Classification and characterisation of brain network changes in chronic back pain: A multicenter study

Hiroaki Mano; Gopal Kotecha; Kenji Leibnitz; Takashi Matsubara; Christian Sprenger; Aya Nakae; Nicholas Shenker; Masahiko Shibata; Valerie Voon; Wako Yoshida; Michael Lee; Toshio Yanagida; Mitsuo Kawato; Maria Joao Rosa; Ben Seymour

doi:10.12688/wellcomeopenres.14069.2

Classification and characterisation of brain network changes in chronic back pain

Standard

Classification and characterisation of brain network changes in chronic back pain : A multicenter study. / Mano, Hiroaki; Kotecha, Gopal; Leibnitz, Kenji; Matsubara, Takashi; Sprenger, Christian; Nakae, Aya; Shenker, Nicholas; Shibata, Masahiko; Voon, Valerie; Yoshida, Wako; Lee, Michael; Yanagida, Toshio; Kawato, Mitsuo; Rosa, Maria Joao; Seymour, Ben.

In: Wellcome open research, Vol. 3, 2018, p. 19.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Mano, H, Kotecha, G, Leibnitz, K, Matsubara, T, Sprenger, C, Nakae, A, Shenker, N, Shibata, M, Voon, V, Yoshida, W, Lee, M, Yanagida, T, Kawato, M, Rosa, MJ & Seymour, B 2018, 'Classification and characterisation of brain network changes in chronic back pain: A multicenter study', Wellcome open research, vol. 3, pp. 19. https://doi.org/10.12688/wellcomeopenres.14069.2

APA

Mano, H., Kotecha, G., Leibnitz, K., Matsubara, T., Sprenger, C., Nakae, A., Shenker, N., Shibata, M., Voon, V., Yoshida, W., Lee, M., Yanagida, T., Kawato, M., Rosa, M. J., & Seymour, B. (2018). Classification and characterisation of brain network changes in chronic back pain: A multicenter study. Wellcome open research, 3, 19. https://doi.org/10.12688/wellcomeopenres.14069.2

Vancouver

Mano H, Kotecha G, Leibnitz K, Matsubara T, Sprenger C, Nakae A et al. Classification and characterisation of brain network changes in chronic back pain: A multicenter study. Wellcome open research. 2018;3:19. https://doi.org/10.12688/wellcomeopenres.14069.2

Bibtex

@article{9dd5208a46804010a7312240a56bf7f1,

title = "Classification and characterisation of brain network changes in chronic back pain: A multicenter study",

abstract = "Background. Chronic pain is a common, often disabling condition thought to involve a combination of peripheral and central neurobiological factors. However, the extent and nature of changes in the brain is poorly understood. Methods. We investigated brain network architecture using resting-state fMRI data in chronic back pain patients in the UK and Japan (41 patients, 56 controls), as well as open data from USA. We applied machine learning and deep learning (conditional variational autoencoder architecture) methods to explore classification of patients/controls based on network connectivity. We then studied the network topology of the data, and developed a multislice modularity method to look for consensus evidence of modular reorganisation in chronic back pain. Results. Machine learning and deep learning allowed reliable classification of patients in a third, independent open data set with an accuracy of 63%, with 68% in cross validation of all data. We identified robust evidence of network hub disruption in chronic pain, most consistently with respect to clustering coefficient and betweenness centrality. We found a consensus pattern of modular reorganisation involving extensive, bilateral regions of sensorimotor cortex, and characterised primarily by negative reorganisation - a tendency for sensorimotor cortex nodes to be less inclined to form pairwise modular links with other brain nodes. Furthermore, these regions were found to display increased connectivity with the pregenual anterior cingulate cortex, a region known to be involved in endogenous pain control. In contrast, intraparietal sulcus displayed a propensity towards positive modular reorganisation, suggesting that it might have a role in forming modules associated with the chronic pain state. Conclusion. The results provide evidence of consistent and characteristic brain network changes in chronic pain, characterised primarily by extensive reorganisation of the network architecture of the sensorimotor cortex.",

author = "Hiroaki Mano and Gopal Kotecha and Kenji Leibnitz and Takashi Matsubara and Christian Sprenger and Aya Nakae and Nicholas Shenker and Masahiko Shibata and Valerie Voon and Wako Yoshida and Michael Lee and Toshio Yanagida and Mitsuo Kawato and Rosa, {Maria Joao} and Ben Seymour",

year = "2018",

doi = "10.12688/wellcomeopenres.14069.2",

language = "English",

volume = "3",

pages = "19",

}

RIS

TY - JOUR

T1 - Classification and characterisation of brain network changes in chronic back pain

T2 - A multicenter study

AU - Mano, Hiroaki

AU - Kotecha, Gopal

AU - Leibnitz, Kenji

AU - Matsubara, Takashi

AU - Sprenger, Christian

AU - Nakae, Aya

AU - Shenker, Nicholas

AU - Shibata, Masahiko

AU - Voon, Valerie

AU - Yoshida, Wako

AU - Lee, Michael

AU - Yanagida, Toshio

AU - Kawato, Mitsuo

AU - Rosa, Maria Joao

AU - Seymour, Ben

PY - 2018

Y1 - 2018

N2 - Background. Chronic pain is a common, often disabling condition thought to involve a combination of peripheral and central neurobiological factors. However, the extent and nature of changes in the brain is poorly understood. Methods. We investigated brain network architecture using resting-state fMRI data in chronic back pain patients in the UK and Japan (41 patients, 56 controls), as well as open data from USA. We applied machine learning and deep learning (conditional variational autoencoder architecture) methods to explore classification of patients/controls based on network connectivity. We then studied the network topology of the data, and developed a multislice modularity method to look for consensus evidence of modular reorganisation in chronic back pain. Results. Machine learning and deep learning allowed reliable classification of patients in a third, independent open data set with an accuracy of 63%, with 68% in cross validation of all data. We identified robust evidence of network hub disruption in chronic pain, most consistently with respect to clustering coefficient and betweenness centrality. We found a consensus pattern of modular reorganisation involving extensive, bilateral regions of sensorimotor cortex, and characterised primarily by negative reorganisation - a tendency for sensorimotor cortex nodes to be less inclined to form pairwise modular links with other brain nodes. Furthermore, these regions were found to display increased connectivity with the pregenual anterior cingulate cortex, a region known to be involved in endogenous pain control. In contrast, intraparietal sulcus displayed a propensity towards positive modular reorganisation, suggesting that it might have a role in forming modules associated with the chronic pain state. Conclusion. The results provide evidence of consistent and characteristic brain network changes in chronic pain, characterised primarily by extensive reorganisation of the network architecture of the sensorimotor cortex.

AB - Background. Chronic pain is a common, often disabling condition thought to involve a combination of peripheral and central neurobiological factors. However, the extent and nature of changes in the brain is poorly understood. Methods. We investigated brain network architecture using resting-state fMRI data in chronic back pain patients in the UK and Japan (41 patients, 56 controls), as well as open data from USA. We applied machine learning and deep learning (conditional variational autoencoder architecture) methods to explore classification of patients/controls based on network connectivity. We then studied the network topology of the data, and developed a multislice modularity method to look for consensus evidence of modular reorganisation in chronic back pain. Results. Machine learning and deep learning allowed reliable classification of patients in a third, independent open data set with an accuracy of 63%, with 68% in cross validation of all data. We identified robust evidence of network hub disruption in chronic pain, most consistently with respect to clustering coefficient and betweenness centrality. We found a consensus pattern of modular reorganisation involving extensive, bilateral regions of sensorimotor cortex, and characterised primarily by negative reorganisation - a tendency for sensorimotor cortex nodes to be less inclined to form pairwise modular links with other brain nodes. Furthermore, these regions were found to display increased connectivity with the pregenual anterior cingulate cortex, a region known to be involved in endogenous pain control. In contrast, intraparietal sulcus displayed a propensity towards positive modular reorganisation, suggesting that it might have a role in forming modules associated with the chronic pain state. Conclusion. The results provide evidence of consistent and characteristic brain network changes in chronic pain, characterised primarily by extensive reorganisation of the network architecture of the sensorimotor cortex.

U2 - 10.12688/wellcomeopenres.14069.2

DO - 10.12688/wellcomeopenres.14069.2

M3 - SCORING: Journal article

C2 - 29774244

VL - 3

SP - 19

ER -