Objective

Front. Psychiatry

Frontiers in Psychiatry

Front. Psychiatry

1664-0640

Frontiers Media S.A.

10.3389/fpsyt.2022.785547

Psychiatry

Original Research

Gray Matter Alterations in Pediatric Schizophrenia and Obsessive-Compulsive Disorder: A Systematic Review and Meta-Analysis of Voxel-Based Morphometry Studies

Liu

Jingran

Wen

Fang

Yan

Junjuan

Liping

Wang

Fang

Wang

Duo

Zhang

Jishui

Yan

Chunmei

Chu

Jiahui

Yanlin

Ying

^* Cui

Yonghua

Department of Psychiatry, Beijing Children's Hospital, Capital Medical University, National Centre for Children's Health, Beijing, China

Edited by: Lu Liu, Peking University Sixth Hospital, China

Reviewed by: Valentina Ciullo, Santa Lucia Foundation (IRCCS), Italy; Takefumi Ueno, Hizen Psychiatric Center (NHO), Japan

*Correspondence: Ying Li liying@bch.com.cn Yonghua Cui cuiyonghua@bch.com.cn

This article was submitted to Neuroimaging and Stimulation, a section of the journal Frontiers in Psychiatry

02 03 2022

2022

785547

29 09 2021 02 02 2022

2022

Liu, Wen, Yan, Yu, Wang, Wang, Zhang, Yan, Chu, Li, Li and Cui

This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

Objective

The aim of this study is comparing gray matter alterations in SCZ pediatric patients with those suffering from obsessive-compulsive disorder (OCD) based on a systematic review and an activation likelihood estimation (ALE) meta-analysis.

Methods

A systematic literature search was performed in PubMed, Elsevier, and China National Knowledge Infrastructure (CNKI). A systematic review and an ALE meta-analysis were performed to quantitatively examine brain gray matter alterations.

Results

Children and adolescents with schizophrenia had decreased gray matter volume (GMV) mainly in the prefrontal cortex (PFC), temporal cortex (such as the middle temporal gyrus and transverse temporal gyrus), and insula, while children and adolescents with OCD mainly had increased GMV in the PFC and the striatum (including the lentiform nucleus and caudate nucleus), and decreased GMV in the parietal cortex.

Conclusions

Our results suggest that gray matter abnormalities in the PFC may indicate homogeneity between the two diseases. In children and adolescents, structural alterations in schizophrenia mainly involve the fronto-temporal and cortico-insula circuits, whereas those in OCD mainly involve the prefrontal-parietal and the prefrontal-striatal circuits.

schizophrenia obsessive-compulsive disorders activation likelihood estimation gray matter children and adolescents

National Natural Science Foundation of China10.13039/501100001809

Beijing Municipal Natural Science Foundation10.13039/501100005089

Introduction

Schizophrenia (SCZ), a severe psychiatric disorder characterized by symptoms such as hallucinations, delusions, disorganized thinking, amotivation, and cognitive dysfunction, has an onset in childhood and adolescence (1). Another serious psychiatric disorder that also often onsets in childhood and adolescence is obsessive-compulsive disorder (OCD), which is characterized by intrusive thoughts and repetitive and ritualistic behaviors (2). High comorbidity of OCD has been reported among patients with schizophrenia (3). A prior diagnosis of OCD and age of <20 years at OCD onset are associated with higher rates of subsequently diagnosed schizophrenia (4, 5). Some studies have found that SCZ and OCD share some demographic and clinical characteristics (6). These findings suggest that SCZ and OCD share common neuropathology. Therefore, many studies have compared SCZ and OCD to investigate their multidimensional heterogeneity.

Both SCZ and OCD have been recognized as neurodevelopmental disorders (7). Brain structural and functional abnormalities have been observed in SCZ and OCD at the early stages of life (8, 9). Indeed, some neuroimaging studies have compared brain structural abnormalities in adults with SCZ and OCD; however, the results of these studies are largely inconsistent. For example, Zhang et al. found that patients with SCZ and those with OCD lost similar gray matter (GM) volume in the right anterior cingulate (10). However, another study suggests that compared with patients with OCD, those with SCZ had reduced GM volume mainly in the prefrontal gyrus (including the left precuneus, left superior frontal gyrus, right middle frontal gyrus, etc.) (11). The above studies indicate that further investigations are warranted to compare gray matter volume differences between SCZ and OCD.

Notably, a meta-analysis of imaging studies (i.e., activation likelihood estimation [ALE] analysis) might serve as an important tool to confirm the structural and functional abnormalities in SCZ and OCD. Previously, to investigate the differences between SCZ and OCD, Goodkind et al. (12) performed a voxel-based morphometry (VBM)-based meta-analysis of 193 studies. They reported GM loss in the dorsal anterior cingulate cortex (dACC) and bilateral insula, brain areas that relate to executive functions. A secondary analysis of mega- and meta-analytical findings revealed that regions such as the hippocampus and fusiform gyrus exhibited high conformity to the shared morphometric signature of SCZ and OCD (13). Nevertheless, since existing research is limited to comparisons of adult populations, the similarities and differences in GM alterations among children and adolescents with either SCZ or OCD remain largely unknown. Indeed, previous studies found widespread structural brain changes in both pediatric OCD and adult OCD, but different age stages might indicate different structural alterations (14, 15). For example, by assessing cortical thickness and surface area, Boedhoe et al. (16) found that the parietal cortex was consistently implicated in both adults and children with OCD, but the temporal and frontal cortex changes were different during different stages of development and illness.

It should be noted that few studies have compared brain structural abnormalities in children and adolescents with SCZ and those with OCD. To the best of our knowledge, only one comparative study reported that children and adolescents with SCZ have more widespread white matter abnormalities than those with OCD (17). Children and adolescents with SCZ generally have decreased cortical GM, particularly in the frontotemporal cortical areas (18, 19). On the other hand, GM alterations present not only in the classical fronto–striatal–thalamic circuit but also in the parietal and occipital cortices have been found in pediatric OCD (14, 16, 20). However, further meta-analytical research into GM alterations in children and adolescents with SCZ and those with OCD is required.

Currently, there is no comparison between the two patient groups (SCZ and OCD) is performed in children and adolescents. The aim of this study is comparing gray matter alterations in SCZ patients with those suffering from OCD. First, a systematic review was performed to summarize the gray matter alterations in both SCZ and OCD. Second, an ALE meta-analysis was performed to quantitatively examine brain gray matter alterations. We hypothesized that shared GM alterations between SCZ and OCD should be within GM loss in the fronto–striatal–thalamic circuit. Thus, we intend to provide some neural indicators for children and adolescents with SCZ and those with OCD.

Materials and Methods Literature Search

Literature searches were performed in online databases, including PubMed, Web of Science and China National Knowledge Infrastructure (CNKI). We used the keywords and combinations of the following search terms with the following search expressions: (“schizophrenia” OR “obsessive-compulsive disorder”) AND “structural” AND “MRI” AND “gray matter.” Additionally, the reference lists of relevant articles were obtained and screened for any additional studies missed by the database search. Next, the titles and abstracts of the articles identified were screened according to the inclusion criteria. After this screening stage, the full journal articles were checked to determine whether they met the criteria of the included studies. Studies were independently cross-checked by two researchers to identify relevant articles. Articles published up to 31 August 2021 were included.

Inclusion and Exclusion Criteria

The following inclusion criteria were used to identify relevant studies for our meta-analysis: (1) English or Chinese language studies from peer-reviewed journals, (2) age of patients at diagnosis of SCZ or OCD (age: <18 years), and (3) VBM studies (both the whole brain analyses and ROI analyses were included). The exclusion criteria were as follows: (1) patient sample size <10 and (2) duplicate studies.

Systematic Review and ALE Meta-Analysis

First, a systematic review was performed. The key step of the systematic review is data extraction. The extracted data included the “Sample Size,” “Age,” “Males Percentage,” “Duration of Illness (DOI),” as well as the “Brain regions of Gray matter alterations” (if the gray matter decreased, Patients < Controls, it will be marked A; if Patients> Controls, B was marked).

Second, based on the inclusion and exclusion criteria for the included studies, an ALE analysis was performed. The last BrainMap application, the Java-based version of Ginger ALE, is used for performing activation likelihood estimation (ALE) meta-analyses on sets of coordinates extracted from the database in Talairach or MNI space. In the present study, Ginger ALE version 3.0.2 was adopted in the present meta-analysis of the included VBM studies that reported the foci of GM changes (21). ALE analyses were conducted in Montreal Neurological Institute (MNI) space; however, if coordinates were originally reported in Talairach space, they were converted into MNI space with the Lancaster transform using the icbm2tal transformation function implemented within GingerALE (22). The resulting statistical maps were corrected for a threshold at p < 0.001 (False Discovery Rate correction, FDR) with a cluster extent threshold of 50 voxels. For visualization, whole-brain maps of threshold ALE maps were imported into multi-image analysis Mango (http://ric.uthscsa.edu/mango) and overlaid onto a standardized anatomical template (the ICBM-152 brain template) (22).

Results Identification of Included Studies

The identification procedure of the studies can be found in Figure 1. Initially, we identified 21 English language studies and 1 Chinese language study according to the criteria. We list the exclusion information in Supplementary Table 1.

Figure 1

Flowchart of the selection criteria.

Systematic Review of Included Studies

The VBM datasets were obtained from 11 SCZ studies and 11 OCD studies. The baseline characteristics of all participants and the brain regions of gray matter alterations are summarized in Table 1. Two SCZ studies found GM volume changes without reporting the foci (23, 29). Four studies did not find any significant differences in GM volume between patients and healthy controls (26, 33, 36, 38). It seems that children and adolescents with schizophrenia had decreased gray matter volume (GMV), mainly in the prefrontal cortex (PFC), temporal cortex and insula, while children and adolescents with OCD mainly had increased GMV in the PFC and the striatum, but decreased GMV in the parietal cortex.

Table 1

Demographic and clinical characteristics of the 22 voxel-based morphometry studies.

References	Patients					Controls			Brain regions of gray matter alterations
	Sample size	Age	Males%	DOI	Treatment	Sample size	Age	Males%	Patients < Controls (A)	Patients> Controls (B)
SCZ studies
Wen et al. (23)	29	14.93 ± 1.60	34	NR	NR	28	16.00 ± 0.47	43	Hippocampus (A)
Gao et al. (24)	39	13.5 ± 2.3	44	5 ± 3	0	39	13.3 ± 2.0	36	R insula, L IFG, L limbic edge (A)
Zhang et al. (25)	26	16.87 ± 1.05	50	3.61 ± 3.50	0	26	16.81 ± 0.75	50	L parietal postcentral gyrus, L parahippocampa (A)
Castro-Fornieles et al. (26)	34	15.2 ± 1.7	71	NR	NR	70	15.3 ± 1.5	60	No positive results
Zhang et al. (27)	37	15.5 ± 1.8	46	16.0 ± 14.4	0	37	15.3 ± 1.6	46	R STG, R MTG (A)
Tang et al. (28)	29	16.5 ± 0.9	45	9.3 ± 4.6	79	29	16.6 ± 0.8	55	L STG, L MTG (A)
James et al. (29)	32	16.3 ± 1.2	69	21.6 ± NR	100	28	16.4 ± 1.4	64	PFC, STG, ITG (A)
Yoshihara et al. (30)	18	15.8 ± 1.3	50	14.4 ± 10.8	94	18	15.8 ± 1.8	50	L parahippocampal, IFG, STG (A)
Janssen et al. (31)	25	15.4 ± 1.8	76	3.5 ± 2.2	NR	25	15.4 ± 1.6	69	L medial frontal gyrus, L MFG (A)
Douaud et al. (32)	25	16.3 ± 1.3	72	16.8 ± 8.4	100	25	16.0 ± 1.7	68	SMA, R ACC, R dorso-lateral PFC (A)
Pagsberg et al. (33)	15	15.6 ± 1.8	47	NR	NR	29	16 ± 1.9	38	No Positive Results
OCD studies
Cheng et al. (34)	30	10.8 ± 2.1	60	NR	0	30	10.5 ± 2.2	60	L IPL(A), Putamen, L OFC (B)
Jayarajan et al. (35)	15	14.13 ± 1.79	53	16.8 ± 12.9	86	15	14.31 ± 2.12	53	L ACC (A)
Lázaro et al. (36)	62	15.4 ± 2.1	58	28.29 ± 24.16	84	46	15.3 ± 2.1	48	No Positive Results
Huyser et al. (37)	29	13.78 ± 2.58	28	31.2 ± 27.6	0	29	13.60 ± 2.73	28	L superior frontal pole, L insula (B)
Lázaro et al. (38)	27	15.6 ± 1.5	56	NR	100	27	16.1 ± 1.3	48	No Positive Results
Zarei et al. (39)	26	16.6 ± 1.5	54	63.6 ± 40.8	62	26	16.5 ± 1.4	54	Caudate, R putamen (B)
Britton et al. (40)	15	13.5 ± 2.4	60	49.2 ± 24.0	100	20	13.6 ± 2.4	65	Medial frontal gyrus, OFC; R ACC (B)
Lázaro et al. (41)	15	13.7 ± 2.5	53	21.2 ± 16.6	0	15	14.3 ± 2.5	53	Parietal lobes(A)
Szeszko et al. (42)	37	13.0 ± 2.7	38	43.2 ± NR	0	26	13.0 ± 2.6	35	Occipital cortex (A); OFC, STG, parietal lobe (B)
Gilbert et al. (43)	10	12.9 ± 2.7	60	NR	0	10	13.4 ± 2.6	60	L ACC, medial SFG (A)
Carmona et al. (44)	18	12.86 ± 2.76	72	NR	56	18	13.03 ± 3.04	72	Frontal lobe, cingulate cortex (A)

SCZ, schizophrenia; OCD, obsessive-compulsive disorder; y, years; m, months; DOI, duration of illness; SD, standard deviation; NR, not recorded; R, right; L, left; IFG, inferior frontal gyrus; STG, superior temporal gyrus; MTG, middle temporal gyrus; PFC, prefrontal cortex; ITG, inferior temporal gyrus; MFG, middle frontal gyrus; SFG, superior frontal gyrus; SMA, supplementary motor area; IPL, inferior parietal lobule; OFC, orbitofrontal cortex; ACC, anterior cingulate cortex.

ALE Analysis in Children and Adolescents With SCZ and OCD

For the ALE analysis, there were 7 SCZ studies (including 199 patients with SCZ and 225 control subjects) and nine OCD studies (including 195 patients with OCD and 189 control subjects). ALE analysis in children and adolescents with SCZ revealed that GM volume was significantly reduced in the bilateral medial frontal gyrus, right middle frontal gyrus (MFG), bilateral inferior frontal gyrus (IFG), bilateral superior frontal gyrus (SFG), bilateral temporal sub-gyrus, and so on (for more details, see Table 2; Figure 2).

Table 2

Results of ALE analyses on gray matter reduction in SCZ.

Cluster #	Volume (mm³)	Peak ALE value	MNI coordinates (x,y,z)			Brain regions
1	96	0.009153046	48	−10	−16	(R) Temporal Sub-Gyral (BA21)
2	96	0.008924574	36	21	3	(R) Insula (BA13)
3	96	0.008930734	0	44	28	(L) Medial Frontal Gyrus (BA9)
4	80	0.009246408	54	18	9	(R) Inferior Frontal Gyrus (BA44)
5	64	0.008868549	−54	−22	−12	(L) Middle Temporal Gyrus (BA21)
6	56	0.008880154	−50	−16	−22	(L) Temporal Sub-Gyral (BA20)
7	56	0.008856174	−12	−90	6	(L) Lingual Gyrus (BA17)
8	56	0.008856174	50	−22	8	(R) Transverse Temporal Gyrus (BA41)
9	56	0.008856174	−48	−18	10	(L) Transverse Temporal Gyrus (BA41)
10	56	0.008856174	−46	18	12	(L) Inferior Frontal Gyrus (BA44)
11	56	0.008856174	20	−60	14	(R) Posterior Cingulate (BA30)
12	56	0.008856174	50	−24	20	(R) Insula (BA13)
13	56	0.008856174	−50	8	20	(L) Inferior Frontal Gyrus (BA9)
14	56	0.008856175	20	44	20	(R) Medial Frontal Gyrus (BA9)
15	56	0.008856174	−38	−16	24	(L) Insula (BA13)
16	56	0.008858921	14	40	30	(R) Medial Frontal Gyrus (BA9)
17	56	0.008856174	24	−70	32	(R) Precuneus (BA31)
18	56	0.008856176	20	44	32	(R) Superior Frontal Gyrus (BA9)
19	56	0.008856174	14	8	34	(R) Cingulate (BA24)
20	56	0.008856174	38	10	38	(R) Medial Frontal Gyrus (BA6)
21	56	0.008856174	60	−16	44	(R) Postcentral Gyrus (BA3)
22	56	0.008856174	−40	−36	46	(L) Inferior Parietal Lobule (BA40)
23	56	0.008856235	−22	18	48	(L) Superior Frontal Gyrus (BA6)
24	56	0.008929286	−10	−38	70	(L) Postcentral Gyrus (BA5)

SCZ, schizophrenia; ALE, activation likelihood estimation; MNI, Montreal Neurological Institute; R, right; L, left; BA, Brodmann area.

Figure 2

The gray matter reduction (red) in SCZ based on ALE analysis.

For children and adolescents with OCD, GM volume was significantly reduced in the left supramarginal gyrus, left cuneus, left middle occipital gyrus, right IFG, right SFG, bilateral MFG, right precentral gyrus, right paracentral lobule, right precuneus, bilateral cingulate, and right culmen. Simultaneously, GM volume was significantly increased in the left medial frontal gyrus, right MFG, right IFG, left SFG, striatum and so on (for more details, see Tables 3, 4; Figure 3).

Table 3

Results of ALE analyses on gray matter reduction in OCD.

Cluster #	Volume (mm³)	Peak ALE value	MNI coordinates (x,y,z)			Brain regions
1	312	0.013117323	−62	−52	38	(L) Supramarginal Gyrus (BA40)
2	96	0.008858794	−11	−88	13	(L) Cuneus (BA17)
3	96	0.008858794	−27	−84	13	(L) Middle Occipital Gyrus (BA18)
4	96	0.00766531	44	13	35	(R) Precentral Gyrus (BA9)
4		0.007424954	43	13	30	(R) Inferior Frontal Gyrus (BA9)
5	96	0.00766531	25	29	42	(R) Superior Frontal Gyrus (BA8)
5		0.007424954	27	24	43	(R) Superior Frontal Gyrus (BA8)
6	96	0.00766531	3	−13	48	(R) Paracentral Lobule (BA31)
6		0.007424954	8	−11	49	(R) Paracentral Lobule (BA31)
7	80	0.009176578	16	−63	−4	(R) Culmen
8	64	0.007424954	53	27	21	(R) Middle Frontal Gyrus (BA46)
9	64	0.007424954	−45	25	23	(L) Middle Frontal Gyrus (BA46)
10	64	0.007424954	15	−53	41	(R) Precuneus (BA31)
11	64	0.007424954	15	−37	43	(R) Cingulate Gyrus (BA31)
12	64	0.007424954	1	−31	47	(L) Cingulate Gyrus (BA31)

OCD, obsessive-compulsive disorder; ALE, activation likelihood estimation; MNI, Montreal Neurological Institute; R, right; L, left; BA, Brodmann area.

Table 4

Results of ALE analyses on gray matter increase in OCD.

Cluster #	Volume (mm³)	Peak ALE value	MNI coordinates (x,y,z)			Brain regions
1	608	0.016521817	−26	12	2	(L) Lentiform Nucleus (Putamen)
2	304	0.009560066	20	20	−2	(R) Caudate (Caudate Head)
		0.008989162	14	16	−2	(R) Caudate (Caudate Head)
3	224	0.009225059	−12	66	−10	(L) Medial Frontal Gyrus (BA10)
		0.008012949	−18	58	−10	(L) Superior Frontal Gyrus (BA10)
4	200	0.00917098	−18	56	10	(L) Superior Frontal Gyrus (BA10)
		0.008015263	−8	56	10	(L) Medial Frontal Gyrus (BA10)
5	112	0.009076225	−14	38	−22	(L) Medial Frontal Gyrus (BA11)
6	96	0.008518396	−30	−19	19	(L) Claustrum
7	96	0.008858794	13	−52	63	(R) Precuneus Gray (BA7)
8	80	0.009176578	20	34	−23	(R) Inferior Frontal Gyrus (BA47)
9	80	0.008632486	26	−5	2	(R) Lentiform Nucleus (Putamen)
10	80	0.00881557	−50	−26	29	(L) Inferior Parietal Lobule (BA40)
11	80	0.009176578	8	−69	58	(R) Superior Parietal Lobule (BA7)
12	80	0.009176578	−12	−65	62	(L) Superior Parietal Lobule (BA7)
13	64	0.008552016	45	3	−25	(R) Superior Temporal Gyrus (BA38)
14	64	0.008079925	−12	14	2	(L) Caudate (Caudate Head)
15	64	0.008495986	32	3	45	(R) Middle Frontal Gyrus (BA6)

OCD, obsessive-compulsive disorder; ALE, activation likelihood estimation; MNI, Montreal Neurological Institute; R, right; L, left; BA, Brodmann area.

Figure 3

The gray matter reduction (red) and increase (green) in OCD based on ALE analysis.

Discussion

The current systematic review and ALE meta-analysis revealed that children and adolescents with either SCZ or OCD have significant GMV abnormalities in multiple brain regions. However, despite being relatively consistent with the existing literature, our findings showed heterogeneous results. First, both children and adolescents with SCZ and those with OCD showed GMV alterations in the prefrontal cortex (PFC), which included the medial frontal gyrus and MFG (BA9, BA10). Notably, in this area, GMV was decreased in children and adolescents with SCZ and increased in those with OCD. Second, children and adolescents with SCZ showed decreased GMV in the temporal cortex (especially in the MTG and the transverse temporal gyrus) and insula. However, for children and adolescents with OCD, loss of GM was found in the parietal cortex, mainly in the supramarginal gyrus. Third, children and adolescents with OCD had a greater striatal GM volume, including the lentiform nucleus and caudate nucleus, than control subjects. Overall, we found that children and adolescents with SCZ and those with OCD have significant GMV abnormalities in multiple brain regions. For the cortical cortex, a decrease in GMV was observed mainly in the areas of the PFC (medial frontal gyrus and MFG), temporal cortex (especially in the MTG and transverse temporal gyrus), and insula in children and adolescents with SCZ. In children and adolescents with OCD, an increase in GMV was observed in the PFC, while a decrease in GMV was observed in the parietal cortex (supramarginal gyrus). For subcortical regions, we found that children and adolescents with OCD had a greater striatal volume, including the lentiform nucleus and caudate nucleus.

Gray matter loss in the PFC has been previously reported in children and adolescents with SCZ. In addition to the VBM studies in our meta-analysis, studies using the “region of interest” (ROI) approach suggested that children and adolescents with SCZ had a deficit in GM volume in the PFC (45–47). In addition, longitudinal magnetic resonance imaging studies have reported that children and adolescents with SCZ showed greater progressive frontal GM loss over years after illness onset than healthy individuals (48, 49). Recently, a large-scale study concluded that individuals with schizophrenia have a widespread thinner cortex and smaller surface area in frontal lobe regions (50). Supplementing previous research, the results of this study indicate that GM loss in the PFC might occur at an earlier course of SCZ.

We found an increase, rather than a decrease, in GMV of the PFC in children and adolescents with OCD, in contrast to that reported in a previous meta-analysis (20). These discrepancies can be explained by the differences in the OCD studies included. We excluded a study reporting a lower PFC volume because of the small sample size (51) and two studies reporting a greater PFC volume (34, 40). Recently, a large-scale graph analysis of brain structural covariance networks found that the PFC exhibited OCD-related alterations in the trajectories of brain development and maturation (52). Similar to SCZ, the results of the present study also indicated that GM alterations might occur at an earlier course of OCD.

The PFC plays an essential role in the organization and control of goal-directed thoughts and behaviors (53). Furthermore, the PFC orchestrates a wide range of cognitive and affective neuronal functions thanks to its extensive reciprocal connections to nearly all cortical and subcortical structures (53). The PFC dysconnectivity pattern in patients with SCZ is associated with the severity of cognitive impairments (such as impaired working memory) (54). Disruption of executive functions that are PFC-regulated may lead to the generation of obsessions and compulsions in patients with OCD (55). Several functional imaging studies have consistently highlighted abnormal activity patterns in PFC regions and connected circuits in SCZ and OCD during both symptom provocation and performance of neurocognitive tasks (54, 55). Our results hint at GM alterations in the PFC shared by children and adolescents with SCZ and those with OCD, which might account for comorbid cognitive deficits in both disorders.

In terms of other cortical abnormalities, GMV in the temporal cortex was decreased in children and adolescents with SCZ, whereas GMV in the parietal cortex was decreased in children and adolescents with OCD. Previous studies have reported a decreased GMV in the temporal cortex as well as in the PFC (47, 48). Regions in the temporal lobe are associated with auditory hallucinations, thought disorder, and memory dysfunction and are key characteristics of schizophrenia (28). In a previous study, loss of GM in the temporal cortex was negatively correlated with positive symptoms in SCZ (28). Several studies have verified the relationship between frontotemporal functional dysconnectivity and auditory hallucinations during different tasks, suggesting a source-monitoring impairment (56). The parietal cortex has been continuously implicated in the pathophysiology of both adult and pediatric OCD (16, 57). It has been hypothesized that the repetitive behaviors in OCD reflect the problems in set-shifting (58), in which the supramarginal gyrus plays a key role (59). Moreover, the supramarginal gyrus is part of the inferior parietal lobule (IPL). As an important node in both the fronto-parietal network and the default mode network, the IPL is considered to underlie OCD symptoms, such as the inability to eliminate persistent intrusive thoughts (60). In general, GM deficits in the temporal cortex in SCZ patients are associated with positive symptoms, whereas GM deficits in the parietal cortex in OCD patients may be the basis of compulsive behavior. These results tap into the heterogeneity of the two diseases.

Another key observation in this meta-analysis is that GM volume is reduced in the insula among children and adolescents with SCZ. A decrease in GM volume in the insula was found in adults with early-onset schizophrenia (61). A meta-analysis of ROI studies reported medium-sized bilateral GM volume reduction in the insular cortex in schizophrenia, which showed no progression with illness stage (62). Volume reduction in the insular cortex may constitute an important neuropathology in schizophrenia. Significant and widespread dysconnectivity of insula subregions is observed in schizophrenia, which correlates with cognitive function (63). Individuals with schizophrenia have impaired anterior insula-related large-scale brain networks, especially the central executive and default mode networks (64). The disrupted processing in the insula or a network involving the region could contribute to many sensory deficits found in schizophrenia. Failure of this process may lead to internally generated sensory information being attributed to an external source, which in turn contributes to hallucinations (65).

For subcortical regions, we found that the striatal volume was greater in pediatric OCD, consistent with findings of a previous meta-analysis (20). The aforementioned GM alterations in the PFC combined with our findings support theories of prefrontal–striatal circuit abnormalities in pediatric OCD (66). The prefrontal–striatal circuit, the main part of inhibitory control networks, includes several brain regions, such as the ventrolateral prefrontal cortex, anterior insula, supplementary motor area, dACC, and the striatal, thalamic, and dorsolateral prefrontal cortex (67). In OCD, deficits in inhibitory control were thought to underlie the poor control over obsessions and compulsions (68, 69). The prefrontal–striatal circuit is also part of the cortico-striatal-thalamo-cortical (CSTC) pathway. Hyperactivity in the CSTC pathway is thought to underlie the manifestation of OCD (70). Moreover, a meta-analysis of executive function in OCD showed that OCD is associated with broad impairments in executive function (71). Indeed, the impaired executive function in OCD also showed an association with the prefrontal–striatal circuit (55). Meanwhile, GMV in the striatum was greater in OCD than in attention-deficit hyperactivity disorder and autism spectrum disorder (72, 73). In addition, no alterations in striatal volume were found in children and adolescents with SCZ. The results suggest that greater striatal volume may be a disorder-specific neural structural biomarker of pediatric OCD relative to other psychiatric disorders.

Several limitations were noted in the current study. First, the number of studies in our ALE meta-analysis was small. Based on a recent simulation study (74), a recommendation was made to include at least 17–20 experiments in ALE meta-analyses to have sufficient power. However, the present schizophrenia meta-analysis is based on only seven studies, and the meta-analysis on OCD patients contains only nine studies. Therefore, the power can be assumed to be very weak, and the results can only be regarded as indicators for future studies. Second, Müller et al. (75) reported 10 simple rules for neuroimaging meta-analysis. One of the rules is that a cluster-level Family Wise Error (FWE) correction is recommended for ALE meta-analyses, but in the present study, a loose correction (FRD correction, p < 0.001) was used to obtain more results, which made our results preliminary and highly heterogeneous. Third, in line with most voxelwise meta-analyses, our study was based on brain coordinates extracted from published studies rather than raw statistical brain maps. This may also lead to less accurate results (76). Fourth, due to the limited sample size, we did not consider the influencing factors (e.g., treatment, age, and duration of illness). For example, it was consistently reported that both anatomical and functional brain components, including the frontal and temporal lobes, basal ganglia, limbic system and several key components within the default mode network, changed in patients with SCZ after antipsychotic treatment (77). The influence of antidepressants was also reported in OCD (78). However, the influence of medicines on the brains of patients with mental disorders might be an important direction for future studies.

Conclusions

In children and adolescents with SCZ, GM alterations are observed in the PFC, the temporal cortex, and the insula. In children and adolescents with OCD, GM alterations are exhibited in the PFC and striatum. These results suggest that GM abnormalities in the PFC may be a good indicator of the homogeneity between these two disorders. It is suggested that the majority of children and adolescents with SCZ have core defects in the prefrontal-temporal and cortico-insula circuits, whereas those with OCD have core defects in the prefrontal-parietal and the prefrontal-striatal circuits.

Data Availability Statement

The original contributions presented in the study are included in the article/Supplementary Material, further inquiries can be directed to the corresponding authors.

Author Contributions

YC and YiL took the initiative. FWe, JY, LY, FWa, DW, JZ, CY, JC, and YaL finished the study search and data extraction. YiL performed the data analysis. JL finished the draft. All authors contributed to the article and approved the submitted version.

Funding

This work was supported by the National Natural Science Foundation of China (NSFC) under (Grant Nos. 82001445 and 82171538) and the Beijing Natural Science Foundation under (Grant No. 7212035).

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher's Note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Supplementary Material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fpsyt.2022.785547/full#supplementary-material

References 1. Kahn

Sommer

Murray

Meyer-Lindenberg

Weinberger

Cannon

. Schizophrenia. Nat Rev Dis Primers. (2015) 1:15067. 10.1038/nrdp.2015.67

27189524

2. Stein

Costa

DLC

Lochner

Miguel

Reddy

YCJ

Shavitt

. Obsessive-compulsive disorder. Nat Rev Dis Primers. (2019) 5:52. 10.1038/s41572-019-0102-3

31371720

3. Grover

Dua

Chakrabarti

Avasthi

. Obsessive compulsive symptoms/disorder in patients with schizophrenia: prevalence, relationship with other symptom dimensions and impact on functioning. Psychiatry Res. (2017) 250:277–84. 10.1016/j.psychres.2017.01.067

28189922

4. Meier

Petersen

Pedersen

Arendt

Nielsen

Mattheisen

. Obsessive-compulsive disorder as a risk factor for schizophrenia: a nationwide study. JAMA Psychiatry. (2014) 71:1215–21. 10.1001/jamapsychiatry.2014.1011

25188738

5. Cheng

Chen

Yang

Chen

Lee

. Risk of schizophrenia among people with obsessive-compulsive disorder: a nationwide population-based cohort study. Schizophr Res. (2019) 209:58–63. 10.1016/j.schres.2019.05.024

31133461

6. Poyurovsky

Zohar

Glick

Koran

Weizman

Tandon

. Obsessive-compulsive symptoms in schizophrenia: implications for future psychiatric classifications. Compr Psychiatry. (2012) 53:480–3. 10.1016/j.comppsych.2011.08.009

22036006

7. Zarrei

Burton

Engchuan

Young

Higginbotham

MacDonald

. A large data resource of genomic copy number variation across neurodevelopmental disorders. NPJ Genom Med. (2019) 4:26. 10.1038/s41525-019-0098-3

31602316

8. Gogtay

Rapoport

. Childhood-onset schizophrenia: insights from neuroimaging studies. J Am Acad Child Adolesc Psychiatry. (2008) 47:1120–4. 10.1097/CHI.0b013e31817eed7a

26234702

9. MacMaster

O'Neill

Rosenberg

. Brain imaging in pediatric obsessive-compulsive disorder. J Am Acad Child Adolesc Psychiatry. (2008) 47:1262–72. 10.1097/CHI.0b013e318185d2be

18827717

10. Zhang

Jing

Liao

Jiang

Yan

. Abnormal gray matter volume and regional homogeneity of resting fMRI in patients with schizophrenia and obsessive-compulsive disorder. Chin Mental Health J. (2017) 31:768–74. 10.3969/j.issn.1000-6729.2017.10.004 11. Wang

Zou

Xie

Yang

Zhu

Cheung

EFC

. Altered grey matter volume and cortical thickness in patients with schizo-obsessive comorbidity. Psychiatry Res Neuroimaging. (2018) 276:65-72. 10.1016/j.pscychresns.2018.03.009

29628272

12. Goodkind

Eickhoff

Oathes

Jiang

Chang

Jones-Hagata

. Identification of a common neurobiological substrate for mental illness. JAMA Psychiatry. (2015) 72:305–15. 10.1001/jamapsychiatry.2014.2206

25651064

13. Opel

Goltermann

Hermesdorf

Berger

Baune

Dannlowski

. Cross-disorder analysis of brain structural abnormalities in six major psychiatric disorders: a secondary analysis of mega- and meta-analytical findings from the ENIGMA Consortium. Biol Psychiatry. (2020) 88:678–86. 10.1016/j.biopsych.2020.04.027

32646651

14. Piras

Chiapponi

Girardi

Caltagirone

Spalletta

. Widespread structural brain changes in OCD: a systematic review of voxel-based morphometry studies. Cortex. (2015) 62:89–108

10.1016/j.cortex.2013.01.016

23582297

15. Boedhoe

PSW

Heymans

Schmaal

Abe

Alonso

Ameis

. An empirical comparison of meta- and mega-analysis with data from the ENIGMA Obsessive-Compulsive Disorder Working Group. Front Neuroinform. (2018) 12:102. 10.3389/fninf.2018.00102

30670959

16. Boedhoe

PSW

Schmaal

Abe

Alonso

Ameis

Anticevic

. Cortical abnormalities associated with pediatric and adult obsessive-compulsive disorder: findings from the ENIGMA Obsessive-Compulsive Disorder Working Group. Am J Psychiatry. (2018) 175:453–62. 10.1176/appi.ajp.2017.17050485

29377733

17. White

Langen

Schmidt

Hough

James

. Comparative neuropsychiatry: white matter abnormalities in children and adolescents with schizophrenia, bipolar affective disorder, and obsessive-compulsive disorder. Eur Psychiatry. (2015) 30:205–13. 10.1016/j.eurpsy.2014.10.003

25498242

18. Brent

Thermenos

Keshavan

Seidman

. Gray matter alterations in schizophrenia high-risk youth and early-onset schizophrenia. Child Adolesc Psychiatr Clin N Am. (2013) 22:689–714. 10.1016/j.chc.2013.06.003

24012081

19. Ordonez

Sastry

Gogtay

. Functional and clinical insights from neuroimaging studies in childhood-onset schizophrenia. CNS Spectr. (2015) 20:442–50. 10.1017/S1092852915000437

26234702

20. Hu

Chen

Zhou

Zhang

. Meta-analytic investigations of common and distinct grey matter alterations in youths and adults with obsessive-compulsive disorder. Neurosci Biobehav Rev. (2017) 78:91–103. 10.1016/j.neubiorev.2017.04.012

28442404

21. Eickhoff

Laird

Grefkes

Wang

Zilles

Fox

. Coordinate-based activation likelihood estimation meta-analysis of neuroimaging data: a random-effects approach based on empirical estimates of spatial uncertainty. Hum Brain Map. (2009) 30:2907–26. 10.1002/hbm.20718

19172646

22. Lancaster

Tordesillas-Gutierrez

Martinez

Salinas

Evans

Zilles

. Bias between MNI and Talairach coordinates analyzed using the ICBM-152 brain template. Hum Brain Mapp. (2007) 28:1194–205. 10.1002/hbm.20345

17266101

23. Wen

Wang

Yao

Liu

. Abnormality of subcortical volume and resting functional connectivity in adolescents with early-onset and prodromal schizophrenia. J Psychiatr Res. (2021) 140:282–8. 10.1016/j.jpsychires.2021.05.052

34126421

24. Gao

Guo

Xia

. [Brain gray matter volume alterations and cognitive function in first-episode childhood-and adolescence-onset schizophrenia]. Zhonghua Yi Xue Za Zhi. (2019) 99:3581–86. 10.3760/cma.j.issn.0376-2491.2019.45.010

27577221

25. Zhang

Wang

Deng

Zhao

. Differential cortical gray matter deficits in adolescent- and adult-onset first-episode treatment-naive patients with schizophrenia. Sci Rep. (2017) 7:10267. 10.1038/s41598-017-10688-1

28860557

26. Castro-Fornieles

Bargalló

Calvo

Arango

Baeza

Gonzalez-Pinto

. Gray matter changes and cognitive predictors of 2-year follow-up abnormalities in early-onset first-episode psychosis. Eur Child Adolesc Psychiatry. (2017) 27:113–26. 10.1007/s00787-017-1013-z

28707138

27. Zhang

Zheng

Fan

Guo

Yang

. Dysfunctional resting-state connectivities of brain regions with structural deficits in drug-naive first-episode schizophrenia adolescents. Schizophr Res. (2015) 168:353–9. 10.1016/j.schres.2015.07.031

26281967

28. Tang

Liao

Zhou

Tan

Liu

Wang

. Decrease in temporal gyrus gray matter volume in first-episode, early onset schizophrenia: an MRI study. PLoS ONE. (2012) 7:e40247. 10.1371/journal.pone.0040247

22802957

29. James

Hough

James

Winmill

Burge

Nijhawan

. Greater white and grey matter changes associated with early cannabis use in adolescent-onset schizophrenia (AOS). Schizophr Res. (2011) 128:91–7. 10.1016/j.schres.2011.02.014

21388791

30. Yoshihara

Sugihara

Matsumoto

Suckling

Nishimura

Toyoda

. Voxel-based structural magnetic resonance imaging (MRI) study of patients with early onset schizophrenia. Ann Gen Psychiatry. (2008) 7:25. 10.1186/1744-859X-7-25

19102744

31. Janssen

Reig

Parellada

Moreno

Graell

Fraguas

. Regional gray matter volume deficits in adolescents with first-episode psychosis. J Am Acad Child Adolesc Psychiatry. (2008) 47:1311–20. 10.1097/CHI.0b013e318184ff48

18827723

32. Douaud

Smith

Jenkinson

Behrens

Johansen-Berg

Vickers

. Anatomically related grey and white matter abnormalities in adolescent-onset schizophrenia. Brain. (2007) 130:2375–86. 10.1093/brain/awm184

17698497

33. Pagsberg

Baaré

Raabjerg Christensen

Fagerlund

Hansen

Labianca

. Structural brain abnormalities in early onset first-episode psychosis. J Neural Transm. (2007) 114:489–98. 10.1007/s00702-006-0573-8

17024324

34. Cheng

Cai

Wang

Lei

Guo

Yang

. Brain gray matter abnormalities in first-episode, treatment-naive children with obsessive-compulsive disorder. Front Behav Neurosci. (2016) 10:141. 10.3389/fnbeh.2016.00141

27445736

35. Jayarajan

Agarwal

Viswanath

Kalmady

Venkatasubramanian

Srinath

. A voxel based morphometry study of brain gray matter volumes in juvenile obsessive compulsive disorder. J Can Acad Child Adolesc Psychiatry. (2015) 24:84–91.26379719 36. Lázaro

Ortiz

Calvo

Ortiz

Moreno

Morer

. (2014). White matter structural alterations in pediatric obsessive–compulsive disorder: relation to symptom dimensions. Prog Neuropsychopharmacol Biol Psychiatry. (2014) 54:249–58. 10.1016/j.pnpbp.2014.06.009

24977330

37. Huyser

van den Heuvel

Wolters

de Haan

Boer

Veltman

. Increased orbital frontal gray matter volume after cognitive behavioural therapy in paediatric obsessive compulsive disorder. World J Biol Psychiatry. (2013) 14:319–31. 10.3109/15622975.2012.674215

22746998

38. Lázaro

Castro-Fornieles

Cullell

Andrés

Falcón

Calvo

. A voxel-based morphometric MRI study of stabilized obsessive-compulsive adolescent patients. Prog Neuropsychopharmacol Biol Psychiatry. (2011) 35:1863–9. 10.1016/j.pnpbp.07,016.21840363 39. Zarei

Mataix-Cols

Heyman

Hough

Doherty

Burge L et

. Changes in gray matter volume and white matter microstructure in adolescents with obsessive-compulsive disorder. Biol Psychiatry. (2011) 70:1083–90. 10.1016/j.biopsych.2011.06.032

21903200

40. Britton

Rauch

Rosso

Killgore

Price

Ragan

. Cognitive inflexibility and frontal-cortical activation in pediatric obsessive-compulsive disorder. J Am Acad Child Adolesc Psychiatry. (2010) 49:944–53. 10.1016/j.jaac.2010.05.006

20732630

41. Lázaro

Bargalló

Castro-Fornieles

Falcón

Andrés

Calvo

. Brain changes in children and adolescents with obsessive-compulsive disorder before and after treatment: a voxel-based morphometric MRI study. Psychiatry Res. (2009) 172:140–6. 10.1016/j.pscychresns.2008.12.007

19321314

42. Szeszko

Christian

Macmaster

Lencz

Mirza

Taormina

. Gray matter structural alterations in psychotropic drug-naive pediatric obsessive-compulsive disorder: an optimized voxel-based morphometry study. Am J Psychiatry. (2008) 165:1299–307. 10.1176/appi.ajp.2008.08010033

18413702

43. Gilbert

Keshavan

Diwadkar

Nutche

Macmaster

Easter PC et

. Gray matter differences between pediatric obsessive-compulsive disorder patients and high-risk siblings: a preliminary voxel-based morphometry study. Neurosci Lett. (2008) 435:45–50. 10.1016/j.neulet.2008.02.011

18314272

44. Carmona

Bassas

Rovira

Gispert

Soliva

Prado

. Pediatric OCD structural brain deficits in conflict monitoring circuits: a voxel-based morphometry study. Neurosci Lett. (2007) 421:218–23. 10.1016/j.neulet.2007.05.047

17573192

45. El-Sayed

Steen

Poe

Bethea

Gerig

Lieberman

. Brain volumes in psychotic youth with schizophrenia and mood disorders. J Psychiatry Neurosci. (2010) 35:229–36. 10.1503/jpn.090051

20569649

46. Reig

Parellada

Castro-Fornieles

Janssen

Moreno

Baeza

. Multicenter study of brain volume abnormalities in children and adolescent-onset psychosis. Schizophr Bull. (2011) 37:1270–80. 10.1093/schbul/sbq044

20478821

47. Gogtay

Weisinger

Bakalar

Stidd

Fernandez de la Vega

Miller

. Psychotic symptoms and gray matter deficits in clinical pediatric populations. Schizophr Res. (2012) 140:149–54. 10.1016/j.schres.07,006.22835806 48. Thompson

Vidal

Giedd

Gochman

Blumenthal

Nicolson

. Mapping adolescent brain change reveals dynamic wave of accelerated gray matter loss in very early-onset schizophrenia. Proc Natl Acad Sci USA. (2001) 98:11650–5. 10.1073/pnas.201243998

11573002

49. Fraguas

Diaz-Caneja

Pina-Camacho

Janssen

Arango

. Progressive brain changes in children and adolescents with early-onset psychosis: a meta-analysis of longitudinal MRI studies. Schizophr Res. (2016) 173:132–9. 10.1016/j.schres.2014.12.022

25556081

50. van Erp

TGM

Walton

Hibar

Schmaal

Jiang

Glahn

. Cortical brain abnormalities in 4474 individuals with schizophrenia and 5098 control subjects via the Enhancing Neuro Imaging Genetics Through Meta Analysis (ENIGMA) Consortium. Biol Psychiatry. (2018) 84:644–54. 10.1016/j.biopsych.2018.04.023

29960671

51. Chen

Silk

Seal

Dally

Vance

. Widespread decreased grey and white matter in paediatric obsessive-compulsive disorder (OCD): a voxel-based morphometric MRI study. Psychiatry Res. (2013) 213:11–7. 10.1016/j.pscychresns.2013.02.003

23701704

52. Yun

Boedhoe

PSW

Vriend

Jahanshad

Abe

Ameis

. Brain structural covariance networks in obsessive-compulsive disorder: a graph analysis from the ENIGMA Consortium. Brain. (2020) 143:684–700. 10.1093/brain/awaa001

32040561

53. Szczepanski

Knight

. (2014). Insights into human behavior from lesions to the prefrontal cortex. Neuron. (2014) 83:1002–18. 10.1016/j.neuron.2014.08.011

25175878

54. Zhou

Fan

Qiu

Jiang

. Prefrontal cortex and the dysconnectivity hypothesis of schizophrenia. Neurosci Bull. (2015) 31:207–19. 10.1007/s12264-014-1502-8

25761914

55. Ahmari

Rauch

. The prefrontal cortex and OCD. Neuropsychopharmacology. (2021) 47:211–224. 10.1038/s41386-021-01130-2

34400778

56. Hoffman

Hampson

. Functional connectivity studies of patients with auditory verbal hallucinations. Front Hum Neurosci. (2011) 6:6. 10.3389/fnhum.2012.00006

22375109

57. Fallucca

MacMaster

Haddad

Easter

Dick

May

. Distinguishing between major depressive disorder and obsessive-compulsive disorder in children by measuring regional cortical thickness. Arch Gen Psychiatry. (2011) 68:527–33. 10.1001/archgenpsychiatry.2011.36

21536980

58. Benzina

Mallet

Burguiere

N'Diaye

Pelissolo

. Cognitive dysfunction in obsessive-compulsive disorder. Curr Psychiatry Rep. (2016) 18:80. 10.1007/s11920-016-0720-3

27423459

59. Perianez

Maestu

Barcelo

Fernandez

Amo

Ortiz Alonso

. Spatiotemporal brain dynamics during preparatory set shifting: MEG evidence. Neuroimage. (2004) 21:687–95. 10.1016/j.neuroimage.2003.10.008

14980570

60. Stern

Fitzgerald

Welsh

Abelson

Taylor

. Resting-state functional connectivity between fronto-parietal and default mode networks in obsessive-compulsive disorder. PLoS ONE. (2012) 7:e36356. 10.1371/journal.pone.0036356

22570705

61. Egashira

Matsuo

Mihara

Nakano

Nakashima

Watanuki

. Different and shared brain volume abnormalities in late- and early-onset schizophrenia. Neuropsychobiology. (2014) 70:142–51. 10.1159/000364827

25358262

62. Shepherd

Matheson

Laurens

Carr

Green

. (2012). Systematic meta-analysis of insula volume in schizophrenia. Biol Psychiatry. (2012) 72:775–84. 10.1016/j.biopsych.2012.04.020

22621997

63. Sheffield

Rogers

Blackford

Heckers

Woodward

. Insula functional connectivity in schizophrenia. Schizophr Res. (2020) 220:69–77. 10.1016/j.schres.2020.03.068

32307263

64. Moran

Tagamets

Sampath

O'Donnell

Stein

Kochunov

. Disruption of anterior insula modulation of large-scale brain networks in schizophrenia. Biol Psychiatry. (2013) 74:467–74. 10.1016/j.biopsych.2013.02.029

23623456

65. Wylie

Tregellas

. The role of the insula in schizophrenia. Schizophr Res. (2010) 123:93–104. 10.1016/j.schres.2010.08.027

20832997

66. Bernstein

Mueller

Schreiner

Campbell

Regan

Nelson

. Abnormal striatal resting-state functional connectivity in adolescents with obsessive-compulsive disorder. Psychiatry Res Neuroimaging. (2016) 247:49–56. 10.1016/j.pscychresns.2015.11.002

26674413

67. Cai

Ryali

Chen

Menon

. Dissociable roles of right inferior frontal cortex and anterior insula in inhibitory control: evidence from intrinsic and task-related functional parcellation, connectivity, and response profile analyses across multiple datasets. J Neurosci. (2014) 34:14652–67. 10.1523/JNEUROSCI.3048-14.2014

25355218

68. Fineberg

Chamberlain

Goudriaan

Stein

Vanderschuren

Gillan

. New developments in human neurocognition: clinical, genetic, and brain imaging correlates of impulsivity and compulsivity. CNS Spectr. (2014) 19:69–89. 10.1017/S1092852913000801

24512640

69. van Velzen

Vriend

de Wit

van den Heuvel

. Response inhibition and interference control in obsessive-compulsive spectrum disorders. Front Hum Neurosci. (2014) 8:419. 10.3389/fnhum.2014.00419

24966828

70. Radulescu

Herron

Kennedy

Scimemi

. Global and local excitation and inhibition shape the dynamics of the cortico-striatal-thalamo-cortical pathway. Sci Rep. (2017) 7:7608. 10.1038/s41598-017-07527-8

28790376

71. Snyder

Kaiser

Warren

Heller

. Obsessive-compulsive disorder is associated with broad impairments in executive function: a meta-analysis. Clin Psychol Sci. (2015) 3:301–30. 10.1177/2167702614534210

25755918

72. Norman

Carlisi

Lukito

Hart

Mataix-Cols

Radua

. Structural and functional brain abnormalities in attention-deficit/hyperactivity disorder and obsessive-compulsive disorder. JAMA Psychiatry. (2016) 73:815–25. 10.1001/jamapsychiatry.2016.0700

27276220

73. Carlisi

Norman

Lukito

Radua

Mataix-Cols

Rubia

KJBP

. Comparative multimodal meta-analysis of structural and functional brain abnormalities in autism spectrum disorder and obsessive-compulsive disorder. Biol Psychiatry. (2017) 82:83–102. 10.1016/j.biopsych.2016.10.006

27887721

74. Eickhoff

Nichols

Laird

Hoffstaedter

Amunts

Fox

. Behavior, sensitivity, and power of activation likelihood estimation characterized by massive empirical simulation. Neuroimage. (2016) 137:70–85. 10.1016/j.neuroimage.2016.04.072

27179606

75. Muller

Cieslik

Laird

Fox

Radua

Mataix-Cols

. Ten simple rules for neuroimaging meta-analysis. Neurosci Biobehav Rev. (2018) 84:151–61. 10.1016/j.neubiorev.2017.11.012

29180258

76. Radua

Rubia

Canales-Rodriguez

Pomarol-Clotet

Fusar-Poli

Mataix-Cols

. Anisotropic kernels for coordinate-based meta-analyses of neuroimaging studies. Frontiers Psychiatry. (2014) 5:13. 10.3389/fpsyt.2014.00013

24575054

77. Yang

Tang

Liu

Yao

Sun

. The effects of antipsychotic treatment on the brain of patients with first-episode schizophrenia: a selective review of longitudinal MRI studies. Front Psychiatry. (2021) 12:593703. 10.3389/fpsyt.2021.593703

34248691

78. Hoexter

de Souza Duran

D'Alcante

Dougherty

Shavitt

Lopes

. Gray matter volumes in obsessive-compulsive disorder before and after fluoxetine or cognitive-behavior therapy: a randomized clinical trial. Neuropsychopharmacology. (2012) 37:734–45. 10.1038/npp.2011.250

22030709