TY - JOUR
T1 - Network-Based Spreading of Gray Matter Changes Across Different Stages of Psychosis
AU - Chopra, Sidhant
AU - Segal, Ashlea
AU - Oldham, Stuart
AU - Holmes, Alexander
AU - Sabaroedin, Kristina
AU - Orchard, Edwina R.
AU - Francey, Shona M.
AU - O'Donoghue, Brian
AU - Cropley, Vanessa
AU - Nelson, Barnaby
AU - Graham, Jessica
AU - Baldwin, Lara
AU - Tiego, Jeggan
AU - Yuen, Hok Pan
AU - Allott, Kelly
AU - Alvarez-Jimenez, Mario
AU - Harrigan, Susy
AU - Fulcher, Ben D.
AU - Aquino, Kevin
AU - Pantelis, Christos
AU - Wood, Stephen J.
AU - Bellgrove, Mark
AU - McGorry, Patrick D.
AU - Fornito, Alex
N1 - Funding Information:
Funding/Support: This study was supported by grant 1064704 from the Australian National Health and Medical Research Project; by grants from the NHMRC and Australian Research Council (Dr Francey, Aquino, Panteilis, Alvarez-Jimenez, and Fornito); by the Lundbeck Foundation (Dr Pantelis); by the Colonial Foundation, the National Alliance for Research on Schizophrenia and Depression, the Stanley Foundation, the NIH, Wellcome Trust, the Australian and Victorian governments, and Janssen-Cilag (Dr McGorry); by Senior Research Fellowship 1137687 from the NHMRC and a University of Melbourne Dame Kate Campbell Fellowship (Dr Nelson); and by the computational infrastructure provided by the MASSIVE HPC facility ( www.massive.org.au ). Janssen-Cilag partially supported the early years of the clinical trial data set included in this study with an unrestricted investigator-initiated grant and provided risperidone, paliperidone, and matched placebo for the first 30 participants.
Publisher Copyright:
© 2023 American Medical Association. All rights reserved.
PY - 2023/12/6
Y1 - 2023/12/6
N2 - Importance: Psychotic illness is associated with anatomically distributed gray matter reductions that can worsen with illness progression, but the mechanisms underlying the specific spatial patterning of these changes is unknown. Objective: To test the hypothesis that brain network architecture constrains cross-sectional and longitudinal gray matter alterations across different stages of psychotic illness and to identify whether certain brain regions act as putative epicenters from which volume loss spreads. Design, Settings, and Participants: This case-control study included 534 individuals from 4 cohorts, spanning early and late stages of psychotic illness. Early-stage cohorts included patients with antipsychotic-naive first-episode psychosis (n = 59) and a group of patients receiving medications within 3 years of psychosis onset (n = 121). Late-stage cohorts comprised 2 independent samples of people with established schizophrenia (n = 136). Each patient group had a corresponding matched control group (n = 218). A sample of healthy adults (n = 356) was used to derive representative structural and functional brain networks for modeling of network-based spreading processes. Longitudinal illness-related and antipsychotic-related gray matter changes over 3 and 12 months were examined using a triple-blind randomized placebo-control magnetic resonance imaging study of the antipsychotic-naive patients. All data were collected between April 29, 2008, and January 15, 2020, and analyses were performed between March 1, 2021, and January 14, 2023. Main Outcomes and Measures: Coordinated deformation models were used to estimate the extent of gray matter volume (GMV) change in each of 332 parcellated areas by the volume changes observed in areas to which they were structurally or functionally coupled. To identify putative epicenters of volume loss, a network diffusion model was used to simulate the spread of pathology from different seed regions. Correlations between estimated and empirical spatial patterns of GMV alterations were used to quantify model performance. Results: Of 534 included individuals, 354 (66.3%) were men, and the mean (SD) age was 28.4 (7.4) years. In both early and late stages of illness, spatial patterns of cross-sectional volume differences between patients and controls were more accurately estimated by coordinated deformation models constrained by structural, rather than functional, network architecture (r range, >0.46 to <0.57; P <.01). The same model also robustly estimated longitudinal volume changes related to illness (r ≥ 0.52; P <.001) and antipsychotic exposure (r ≥ 0.50; P <.004). Network diffusion modeling consistently identified, across all 4 data sets, the anterior hippocampus as a putative epicenter of pathological spread in psychosis. Epicenters of longitudinal GMV loss were apparent in posterior cortex early in the illness and shifted to the prefrontal cortex with illness progression. Conclusion and Relevance: These findings highlight a central role for white matter fibers as conduits for the spread of pathology across different stages of psychotic illness, mirroring findings reported in neurodegenerative conditions. The structural connectome thus represents a fundamental constraint on brain changes in psychosis, regardless of whether these changes are caused by illness or medication. Moreover, the anterior hippocampus represents a putative epicenter of early brain pathology from which dysfunction may spread to affect connected areas..
AB - Importance: Psychotic illness is associated with anatomically distributed gray matter reductions that can worsen with illness progression, but the mechanisms underlying the specific spatial patterning of these changes is unknown. Objective: To test the hypothesis that brain network architecture constrains cross-sectional and longitudinal gray matter alterations across different stages of psychotic illness and to identify whether certain brain regions act as putative epicenters from which volume loss spreads. Design, Settings, and Participants: This case-control study included 534 individuals from 4 cohorts, spanning early and late stages of psychotic illness. Early-stage cohorts included patients with antipsychotic-naive first-episode psychosis (n = 59) and a group of patients receiving medications within 3 years of psychosis onset (n = 121). Late-stage cohorts comprised 2 independent samples of people with established schizophrenia (n = 136). Each patient group had a corresponding matched control group (n = 218). A sample of healthy adults (n = 356) was used to derive representative structural and functional brain networks for modeling of network-based spreading processes. Longitudinal illness-related and antipsychotic-related gray matter changes over 3 and 12 months were examined using a triple-blind randomized placebo-control magnetic resonance imaging study of the antipsychotic-naive patients. All data were collected between April 29, 2008, and January 15, 2020, and analyses were performed between March 1, 2021, and January 14, 2023. Main Outcomes and Measures: Coordinated deformation models were used to estimate the extent of gray matter volume (GMV) change in each of 332 parcellated areas by the volume changes observed in areas to which they were structurally or functionally coupled. To identify putative epicenters of volume loss, a network diffusion model was used to simulate the spread of pathology from different seed regions. Correlations between estimated and empirical spatial patterns of GMV alterations were used to quantify model performance. Results: Of 534 included individuals, 354 (66.3%) were men, and the mean (SD) age was 28.4 (7.4) years. In both early and late stages of illness, spatial patterns of cross-sectional volume differences between patients and controls were more accurately estimated by coordinated deformation models constrained by structural, rather than functional, network architecture (r range, >0.46 to <0.57; P <.01). The same model also robustly estimated longitudinal volume changes related to illness (r ≥ 0.52; P <.001) and antipsychotic exposure (r ≥ 0.50; P <.004). Network diffusion modeling consistently identified, across all 4 data sets, the anterior hippocampus as a putative epicenter of pathological spread in psychosis. Epicenters of longitudinal GMV loss were apparent in posterior cortex early in the illness and shifted to the prefrontal cortex with illness progression. Conclusion and Relevance: These findings highlight a central role for white matter fibers as conduits for the spread of pathology across different stages of psychotic illness, mirroring findings reported in neurodegenerative conditions. The structural connectome thus represents a fundamental constraint on brain changes in psychosis, regardless of whether these changes are caused by illness or medication. Moreover, the anterior hippocampus represents a putative epicenter of early brain pathology from which dysfunction may spread to affect connected areas..
UR - http://www.scopus.com/inward/record.url?scp=85178053350&partnerID=8YFLogxK
U2 - 10.1001/jamapsychiatry.2023.3293
DO - 10.1001/jamapsychiatry.2023.3293
M3 - Article
C2 - 37728918
AN - SCOPUS:85178053350
SN - 2168-622X
VL - 80
SP - 1246
EP - 1257
JO - JAMA Psychiatry
JF - JAMA Psychiatry
IS - 12
ER -