Using brain structural neuroimaging measures to predict psychosis onset for individuals at clinical high-risk

Yinghan Zhu; Norihide Maikusa; Joaquim Radua; Philipp G. Sämann; Paolo Fusar-Poli; Ingrid Agartz; Ole A. Andreassen; Peter Bachman; Inmaculada Baeza; Xiaogang Chen; Sunah Choi; Cheryl M. Corcoran; Bjørn H. Ebdrup; Adriana Fortea; Ranjini R. G. Garani; Birte Yding Glenthøj; Louise Birkedal Glenthøj; Shalaila S. Haas; Holly K. Hamilton; Rebecca A. Hayes; Ying He; Karsten Heekeren; Kiyoto Kasai; Naoyuki Katagiri; Minah Kim; Tina D. Kristensen; Jun Soo Kwon; Stephen M. Lawrie; Irina Lebedeva; Jimmy Lee; Rachel L. Loewy; Daniel H. Mathalon; Philip McGuire; Romina Mizrahi; Masafumi Mizuno; Paul Møller; Takahiro Nemoto; Dorte Nordholm; Maria A. Omelchenko; Jayachandra M. Raghava; Jan I. Røssberg; Wulf Rössler; Dean F. Salisbury; Daiki Sasabayashi; Lukasz Smigielski; Gisela Sugranyes; Tsutomu Takahashi; Christian K. Tamnes; Jinsong Tang; Anastasia Theodoridou; Alexander S. Tomyshev; Peter J. Uhlhaas; Tor G. Værnes; Therese A. M. J. van Amelsvoort; James A. Waltz; Lars T. Westlye; Juan H. Zhou; Paul M. Thompson; Dennis Hernaus; Maria Jalbrzikowski; Shinsuke Koike; Paul Allen; Helen Baldwin; Sabrina Catalano; Michael W. L. Chee; Kang Ik K. Cho; Lieuwe de Haan; Leslie E. Horton; Mallory J. Klaunig; Yoo Bin Kwak; Xiaoqian Ma; Merete Nordentoft; Lijun Ouyang; Jose C. Pariente; Franz Resch; Jason Schiffman; Mikkel E. Sørensen; Michio Suzuki; Sophia Vinogradov; Christina Wenneberg; Hidenori Yamasue; Liu Yuan

doi:10.1038/s41380-024-02426-7

Using brain structural neuroimaging measures to predict psychosis onset for individuals at clinical high-risk

Yinghan Zhu, Norihide Maikusa, Joaquim Radua, Philipp G. Sämann, Paolo Fusar-Poli, Ingrid Agartz, Ole A. Andreassen, Peter Bachman, Inmaculada Baeza, Xiaogang Chen, Sunah Choi, Cheryl M. Corcoran, Bjørn H. Ebdrup, Adriana Fortea, Ranjini R. G. Garani, Birte Yding Glenthøj, Louise Birkedal Glenthøj, Shalaila S. Haas, Holly K. Hamilton, Rebecca A. HayesYing He, Karsten Heekeren, Kiyoto Kasai, Naoyuki Katagiri, Minah Kim, Tina D. Kristensen, Jun Soo Kwon, Stephen M. Lawrie, Irina Lebedeva, Jimmy Lee, Rachel L. Loewy, Daniel H. Mathalon, Philip McGuire, Romina Mizrahi, Masafumi Mizuno, Paul Møller, Takahiro Nemoto, Dorte Nordholm, Maria A. Omelchenko, Jayachandra M. Raghava, Jan I. Røssberg, Wulf Rössler, Dean F. Salisbury, Daiki Sasabayashi, Lukasz Smigielski, Gisela Sugranyes, Tsutomu Takahashi, Christian K. Tamnes, Jinsong Tang, Anastasia Theodoridou, Alexander S. Tomyshev, Peter J. Uhlhaas, Tor G. Værnes, Therese A. M. J. van Amelsvoort, James A. Waltz, Lars T. Westlye, Juan H. Zhou, Paul M. Thompson, Dennis Hernaus, Maria Jalbrzikowski, Shinsuke Koike, Paul Allen, Helen Baldwin, Sabrina Catalano, Michael W. L. Chee, Kang Ik K. Cho, Lieuwe de Haan, Leslie E. Horton, Mallory J. Klaunig, Yoo Bin Kwak, Xiaoqian Ma, Merete Nordentoft, Lijun Ouyang, Jose C. Pariente, Franz Resch, Jason Schiffman, Mikkel E. Sørensen, Michio Suzuki, Sophia Vinogradov, Christina Wenneberg, Hidenori Yamasue, Liu Yuan

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

Abstract

Machine learning approaches using structural magnetic resonance imaging (sMRI) can be informative for disease classification, although their ability to predict psychosis is largely unknown. We created a model with individuals at CHR who developed psychosis later (CHR-PS+) from healthy controls (HCs) that can differentiate each other. We also evaluated whether we could distinguish CHR-PS+ individuals from those who did not develop psychosis later (CHR-PS-) and those with uncertain follow-up status (CHR-UNK). T1-weighted structural brain MRI scans from 1165 individuals at CHR (CHR-PS+, n = 144; CHR-PS-, n = 793; and CHR-UNK, n = 228), and 1029 HCs, were obtained from 21 sites. We used ComBat to harmonize measures of subcortical volume, cortical thickness and surface area data and corrected for non-linear effects of age and sex using a general additive model. CHR-PS+ (n = 120) and HC (n = 799) data from 20 sites served as a training dataset, which we used to build a classifier. The remaining samples were used external validation datasets to evaluate classifier performance (test, independent confirmatory, and independent group [CHR-PS- and CHR-UNK] datasets). The accuracy of the classifier on the training and independent confirmatory datasets was 85% and 73% respectively. Regional cortical surface area measures-including those from the right superior frontal, right superior temporal, and bilateral insular cortices strongly contributed to classifying CHR-PS+ from HC. CHR-PS- and CHR-UNK individuals were more likely to be classified as HC compared to CHR-PS+ (classification rate to HC: CHR-PS+, 30%; CHR-PS-, 73%; CHR-UNK, 80%). We used multisite sMRI to train a classifier to predict psychosis onset in CHR individuals, and it showed promise predicting CHR-PS+ in an independent sample. The results suggest that when considering adolescent brain development, baseline MRI scans for CHR individuals may be helpful to identify their prognosis. Future prospective studies are required about whether the classifier could be actually helpful in the clinical settings.

Original language	English
Journal	Molecular psychiatry
Early online date	2024
DOIs	https://doi.org/10.1038/s41380-024-02426-7
Publication status	E-pub ahead of print - 2024

Access to Document

10.1038/s41380-024-02426-7

Cite this

Zhu, Y., Maikusa, N., Radua, J., Sämann, P. G., Fusar-Poli, P., Agartz, I., Andreassen, O. A., Bachman, P., Baeza, I., Chen, X., Choi, S., Corcoran, C. M., Ebdrup, B. H., Fortea, A., Garani, R. R. G., Glenthøj, B. Y., Glenthøj, L. B., Haas, S. S., Hamilton, H. K., ... Yuan, L. (2024). Using brain structural neuroimaging measures to predict psychosis onset for individuals at clinical high-risk. Molecular psychiatry. Advance online publication. https://doi.org/10.1038/s41380-024-02426-7

@article{49f7d6711d514bc588a81181108d53b0,

title = "Using brain structural neuroimaging measures to predict psychosis onset for individuals at clinical high-risk",

abstract = "Machine learning approaches using structural magnetic resonance imaging (sMRI) can be informative for disease classification, although their ability to predict psychosis is largely unknown. We created a model with individuals at CHR who developed psychosis later (CHR-PS+) from healthy controls (HCs) that can differentiate each other. We also evaluated whether we could distinguish CHR-PS+ individuals from those who did not develop psychosis later (CHR-PS-) and those with uncertain follow-up status (CHR-UNK). T1-weighted structural brain MRI scans from 1165 individuals at CHR (CHR-PS+, n = 144; CHR-PS-, n = 793; and CHR-UNK, n = 228), and 1029 HCs, were obtained from 21 sites. We used ComBat to harmonize measures of subcortical volume, cortical thickness and surface area data and corrected for non-linear effects of age and sex using a general additive model. CHR-PS+ (n = 120) and HC (n = 799) data from 20 sites served as a training dataset, which we used to build a classifier. The remaining samples were used external validation datasets to evaluate classifier performance (test, independent confirmatory, and independent group [CHR-PS- and CHR-UNK] datasets). The accuracy of the classifier on the training and independent confirmatory datasets was 85% and 73% respectively. Regional cortical surface area measures-including those from the right superior frontal, right superior temporal, and bilateral insular cortices strongly contributed to classifying CHR-PS+ from HC. CHR-PS- and CHR-UNK individuals were more likely to be classified as HC compared to CHR-PS+ (classification rate to HC: CHR-PS+, 30%; CHR-PS-, 73%; CHR-UNK, 80%). We used multisite sMRI to train a classifier to predict psychosis onset in CHR individuals, and it showed promise predicting CHR-PS+ in an independent sample. The results suggest that when considering adolescent brain development, baseline MRI scans for CHR individuals may be helpful to identify their prognosis. Future prospective studies are required about whether the classifier could be actually helpful in the clinical settings.",

author = "Yinghan Zhu and Norihide Maikusa and Joaquim Radua and S{\"a}mann, {Philipp G.} and Paolo Fusar-Poli and Ingrid Agartz and Andreassen, {Ole A.} and Peter Bachman and Inmaculada Baeza and Xiaogang Chen and Sunah Choi and Corcoran, {Cheryl M.} and Ebdrup, {Bj{\o}rn H.} and Adriana Fortea and Garani, {Ranjini R. G.} and Glenth{\o}j, {Birte Yding} and Glenth{\o}j, {Louise Birkedal} and Haas, {Shalaila S.} and Hamilton, {Holly K.} and Hayes, {Rebecca A.} and Ying He and Karsten Heekeren and Kiyoto Kasai and Naoyuki Katagiri and Minah Kim and Kristensen, {Tina D.} and Kwon, {Jun Soo} and Lawrie, {Stephen M.} and Irina Lebedeva and Jimmy Lee and Loewy, {Rachel L.} and Mathalon, {Daniel H.} and Philip McGuire and Romina Mizrahi and Masafumi Mizuno and Paul M{\o}ller and Takahiro Nemoto and Dorte Nordholm and Omelchenko, {Maria A.} and Raghava, {Jayachandra M.} and R{\o}ssberg, {Jan I.} and Wulf R{\"o}ssler and Salisbury, {Dean F.} and Daiki Sasabayashi and Lukasz Smigielski and Gisela Sugranyes and Tsutomu Takahashi and Tamnes, {Christian K.} and Jinsong Tang and Anastasia Theodoridou and Tomyshev, {Alexander S.} and Uhlhaas, {Peter J.} and V{\ae}rnes, {Tor G.} and {van Amelsvoort}, {Therese A. M. J.} and Waltz, {James A.} and Westlye, {Lars T.} and Zhou, {Juan H.} and Thompson, {Paul M.} and Dennis Hernaus and Maria Jalbrzikowski and Shinsuke Koike and Paul Allen and Helen Baldwin and Sabrina Catalano and Chee, {Michael W. L.} and Cho, {Kang Ik K.} and {de Haan}, Lieuwe and Horton, {Leslie E.} and Klaunig, {Mallory J.} and {Bin Kwak}, Yoo and Xiaoqian Ma and Merete Nordentoft and Lijun Ouyang and Pariente, {Jose C.} and Franz Resch and Jason Schiffman and S{\o}rensen, {Mikkel E.} and Michio Suzuki and Sophia Vinogradov and Christina Wenneberg and Hidenori Yamasue and Liu Yuan",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

doi = "10.1038/s41380-024-02426-7",

language = "English",

journal = "Molecular psychiatry",

issn = "1359-4184",

publisher = "Nature Publishing Group",

}

Zhu, Y, Maikusa, N, Radua, J, Sämann, PG, Fusar-Poli, P, Agartz, I, Andreassen, OA, Bachman, P, Baeza, I, Chen, X, Choi, S, Corcoran, CM, Ebdrup, BH, Fortea, A, Garani, RRG, Glenthøj, BY, Glenthøj, LB, Haas, SS, Hamilton, HK, Hayes, RA, He, Y, Heekeren, K, Kasai, K, Katagiri, N, Kim, M, Kristensen, TD, Kwon, JS, Lawrie, SM, Lebedeva, I, Lee, J, Loewy, RL, Mathalon, DH, McGuire, P, Mizrahi, R, Mizuno, M, Møller, P, Nemoto, T, Nordholm, D, Omelchenko, MA, Raghava, JM, Røssberg, JI, Rössler, W, Salisbury, DF, Sasabayashi, D, Smigielski, L, Sugranyes, G, Takahashi, T, Tamnes, CK, Tang, J, Theodoridou, A, Tomyshev, AS, Uhlhaas, PJ, Værnes, TG, van Amelsvoort, TAMJ, Waltz, JA, Westlye, LT, Zhou, JH, Thompson, PM, Hernaus, D, Jalbrzikowski, M, Koike, S, Allen, P, Baldwin, H, Catalano, S, Chee, MWL, Cho, KIK, de Haan, L, Horton, LE, Klaunig, MJ, Bin Kwak, Y, Ma, X, Nordentoft, M, Ouyang, L, Pariente, JC, Resch, F, Schiffman, J, Sørensen, ME, Suzuki, M, Vinogradov, S, Wenneberg, C, Yamasue, H & Yuan, L 2024, 'Using brain structural neuroimaging measures to predict psychosis onset for individuals at clinical high-risk', Molecular psychiatry. https://doi.org/10.1038/s41380-024-02426-7

TY - JOUR

T1 - Using brain structural neuroimaging measures to predict psychosis onset for individuals at clinical high-risk

AU - Zhu, Yinghan

AU - Maikusa, Norihide

AU - Radua, Joaquim

AU - Sämann, Philipp G.

AU - Fusar-Poli, Paolo

AU - Agartz, Ingrid

AU - Andreassen, Ole A.

AU - Bachman, Peter

AU - Baeza, Inmaculada

AU - Chen, Xiaogang

AU - Choi, Sunah

AU - Corcoran, Cheryl M.

AU - Ebdrup, Bjørn H.

AU - Fortea, Adriana

AU - Garani, Ranjini R. G.

AU - Glenthøj, Birte Yding

AU - Glenthøj, Louise Birkedal

AU - Haas, Shalaila S.

AU - Hamilton, Holly K.

AU - Hayes, Rebecca A.

AU - He, Ying

AU - Heekeren, Karsten

AU - Kasai, Kiyoto

AU - Katagiri, Naoyuki

AU - Kim, Minah

AU - Kristensen, Tina D.

AU - Kwon, Jun Soo

AU - Lawrie, Stephen M.

AU - Lebedeva, Irina

AU - Lee, Jimmy

AU - Loewy, Rachel L.

AU - Mathalon, Daniel H.

AU - McGuire, Philip

AU - Mizrahi, Romina

AU - Mizuno, Masafumi

AU - Møller, Paul

AU - Nemoto, Takahiro

AU - Nordholm, Dorte

AU - Omelchenko, Maria A.

AU - Raghava, Jayachandra M.

AU - Røssberg, Jan I.

AU - Rössler, Wulf

AU - Salisbury, Dean F.

AU - Sasabayashi, Daiki

AU - Smigielski, Lukasz

AU - Sugranyes, Gisela

AU - Takahashi, Tsutomu

AU - Tamnes, Christian K.

AU - Tang, Jinsong

AU - Theodoridou, Anastasia

AU - Tomyshev, Alexander S.

AU - Uhlhaas, Peter J.

AU - Værnes, Tor G.

AU - van Amelsvoort, Therese A. M. J.

AU - Waltz, James A.

AU - Westlye, Lars T.

AU - Zhou, Juan H.

AU - Thompson, Paul M.

AU - Hernaus, Dennis

AU - Jalbrzikowski, Maria

AU - Koike, Shinsuke

AU - Allen, Paul

AU - Baldwin, Helen

AU - Catalano, Sabrina

AU - Chee, Michael W. L.

AU - Cho, Kang Ik K.

AU - de Haan, Lieuwe

AU - Horton, Leslie E.

AU - Klaunig, Mallory J.

AU - Bin Kwak, Yoo

AU - Ma, Xiaoqian

AU - Nordentoft, Merete

AU - Ouyang, Lijun

AU - Pariente, Jose C.

AU - Resch, Franz

AU - Schiffman, Jason

AU - Sørensen, Mikkel E.

AU - Suzuki, Michio

AU - Vinogradov, Sophia

AU - Wenneberg, Christina

AU - Yamasue, Hidenori

AU - Yuan, Liu

PY - 2024

Y1 - 2024

N2 - Machine learning approaches using structural magnetic resonance imaging (sMRI) can be informative for disease classification, although their ability to predict psychosis is largely unknown. We created a model with individuals at CHR who developed psychosis later (CHR-PS+) from healthy controls (HCs) that can differentiate each other. We also evaluated whether we could distinguish CHR-PS+ individuals from those who did not develop psychosis later (CHR-PS-) and those with uncertain follow-up status (CHR-UNK). T1-weighted structural brain MRI scans from 1165 individuals at CHR (CHR-PS+, n = 144; CHR-PS-, n = 793; and CHR-UNK, n = 228), and 1029 HCs, were obtained from 21 sites. We used ComBat to harmonize measures of subcortical volume, cortical thickness and surface area data and corrected for non-linear effects of age and sex using a general additive model. CHR-PS+ (n = 120) and HC (n = 799) data from 20 sites served as a training dataset, which we used to build a classifier. The remaining samples were used external validation datasets to evaluate classifier performance (test, independent confirmatory, and independent group [CHR-PS- and CHR-UNK] datasets). The accuracy of the classifier on the training and independent confirmatory datasets was 85% and 73% respectively. Regional cortical surface area measures-including those from the right superior frontal, right superior temporal, and bilateral insular cortices strongly contributed to classifying CHR-PS+ from HC. CHR-PS- and CHR-UNK individuals were more likely to be classified as HC compared to CHR-PS+ (classification rate to HC: CHR-PS+, 30%; CHR-PS-, 73%; CHR-UNK, 80%). We used multisite sMRI to train a classifier to predict psychosis onset in CHR individuals, and it showed promise predicting CHR-PS+ in an independent sample. The results suggest that when considering adolescent brain development, baseline MRI scans for CHR individuals may be helpful to identify their prognosis. Future prospective studies are required about whether the classifier could be actually helpful in the clinical settings.

AB - Machine learning approaches using structural magnetic resonance imaging (sMRI) can be informative for disease classification, although their ability to predict psychosis is largely unknown. We created a model with individuals at CHR who developed psychosis later (CHR-PS+) from healthy controls (HCs) that can differentiate each other. We also evaluated whether we could distinguish CHR-PS+ individuals from those who did not develop psychosis later (CHR-PS-) and those with uncertain follow-up status (CHR-UNK). T1-weighted structural brain MRI scans from 1165 individuals at CHR (CHR-PS+, n = 144; CHR-PS-, n = 793; and CHR-UNK, n = 228), and 1029 HCs, were obtained from 21 sites. We used ComBat to harmonize measures of subcortical volume, cortical thickness and surface area data and corrected for non-linear effects of age and sex using a general additive model. CHR-PS+ (n = 120) and HC (n = 799) data from 20 sites served as a training dataset, which we used to build a classifier. The remaining samples were used external validation datasets to evaluate classifier performance (test, independent confirmatory, and independent group [CHR-PS- and CHR-UNK] datasets). The accuracy of the classifier on the training and independent confirmatory datasets was 85% and 73% respectively. Regional cortical surface area measures-including those from the right superior frontal, right superior temporal, and bilateral insular cortices strongly contributed to classifying CHR-PS+ from HC. CHR-PS- and CHR-UNK individuals were more likely to be classified as HC compared to CHR-PS+ (classification rate to HC: CHR-PS+, 30%; CHR-PS-, 73%; CHR-UNK, 80%). We used multisite sMRI to train a classifier to predict psychosis onset in CHR individuals, and it showed promise predicting CHR-PS+ in an independent sample. The results suggest that when considering adolescent brain development, baseline MRI scans for CHR individuals may be helpful to identify their prognosis. Future prospective studies are required about whether the classifier could be actually helpful in the clinical settings.

UR - http://www.scopus.com/inward/record.url?scp=85184404780&partnerID=8YFLogxK

U2 - 10.1038/s41380-024-02426-7

DO - 10.1038/s41380-024-02426-7

M3 - Article

C2 - 38332374

SN - 1359-4184

JO - Molecular psychiatry

JF - Molecular psychiatry

ER -

Using brain structural neuroimaging measures to predict psychosis onset for individuals at clinical high-risk

Abstract

Access to Document

Other files and links

Cite this