However, filtering large datasets for potential poor-quality outliers can be a challenge. We present AIDAqc, a machine-learning-assisted automated Python-based command-line tool for small animal MRI quality assessment. Quality control features include signal-to-noise ratio (SNR), temporal SNR, and motion. All features are automatically calculated and no regions of interest are needed. Automated outlier detection for a given dataset combines the interquartile range and the machine-learning methods one-class support vector machine, isolation forest, local outlier factor, and elliptic envelope. To evaluate the reliability of individual quality control metrics, a simulation of noise (Gaussian, salt and pepper, speckle) and motion was performed. In outlier detection, single scans with induced artifacts were successfully identified by AIDAqc. AIDAqc was challenged in a large heterogeneous dataset collected from 19 international laboratories, including data from mice, rats, rabbits, hamsters, and gerbils, obtained with different hardware and at different field strengths. The results show that the manual inter-rater agreement (mean Fleiss Kappa score 0.17) is low when identifying poor-quality data. A direct comparison of AIDAqc results, therefore, showed only low-to-moderate concordance. In a manual post hoc validation of AIDAqc output, precision was high (>70%). The outlier data can have a significant impact on further postprocessing, as shown in representative functional and structural connectivity analysis. In summary, this pipeline optimized for small animal MRI provides researchers with a valuable tool to efficiently and effectively assess the quality of their MRI data, which is essential for improved reliability and reproducibility.

KW - image artifacts

KW - machine learning

KW - majority voting

KW - motion detection

KW - reproducibility

KW - standardization

UR - http://www.scopus.com/inward/record.url?scp=105006417153&partnerID=8YFLogxK

U2 - 10.1162/imag_a_00317

DO - 10.1162/imag_a_00317

M3 - Article

AN - SCOPUS:105006417153

SN - 2837-6056

VL - 2

JO - Imaging Neuroscience

JF - Imaging Neuroscience

ER -

Automated quality control of small animal MR neuroimaging data

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Keywords

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