Hostname: page-component-cd9895bd7-jkksz Total loading time: 0 Render date: 2024-12-26T15:55:35.492Z Has data issue: false hasContentIssue false

Neuronal network mechanisms associated with depressive symptom improvement following electroconvulsive therapy

Published online by Cambridge University Press:  01 June 2020

Akihiro Takamiya
Affiliation:
Department of Neuropsychiatry, Keio University School of Medicine, Tokyo160-8582, Japan Center for Psychiatry and Behavioral Science, Tokyo193-8505, Japan
Taishiro Kishimoto*
Affiliation:
Department of Neuropsychiatry, Keio University School of Medicine, Tokyo160-8582, Japan
Jinichi Hirano
Affiliation:
Department of Neuropsychiatry, Keio University School of Medicine, Tokyo160-8582, Japan
Shiro Nishikata
Affiliation:
Center for Psychiatry and Behavioral Science, Tokyo193-8505, Japan
Kyosuke Sawada
Affiliation:
Department of Neuropsychiatry, Keio University School of Medicine, Tokyo160-8582, Japan
Shunya Kurokawa
Affiliation:
Department of Neuropsychiatry, Keio University School of Medicine, Tokyo160-8582, Japan
Bun Yamagata
Affiliation:
Department of Neuropsychiatry, Keio University School of Medicine, Tokyo160-8582, Japan
Toshiaki Kikuchi
Affiliation:
Department of Neuropsychiatry, Keio University School of Medicine, Tokyo160-8582, Japan
Masaru Mimura
Affiliation:
Department of Neuropsychiatry, Keio University School of Medicine, Tokyo160-8582, Japan
*
Author for correspondence: Taishiro Kishimoto, E-mail: tkishimoto@keio.jp
Rights & Permissions [Opens in a new window]

Abstract

Background

Electroconvulsive therapy (ECT) is the most effective antidepressant treatment for severe depression. Although recent structural magnetic resonance imaging (MRI) studies have consistently reported ECT-induced hippocampal volume increases, most studies did not find the association of the hippocampal volume changes with clinical improvement. To understand the underlying mechanisms of ECT action, we aimed to identify the longitudinal effects of ECT on hippocampal functional connectivity (FC) and their associations with clinical improvement.

Methods

Resting-state functional MRI was acquired before and after bilateral ECT in 27 depressed individuals. A priori hippocampal seed-based FC analysis and a data-driven multivoxel pattern analysis (MVPA) were conducted to investigate FC changes associated with clinical improvement. The statistical threshold was set at cluster-level false discovery rate-corrected p < 0.05.

Results

Depressive symptom improvement after ECT was positively associated with the change in the right hippocampus-ventromedial prefrontal cortex FC, and negatively associated with the right hippocampus-superior frontal gyrus FC. MVPA confirmed the results of hippocampal seed-based analyses and identified the following additional clusters associated with clinical improvement following ECT: the thalamus, the sensorimotor cortex, and the precuneus.

Conclusions

ECT-induced change in the right frontotemporal connectivity and thalamocortical connectivity, and changes in the nodes of the default mode network were associated with clinical improvement. Modulation of these networks may explain the underlying mechanisms by which ECT exert its potent and rapid antidepressant effect.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2020. Published by Cambridge University Press

Introduction

Neuroimaging studies have revealed that neuronal network disorganization is related to various depressive symptoms (Northoff, Reference Northoff2016), supporting the notion of depression as a neuronal network disorder (Mayberg, Reference Mayberg2009; Price & Drevets, Reference Price and Drevets2010). Indeed, abnormal resting-state functional connectivity (FC) among certain brain regions has been reported in depressed individuals: those brain regions include the subcallosal cingulate cortex (SCC), thalamus, medial prefrontal cortex (MPFC), orbitofrontal cortex (OFC), medial temporal lobe (MTL), and precuneus (Cheng et al., Reference Cheng, Rolls, Qiu, Liu, Tang, Huang and Feng2016; Greicius et al., Reference Greicius, Flores, Menon, Glover, Solvason, Kenna and Schatzberg2007; Kaiser, Andrews-Hanna, Wager, & Pizzagalli, Reference Kaiser, Andrews-Hanna, Wager and Pizzagalli2015). Antidepressant medications (Meyer et al., Reference Meyer, Rabl, Huemer, Bartova, Kalcher, Provenzano and Pezawas2019; Wang et al., Reference Wang, Bernanke, Peterson, McGrath, Stewart, Chen and Posner2019), cognitive behavioral therapy (CBT) (Rubin-Falcone et al., Reference Rubin-Falcone, Weber, Kishon, Ochsner, Delaparte, Doré and Miller2020), and transcranial magnetic stimulation (TMS) (Philip et al., Reference Philip, Barredo, van ‘t Wout-Frank, Tyrka, Price and Carpenter2018) had various effects on FC among distributed neuronal networks. Among several antidepressant treatments, electroconvulsive therapy (ECT) is the most effective and rapidly acting treatment (Kellner et al., Reference Kellner, Greenberg, Murrough, Bryson, Briggs and Pasculli2012; Spaans et al., Reference Spaans, Sienaert, Bouckaert, Van Den Berg, Verwijk, Kho and Kok2015). Although the underlying mechanisms of ECT action are still unclear, studying the mechanisms by which ECT exerts its potent and rapid antidepressant effect, as well as its cognitive side effect, could advance our ability to develop precisely targeted antidepressant treatments that are fast-acting and effective with less side effects (McMullen & Lisanby, Reference McMullen and Lisanby2019).

One of the most consistent brain regions that have been reported in ECT literature so far is the hippocampus. A recent meta-analysis (Takamiya et al., Reference Takamiya, Chung, Liang, Graff-Guerrero, Mimura and Kishimoto2018) and mega-analysis (Oltedal et al., Reference Oltedal, Narr, Abbott, Anand, Argyelan, Bartsch and Dale2018) showed ECT-related hippocampal volume increase. However, the clinical relevance of this hippocampal volume increase is unclear. The degree of the increased volume of the whole hippocampus did not correlate with improvement of depressive symptoms (Oltedal et al., Reference Oltedal, Narr, Abbott, Anand, Argyelan, Bartsch and Dale2018; Sartorius et al., Reference Sartorius, Demirakca, Böhringer, Clemm von Hohenberg, Aksay, Bumb and Ende2019; Takamiya et al., Reference Takamiya, Chung, Liang, Graff-Guerrero, Mimura and Kishimoto2018), whereas volume changes in a specific hippocampal subfield (e.g. dentate gyrus) correlated with clinical improvement (Nuninga et al., Reference Nuninga, Mandl, Boks, Bakker, Somers, Heringa and Sommer2019; Takamiya et al., Reference Takamiya, Plitman, Chung, Chakravarty, Graff-Guerrero, Mimura and Kishimoto2019a, Reference Takamiya, Nuninga, Mandl, Sommer, Mimura and Kishimoto2019b). Similar to this evidence, the relationship between hippocampal volume change and cognitive function is also inconsistent (Abbott et al., Reference Abbott, Jones, Lemke, Gallegos, McClintock, Mayer and Calhoun2014; Nordanskog, Larsson, Larsson, & Johanson, Reference Nordanskog, Larsson, Larsson and Johanson2014; Van Oostrom et al., Reference Van Oostrom, Van Eijndhoven, Butterbrod, Van Beek, Janzing, Donders and Tendolkar2018).

Since the hippocampus has direct connections with several brain regions implicated in depression, such as the amygdala and ventromedial prefrontal cortex (vmPFC) (Poppenk, Evensmoen, Moscovitch, & Nadel, Reference Poppenk, Evensmoen, Moscovitch and Nadel2013), investigating the effect of ECT on the hippocampal network may be beneficial. Moreover, preclinical studies have shown that electroconvulsive stimulation (ECS), an animal model of ECT, induced synaptogenesis and regulated key molecules for synaptic plasticity in the hippocampus (Chen, Madsen, Wegener, & Nyengaard, Reference Chen, Madsen, Wegener and Nyengaard2009; Nordgren et al., Reference Nordgren, Karlsson, Svensson, Koczy, Josephson, Olson and Brené2013), which could lead to the reorganization of the human brain's neuronal network. Abbott et al., reported that within a geriatric depressed cohort (mean 65.3 years old) that changes in the right hippocampal FC with the right temporal lobe correlated with symptom improvement, but not with cognitive performance (Abbott et al., Reference Abbott, Jones, Lemke, Gallegos, McClintock, Mayer and Calhoun2014). Bai et al., reported that within a middle-aged cohort (mean 38.0 years old), changes in the left anterior hippocampal FC with the right medial temporal gyrus (MTG) correlated with changes in depressive symptoms, and changes in the left posterior hippocampal FC with the bilateral angular gyrus (AG) correlated with changes in verbal fluency scores (Bai et al., Reference Bai, Wei, Xie, Wang, Wang, Ji and Tian2019). Compared with findings of the effect of ECT on hippocampal volumes, our understanding of the effect of ECT on the hippocampal network is limited.

Based on previous findings regarding the close relationships between depression, the hippocampus, and ECT, we hypothesized that the clinical effect of ECT was mediated by hippocampal network change. To test this hypothesis in the current study, we acquired resting-state functional magnetic resonance imaging (rs-fMRI) data before and after a course of ECT, and we performed hippocampal seed-based FC analyses. We also analyzed whole-brain FC with multivoxel pattern analysis (MVPA) to validate our hypothesis-driven analyses and to investigate FC changes of other brain regions associated with a change in depressive symptoms and change in cognitive function.

Materials and methods

Participants and clinical assessments

This prospective and observational study was approved by the ethics committee of the hospital and performed in accordance with the Declaration of Helsinki. The study was registered at UMIN-CTR (UMIN000019475). Written informed consent was obtained from all participants and/or their surrogate family members. Patients who met the following inclusion criteria were recruited at Komagino Hospital: (1) Diagnostic and Statistical Manual of Mental Disorders, Fourth Edition, Text Revision (DSM-IV-TR) diagnosis of major depressive disorder (MDD), or bipolar (BP) I or II disorder experiencing a major depressive episode (MDE) with melancholic features confirmed by Mini-International Neuropsychiatric Interview; (2) clinical indications for ECT, including pharmacotherapy resistance or requiring a rapid response; (3) age ⩾50 years. The age range was selected based on a previous similar study (Abbott et al., Reference Abbott, Jones, Lemke, Gallegos, McClintock, Mayer and Calhoun2014). Exclusion criteria included: (1) any concurrent Axis I diagnosis other than MDD or BP; (2) concurrent drug or alcohol dependence; (3) a diagnosis of neurological or degenerative disorders (e.g. epilepsy, dementia); (4) unstable or severe medical illness (e.g. myocardial infarction within 1 month); (5) pregnancy; (6) ECT treatment within the last 3 months; (7) patients with mandatory admission by the mayor of the municipality. Healthy controls were recruited from the same area. Subjects in this study partly overlap with a previous report (Takamiya et al., Reference Takamiya, Plitman, Chung, Chakravarty, Graff-Guerrero, Mimura and Kishimoto2019a).

Clinical and MRI assessments were conducted within 1 week before the first ECT (TP1) and after 1 week from the last ECT (TP2). Depressive symptoms were evaluated using the 17-item Hamilton Depression Rating Scale (HAM-D), and remission was defined as HAM-D total score ⩽7. The Mini-Mental State Examination (MMSE) was used to assess global cognitive function.

ECT procedure

Participation in our research did not influence any clinical decision regarding ECT. Informed consent for ECT treatment was obtained independently and prior to recruitment for the study. ECT was provided in clinical settings by each participant's attending psychiatrist. Bilateral ECT was performed using a brief-pulse (0.5 ms) square-wave device (Thymatron system IV device; Somatics, Inc., Lake Bluff, IL, USA). Treatments were performed two to three times a week, in accordance with clinical judgment, and treatments were continued until a plateau was reached and no more improvement was seen in the last two sessions based on clinical assessments. Electroencephalograms (EEG) were recorded to ensure at least 20-s of epileptiform EEG activity after ECT. Propofol (1 mg/kg) was used for general anesthesia, and succinylcholine (0.5–1.0 mg/kg) was used to induce muscle relaxation. Participants continued their psychotropic medications throughout the course of ECT. Incidental use of benzodiazepines or antipsychotics for sleep or anxiety was permitted.

MRI data acquisition

MRI data were acquired using a 3-Tesla GE Signa HDxt scanner at Komagino Hospital. Whole-brain rs-fMRI scans comprising a total of 188 echo-planar imaging volumes (the first eight volumes were dummy scans) were acquired with the following parameters: TR = 2000 ms, TE = 28 ms, matrix = 64 × 64, slice thickness = 3.5 mm, 36 continuous axial slices, and voxel size = 3.75 × 3.75 × 3.5 mm3. During the acquisition, all subjects were instructed to close their eyes and remain awake. Foam padding and earplugs were used to minimize head movement and scanner noise.

High-resolution 3D T1-weighted images were acquired using a fast-spoiled gradient recalled echo sequence (fSPGR: TR = 6.9 ms, TE = 2.9 ms, sagittal orientation, matrix = 256 × 256 mm2, slice thickness = 1.0 mm, voxel size = 0.9 × 0.9 × 1.0 mm3, 174 slices).

Functional image preprocessing

All preprocessing was conducted using the CONN Functional Connectivity Toolbox (https://www.nitrc.org/projects/conn) with the SPM12 (www.fil.ion.ucl.ac.uk/spm). After the removal of the first initial 10 scans (eight dummy scans and two functional scans), default-preprocessing pipeline implemented in CONN was used.

The preprocessing pipeline included realignment and unwarping, slice-timing correction, normalization into Montreal Neurological Institute (MNI) space, and smoothing (8-mm Gaussian kernel). To minimize the impact of head motion on estimated FC, the following possible confounders were removed before computing connectivity measures: BOLD signals from white matter (WM) and cerebrospinal fluid (CSF), and motion parameters (realignment and scrubbing parameters). The anatomical component correction (aCompCor) method (Behzadi, Restom, Liau, & Liu, Reference Behzadi, Restom, Liau and Liu2007) was used to identify principal components associated with segmented WM and CSF. The Artifact Rejection Toolbox (ART) outlier detection and scrubbing method were used to regress out motion parameters and to eliminate specific frames with motion outliers. The threshold for outliers was set at global-signal z-value of 3 and subject-motion of 0.5 mm. We excluded the data from subsequent analysis if more than 36 volumes (i.e. 20% of the acquired volumes) were scrubbed (Wang et al., Reference Wang, Bernanke, Peterson, McGrath, Stewart, Chen and Posner2019). The resulting functional images were despiked and band-pass filtered (0.008–0.09 Hz).

FC analysis

Our analyses included the following two approaches: (1) a priori hypothesis testing and (2) data-driven exploratory analysis. Because the effect of ECT on the hippocampus has been consistently reported (Oltedal et al., Reference Oltedal, Narr, Abbott, Anand, Argyelan, Bartsch and Dale2018; Sartorius et al., Reference Sartorius, Demirakca, Böhringer, Clemm von Hohenberg, Aksay, Bumb and Ende2019; Takamiya et al., Reference Takamiya, Chung, Liang, Graff-Guerrero, Mimura and Kishimoto2018), we selected bilateral hippocampal seeds (defined by Harvard-Oxford Atlas implemented in CONN) to examine how FCs in these regions were associated with clinical outcomes following ECT. Whole-brain correlation maps were created by calculating Pearson's correlation coefficients between the extracted mean signal time course from the hippocampal seeds and all other voxels. Subject-level seed maps were converted to Fisher-transformed Z scores to allow for second-level general linear model analyses.

Multivoxel pattern analysis (MVPA) is a whole-brain connectomic approach and it is used to replicate hypothesis-driven seed-based analyses, and to conduct whole-brain voxel-wise resting-state FC analysis (Philip et al., Reference Philip, Barredo, van ‘t Wout-Frank, Tyrka, Price and Carpenter2018; Wang et al., Reference Wang, Bernanke, Peterson, McGrath, Stewart, Chen and Posner2019; Whitfield-Gabrieli et al., Reference Whitfield-Gabrieli, Ghosh, Nieto-Castanon, Saygin, Doehrmann, Chai and Gabrieli2016). For all voxels in each subject and session, MVPA can create the pairwise connectivity pattern between each voxel and the rest of the brain. Principal component analysis (PCA) was used to reduce the dimensionality, and five components were kept to maintain an approximate 5:1 ratio between subjects and number of components (Philip et al., Reference Philip, Barredo, van ‘t Wout-Frank, Tyrka, Price and Carpenter2018; Whitfield-Gabrieli et al., Reference Whitfield-Gabrieli, Ghosh, Nieto-Castanon, Saygin, Doehrmann, Chai and Gabrieli2016). Second-level MVPA statistical analysis yields a multivariate pattern of voxel clusters showing connectivity changes associated with clinical improvement after ECT. Because MVPA is an omnibus test, post-hoc analyses are needed to investigate connectivity patterns of each identified cluster. Therefore, the following seed-to-voxel analyses using identified clusters were conducted.

Statistical analysis

Descriptive statistics were used to describe the study participants. Distributions of all variables were inspected using histograms, q-q plots, and Shapiro-Wilk tests. Because percentage changes in HAM-D were negatively skewed, these variables were squared to obtain a normal distribution. Percentage change in MMSE was positively skewed, and these variables were natural log-transformed to obtain a normal distribution.

To identify the FC change associated with the clinical effect of ECT, the second-level analysis was conducted in the CONN toolbox, including seed-to-voxel maps as seeds, TP1 and TP2 as between-conditions contrast, and percentage change in HAM-D as between-subjects contrast. Age and Sex were included as nuisance covariates. Baseline HAM-D scores were also included as an additional covariate to control for the baseline severity.

For MVPA second-level analyses, MVPA components were included as between-measures contrast, TP1 and TP2 as between-conditions contrast, and percentage change in HAM-D as between-subjects contrast. Age, sex, baseline HAM-D scores were included as nuisance covariates. Then, clusters identified at this step were used as seeds in the following seed-to-voxel analyses.

To investigate the association between ECT-related FC changes and global cognitive changes, all analyses were conducted using percentage change in the MMSE before and after ECT instead of the percentage change in the HAM-D. R ver 3.4.3 was used for statistical analysis except for above-mentioned seed-to-voxel and MVPA analyses. The statistical threshold for voxel-wise whole-brain analyses was set at cluster-level false discovery rate (FDR)-corrected p < 0.05 with a voxel height of p < 0.001. Mango (http://ric.uthscsa.edu/mango/mango.html) was used to show imaging results.

Results

Clinical demographics

Twenty-seven depressed individuals (67.5 ± 8.1 years old; 19 female) participated in the study (Table 1). ECT significantly improved depressive symptoms (HAM-D = 32.0 ± 6.6 at TP1; HAM-D = 6.0 ± 5.3 at TP2) (Paired t test: t = 16.0, df = 26, p < 0.001), and global cognitive function (MMSE = 26.4 ± 3.4 at TP1; MMSE = 27.7 ± 2.4 at TP2) (Paired t test: t = 2.49, df = 23, p = 0.02). There was no correlation between percentage change in HAM-D scores and percentage change in MMSE scores (r = −0.26, df = 21, p = 0.24). After ECT, 20 participants (74%) met the remission criteria. All but two participants completed rs-fMRI assessments at both TP1 and TP2.

Table 1. Clinical characteristics of participants

Each variable is described as mean (s.d.) for continuous variable.

Duration of the current episode and Illness duration are described as median (IQR) because of non-normal distribution.

Hippocampal seed-to-voxel analysis: correlation with HAM-D changes or MMSE changes

Connectivity changes between the right hippocampus and one cluster located in the vmPFC, including the SCC, MPFC, and OFC, showed a positive correlation with HAM-D changes (Fig. 1; Table 2). Connectivity changes between the right hippocampus and the right superior frontal gyrus (SFG) showed a negative correlation with HAM-D changes. Connectivity changes of the left hippocampal seed did not show any correlations with HAM-D changes. We investigated the effect of head motion, longitudinal volume change with ECT, medication dosage, and each participant's data on our results, but none of them altered the main results (online Supplementary Material).

Fig. 1. Hippocampal connectivity changes with clinical effect of ECT. Changes in depressive symptom following ECT positively correlated with changes in the right hippocampus-vmPFC connectivity, and negatively correlated with changes in the right hippocampus-SFG connectivity. Hip, hippocampus; vmPFC, ventromedial prefrontal cortex; SFG, superior frontal gyrus.

Table 2. Hippocampal connectivity changes associated with changes in clinical scores

Connectivity changes between the left hippocampus and the frontal pole (FP) showed a positive correlation with MMSE changes, whereas no significant clusters were identified in the right hippocampal seed-to-voxel analysis (online Supplementary Table 1).

MVPA analysis: correlation with HAM-D changes or MMSE changes

MVPA identified six clusters associated with HAM-D changes (online Supplementary Table 2; Fig. 2). One of these clusters was the right medial temporal lobe (MTL), including the hippocampus. The following seed-to-voxel analysis using the MVPA-defined right MTL cluster replicated our hypothesis-driven right hippocampal seed-to-voxel analysis (online Supplementary Table 3).

Fig. 2. Results of multi-voxel pattern analysis (MVPA). MVPA identified six brain regions associated with improvement in depressive symptoms.

Results of the other MVPA-identified seeds-to-voxel analyses are described in online Supplementary Table 3. In short, HAM-D changes showed a positive correlation with the following FC changes: (1) right MTL and several other brain regions, including SFG, MPFC, SCC, and precuneus; (2) bilateral precuneus and left occipital cortex. HAM-D changes showed a negative correlation with the following FC changes: (1) left precuneus and left MPFC; (2) right thalamus and left pre/postcentral gyrus; (3) right pre/postcentral gyrus and anterior cingulate gyrus.

MVPA identified two clusters (e.g. brainstem and left precentral gyrus) associated with MMSE changes (online Supplementary Table 2). The results of MVPA did not include the left hippocampus but results of the MVPA-identified seeds-to-voxel analyses included the left hippocampus and left FP (online Supplementary Table 4).

Discussion

The current results show that depressive symptom improvement after ECT was associated with right hippocampal FC changes. MVPA analysis revealed that depressive symptom improvement was associated with FC changes among the MTL, thalamus, sensorimotor cortex, and precuneus. Because ECT is the most effective and rapid antidepressant treatment, understanding of the neuronal networks associated with ECT-related antidepressant effects may lead to the development of precisely targeted antidepressant treatments.

Both hypothesis-driven seed-based analyses and data-driven whole-brain analyses revealed that ECT-induced increased FC between MTL, including the hippocampus, and the vmPFC was associated with depressive symptom improvement. The vmPFC plays a critical role in both positive and negative emotional processing (Myers-Schulz & Koenigs, Reference Myers-Schulz and Koenigs2012). Functional imaging studies have shown that the vmPFC was hyperactive during a depressed state and that recovery from depression was associated with decreased activity in the vmPFC (Koenigs & Grafman, Reference Koenigs and Grafman2009). Direct stimulation of the SCC, a part of the vmPFC, demonstrated an antidepressant effect in treatment-resistant depression (Mayberg et al., Reference Mayberg, Lozano, Voon, McNeely, Seminowicz, Hamani and Kennedy2005). Recent studies emphasized that the antidepressant effect of SCC-DBS was mediated by modulation of certain neuronal networks rather than modulation of SCC itself (Choi, Riva-Posse, Gross, & Mayberg, Reference Choi, Riva-Posse, Gross and Mayberg2015; Riva-Posse et al., Reference Riva-Posse, Choi, Holtzheimer, Crowell, Garlow, Rajendra and Mayberg2018). These studies reported that stimulation of the uncinate fasciculus, which connects vmPFC and MTL, was one of the critical pathways for mediating rapid-onset relief of depression (Choi et al., Reference Choi, Riva-Posse, Gross and Mayberg2015) and achieving a long-term antidepressant effect (Riva-Posse et al., Reference Riva-Posse, Choi, Holtzheimer, Crowell, Garlow, Rajendra and Mayberg2018). The uncinate fasciculus includes bidirectional monosynaptic fibers connecting vmPFC and MTL (Catani, Howard, Pajevic, & Jones, Reference Catani, Howard, Pajevic and Jones2002), and abnormal structural connectivity among these regions was reported in depression (Dalby et al., Reference Dalby, Frandsen, Chakravarty, Ahdidan, Sørensen, Rosenberg and Østergaard2010; Zhang et al., Reference Zhang, Leow, Ajilore, Lamar, Yang, Joseph and Kumar2012). A recent large neuroimaging study revealed that resting-state FC between vmPFC and MTL was abnormally reduced in depression (Cheng et al., Reference Cheng, Rolls, Qiu, Liu, Tang, Huang and Feng2016). Given all this evidence, our results indicate that the modulation of the frontotemporal connectivity, especially the right hippocampus-vmPFC connectivity, may mediate the potent and rapid antidepressant effects of ECT.

MVPA analysis showed that FC change in the thalamus was associated with depressive symptom improvement. The thalamus is a central hub of the cortico-striatal-thalamic-cortical (CSTC) loop, and it plays a critical role in relaying information from peripheral organs to sensory cortices as well as in cortico–cortical interactions (Sherman & Guillery, Reference Sherman and Guillery2017). Structural abnormalities in the thalamus have been shown in late-life depression (Bora, Harrison, Davey, Yücel, & Pantelis, Reference Bora, Harrison, Davey, Yücel and Pantelis2012). Abnormalities in thalamic FC have been identified in depression, including increased thalamic connectivity with SCC (Greicius et al., Reference Greicius, Flores, Menon, Glover, Solvason, Kenna and Schatzberg2007), increased thalamocortical connectivity (Cheng et al., Reference Cheng, Rolls, Qiu, Liu, Tang, Huang and Feng2016), and increased thalamo-temporal as well as thalamo-somatosensory connectivity (Brown, Clark, Hassel, MacQueen, & Ramasubbu, Reference Brown, Clark, Hassel, MacQueen and Ramasubbu2017). The thalamus is a critical region for seizure propagation (Blumenfeld et al., Reference Blumenfeld, Varghese, Purcaro, Motelow, Enev, McNally and Spencer2009; Enev et al., Reference Enev, McNally, Varghese, Zubal, Ostroff and Blumenfeld2007), as well as an important region for the underlying mechanisms of ECT action (Farzan, Boutros, Blumberger, & Daskalakis, Reference Farzan, Boutros, Blumberger and Daskalakis2014). Pretreatment smaller thalamic volume and resting-state activity predicted a worse outcome for ECT (Takamiya et al., Reference Takamiya, Kishimoto, Liang, Terasawa, Nishikata, Tarumi and Mimura2019c). Longitudinal changes in the thalamic FC were associated with clinical improvement in depression (Leaver et al., Reference Leaver, Espinoza, Pirnia, Joshi, Woods and Narr2016), and longitudinal cerebral blood flow change in the thalamus and somatosensory cortex were observed only in ECT responders (Leaver et al., Reference Leaver, Vasavada, Joshi, Wade, Woods, Espinoza and Narr2019). A previous positron emission tomography study also reported increased blood flow during and following ECT (Takano et al., Reference Takano, Motohashi, Uema, Ogawa, Ohnishi, Nishikawa and Matsuda2007). Moreover, thalamic FC modulation may be specific to ECT. Previous studies, which utilized MVPA to investigate FC changes associated with improvement of depression before and after TMS or antidepressant medications, reported similar significant brain regions (e.g. right MFG, ACC, and insula), which were also identified in the current study. However, unlike our study, neither of the previous TMS nor antidepressant studies reported the thalamus as a significant brain region (online Supplementary Table 6). The current results support previous findings for the importance of the thalamus as the mechanisms of ECT action.

MVPA analysis also showed that FC change in the precuneus was associated with depressive improvement. The precuneus is a central hub of the posterior default mode network (DMN), which is implicated in self-referential processing (Sheline et al., Reference Sheline, Barch, Price, Rundle, Vaishnavi, Snyder and Raichle2009). A previous meta-analysis revealed that depressed patients showed increased FC within DMN nodes (Kaiser et al., Reference Kaiser, Andrews-Hanna, Wager and Pizzagalli2015). The effect of ECT on DMN has been reported in previous fMRI studies (Abbott et al., Reference Abbott, Lemke, Gopal, Thoma, Bustillo, Calhoun and Turner2013; Mulders et al., Reference Mulders, van Eijndhoven, Pluijmen, Schene, Tendolkar and Beckmann2016; Wang et al., Reference Wang, Wei, Wang, Zhang, Bai, Cheng and Wang2018), although the clinical relevance of these effects was unclear. The current result of the association between clinical improvement and decreased FC within DMN nodes, specifically between posterior DMN and anterior DMN (e.g. decreased precuneus-MPFC connectivity), adds to our understanding of the effect of ECT on DMN.

Some limitations should be acknowledged. First, the sample size was modest, although comparable to or larger than previous ECT imaging studies. Patients who need ECT are the most severe cases (e.g. baseline mean HAM-D score was 32.0 in the study, and most of them had psychotic features) and it may be difficult for them to participate in longitudinal MRI studies. In the current study, however, we confirmed our results by investigating the effect of each individual's data on the results (online Supplementary Material). Second, our cohort continued taking medications, which may affect the results of FC changes. Discontinuation of medications was not ethical given the severity of our cohort. We confirmed that our main results did not change after including medication dosage as covariates in multiple regression analyses (online Supplementary Material). Third, because our cohort includes only elderly depressed patients, it is difficult to generalize our results to non-geriatric patients. In contrast, our cohort includes both patients with MDD and BP, because we focused on longitudinal FC changes associated with improvements in severe melancholic depressive symptoms with ECT based on a dimensional approach. Indeed, there is an argument that identifying the shared neurobiology underlying common symptoms across disease categories may be suitable for personalized treatments (Insel et al., Reference Insel, Cuthbert, Garvey, Heinssen, Pine, Quinn and Wang2010; Nusslock & Alloy, Reference Nusslock and Alloy2017). However, because there is a possibility that a categorical diagnosis may affect the longitudinal effects of ECT on the brain, a future study including a larger cohort is warranted to address this argument. Fourth, MMSE includes multiple cognitive domains, and may not detect subtle cognitive changes induced by ECT (Moirand et al., Reference Moirand, Galvao, Lecompte, Poulet, Haesebaert and Brunelin2018). Therefore, our analysis regarding cognitive change was exploratory, and the results regarding cognitive changes should not be overemphasized. Future studies should focus on change in specific cognitive domains that relate to ECT.

Conclusions

In conclusion, depressive symptom improvement after ECT was associated with a reorganization of the neuronal network, including the hippocampus, thalamus, sensorimotor cortex, and precuneus. Modulation of these networks may be the underlying mechanisms of ECT action. Our results have important implications for developing precisely targeted neuromodulation treatments.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0033291720001518

Acknowledgements

We would like to thank Dr Tamotsu Watanabe, Dr Saeko Kaneko, Dr Takasuke Hayakawa, Dr Ryosuke Tarumi, Dr Genki Imagawa, Dr Takayuki Kakimoto, and Dr Taisuke Yatomi for patient recruitment. We would like to thank Mrs. Kelley Cortright for providing language help for the manuscript. This study is supported by Inokashira Hospital Grants for Psychiatry Research (2016–2017), and Keio University Graduate School Grants for Department of Neuropsychiatry (2017–2018).

Author contributions

AT and TK designed the study. AT recruited the participants with above-mentioned Drs in the acknowledgement. SN acquired all MRI data. AT analysed the data. AT conducted a literature search and wrote the first draft. TK, JH, SN, KS, SK, BY, TK, and MM wrote the final manuscript. All authors contributed to and have approved the final manuscript.

Conflict of interest

None.

Ethical standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008. The study was registered at UMIN-CTR (UMIN000019475). Written informed consent was obtained from all participants and/or their surrogate family members.

References

Abbott, C. C., Jones, T., Lemke, N. T., Gallegos, P., McClintock, S. M., Mayer, A. R., … Calhoun, V. D. (2014). Hippocampal structural and functional changes associated with electroconvulsive therapy response. Translational Psychiatry, 4(11), e483. https://doi.org/10.1038/tp.2014.124.CrossRefGoogle ScholarPubMed
Abbott, C. C., Lemke, N. T., Gopal, S., Thoma, R. J., Bustillo, J., Calhoun, V. D., & Turner, J. A. (2013). Electroconvulsive therapy response in major depressive disorder: A pilot functional network connectivity resting state fMRI investigation. Frontiers in Psychiatry, 4(Mar), 19. https://doi.org/10.3389/fpsyt.2013.00010.CrossRefGoogle ScholarPubMed
Bai, T., Wei, Q., Xie, W., Wang, A., Wang, J., Ji, G. J., … Tian, Y. (2019). Hippocampal-subregion functional alterations associated with antidepressant effects and cognitive impairments of electroconvulsive therapy. Psychological Medicine, 49(8), 13571364. https://doi.org/10.1017/S0033291718002684.CrossRefGoogle ScholarPubMed
Behzadi, Y., Restom, K., Liau, J., & Liu, T. T. (2007). A component based noise correction method (CompCor) for BOLD and perfusion based fMRI. NeuroImage, 37(1), 90101. https://doi.org/10.1016/j.neuroimage.2007.04.042.CrossRefGoogle ScholarPubMed
Blumenfeld, H., Varghese, G. I., Purcaro, M. J., Motelow, J. E., Enev, M., McNally, K. A., … Spencer, S. S. (2009). Cortical and subcortical networks in human secondarily generalized tonic clonic seizures. Brain, 132(4), 9991012. https://doi.org/10.1093/brain/awp028.CrossRefGoogle ScholarPubMed
Bora, E., Harrison, B. J., Davey, C. G., Yücel, M., & Pantelis, C. (2012). Meta-analysis of volumetric abnormalities in cortico-striatal-pallidal- thalamic circuits in major depressive disorder. Psychological Medicine, 42(4), 671681. https://doi.org/10.1017/S0033291711001668.CrossRefGoogle ScholarPubMed
Brown, E. C., Clark, D. L., Hassel, S., MacQueen, G., & Ramasubbu, R. (2017). Thalamocortical connectivity in major depressive disorder. Journal of Affective Disorders, 217(February), 125131. https://doi.org/10.1016/j.jad.2017.04.004.CrossRefGoogle ScholarPubMed
Catani, M., Howard, R. J., Pajevic, S., & Jones, D. K. (2002). Virtual in vivo interactive dissection of white matter fasciculi in the human brain. NeuroImage, 17(1), 7794. https://doi.org/10.1006/nimg.2002.1136.CrossRefGoogle ScholarPubMed
Chen, F., Madsen, T. M., Wegener, G., & Nyengaard, J. R. (2009). Repeated electroconvulsive seizures increase the total number of synapses in adult male rat hippocampus. European Neuropsychopharmacology, 19(5), 329338. https://doi.org/10.1016/j.euroneuro.2008.12.007.CrossRefGoogle ScholarPubMed
Cheng, W., Rolls, E. T., Qiu, J., Liu, W., Tang, Y., Huang, C. C., … Feng, J. (2016). Medial reward and lateral non-reward orbitofrontal cortex circuits change in opposite directions in depression. Brain, 139(12), 32963309. https://doi.org/10.1093/brain/aww255.CrossRefGoogle ScholarPubMed
Choi, K. S., Riva-Posse, P., Gross, R. E., & Mayberg, H. S. (2015). Mapping the “depression switch” during intraoperative testing of subcallosal cingulate deep brain stimulation. JAMA Neurology, 72(11), 12521260. https://doi.org/10.1001/jamaneurol.2015.2564.CrossRefGoogle ScholarPubMed
Dalby, R. B., Frandsen, J., Chakravarty, M. M., Ahdidan, J., Sørensen, L., Rosenberg, R., … Østergaard, L. (2010). Depression severity is correlated to the integrity of white matter fiber tracts in late-onset major depression. Psychiatry Research - Neuroimaging, 184(1), 3848. https://doi.org/10.1016/j.pscychresns.2010.06.008.CrossRefGoogle Scholar
Enev, M., McNally, K. A., Varghese, G., Zubal, I. G., Ostroff, R. B., & Blumenfeld, H. (2007). Imaging onset and propagation of ECT-induced seizures. Epilepsia, 48(2), 238244. https://doi.org/10.1111/j.1528-1167.2007.00919.x.CrossRefGoogle ScholarPubMed
Farzan, F., Boutros, N. N., Blumberger, D. M., & Daskalakis, Z. J. (2014). What does the electroencephalogram tell us about the mechanisms of action of ECT in major depressive disorders? Journal of ECT, 30(2), 98106. https://doi.org/10.1097/YCT.0000000000000144.CrossRefGoogle ScholarPubMed
Greicius, M. D., Flores, B. H., Menon, V., Glover, G. H., Solvason, H. B., Kenna, H., … Schatzberg, A. F. (2007). Resting-State functional connectivity in Major depression: Abnormally increased contributions from subgenual cingulate cortex and thalamus. Biological Psychiatry, 62(5), 429437. https://doi.org/10.1016/j.biopsych.2006.09.020.CrossRefGoogle ScholarPubMed
Insel, T., Cuthbert, B., Garvey, M., Heinssen, R., Pine, D., Quinn, K., … Wang, P. (2010). Research domain criteria (RDoC): Toward a new classification framework for research on mental disorders. American Journal of Psychiatry, 167(7), 748751. https://doi.org/10.1176/appi.ajp.2010.09091379.CrossRefGoogle Scholar
Kaiser, R. H., Andrews-Hanna, J. R., Wager, T. D., & Pizzagalli, D. A. (2015). Large-scale network dysfunction in major depressive disorder: A meta-analysis of resting-state functional connectivity. JAMA Psychiatry, 72(6), 603611. https://doi.org/10.1001/jamapsychiatry.2015.0071.CrossRefGoogle ScholarPubMed
Kellner, C. H., Greenberg, R. M., Murrough, J. W., Bryson, E. O., Briggs, M. C., & Pasculli, R. M. (2012). ECT In treatment-resistant depression. American Journal of Psychiatry, 169(December), 12381244.CrossRefGoogle ScholarPubMed
Koenigs, M., & Grafman, J. (2009). The functional neuroanatomy of depression: Distinct roles for ventromedial and dorsolateral prefrontal cortex. Behavioural Brain Research, 201(2), 239243. https://doi.org/10.1016/j.bbr.2009.03.004.CrossRefGoogle ScholarPubMed
Leaver, A. M., Espinoza, R., Pirnia, T., Joshi, S. H., Woods, R. P., & Narr, K. L. (2016). Modulation of intrinsic brain activity by electroconvulsive therapy in Major depression. Biological Psychiatry: Cognitive Neuroscience and Neuroimaging, 1(1), 7786. https://doi.org/10.1016/j.bpsc.2015.09.001.Google ScholarPubMed
Leaver, A. M., Vasavada, M., Joshi, S. H., Wade, B., Woods, R. P., Espinoza, R., & Narr, K. L. (2019). Mechanisms of antidepressant response to electroconvulsive therapy studied with perfusion magnetic resonance imaging. Biological Psychiatry, 85(6), 466476. https://doi.org/10.1016/j.biopsych.2018.09.021.CrossRefGoogle ScholarPubMed
Mayberg, H. S. (2009). Targeted electrode-based modulation of neural circuits for depression. Journal of Clinical Investigation, 119(4), 717725. https://doi.org/10.1172/JCI38454.CrossRefGoogle ScholarPubMed
Mayberg, H.S., Lozano, A.M., Voon, V., McNeely, H.E., Seminowicz, D., Hamani, C., … Kennedy, S.H. (2005). Deep brain stimulation for treatment-resistant depression. Neuron 45, 651660.CrossRefGoogle ScholarPubMed
McMullen, D. P., & Lisanby, S. H. (2019). Better, faster, safer: Exploring biomarkers of response to transform electroconvulsive therapy. Biological Psychiatry, 85(6), 439440. https://doi.org/10.1016/j.biopsych.2019.01.009.CrossRefGoogle ScholarPubMed
Meyer, B. M., Rabl, U., Huemer, J., Bartova, L., Kalcher, K., Provenzano, J., … Pezawas, L. (2019). Prefrontal networks dynamically related to recovery from major depressive disorder: A longitudinal pharmacological fMRI study. Translational Psychiatry, 9(1), 64. https://doi.org/10.1038/s41398-019-0395-8.CrossRefGoogle ScholarPubMed
Moirand, R., Galvao, F., Lecompte, M., Poulet, E., Haesebaert, F., & Brunelin, J. (2018). Usefulness of the Montreal cognitive assessment (MoCA) to monitor cognitive impairments in depressed patients receiving electroconvulsive therapy. Psychiatry Research, 259(October 2017), 476481. https://doi.org/10.1016/j.psychres.2017.11.022.CrossRefGoogle ScholarPubMed
Mulders, P. C. R., van Eijndhoven, P. F. P., Pluijmen, J., Schene, A. H., Tendolkar, I., & Beckmann, C. F. (2016). Default mode network coherence in treatment-resistant major depressive disorder during electroconvulsive therapy. Journal of Affective Disorders, 205, 130137. https://doi.org/10.1016/j.jad.2016.06.059.CrossRefGoogle ScholarPubMed
Myers-Schulz, B., & Koenigs, M. (2012). Functional anatomy of ventromedial prefrontal cortex: Implications for mood and anxiety disorders. Molecular Psychiatry, 17(2), 132141. https://doi.org/10.1038/mp.2011.88.CrossRefGoogle ScholarPubMed
Nordanskog, P., Larsson, M. R., Larsson, E. M., & Johanson, A. (2014). Hippocampal volume in relation to clinical and cognitive outcome after electroconvulsive therapy in depression. Acta Psychiatrica Scandinavica, 129(4), 303311. https://doi.org/10.1111/acps.12150.CrossRefGoogle ScholarPubMed
Nordgren, M., Karlsson, T., Svensson, M., Koczy, J., Josephson, A., Olson, L., … Brené, S. (2013). Orchestrated regulation of nogo receptors, lotus, AMPA receptors and BDNF in an ECT model suggests opening and closure of a window of synaptic plasticity. PLoS ONE, 8(11), 18. https://doi.org/10.1371/journal.pone.0078778.CrossRefGoogle Scholar
Northoff, G. (2016). Spatiotemporal psychopathology I: No rest for the brain's resting state activity in depression? Spatiotemporal psychopathology of depressive symptoms. Journal of Affective Disorders, 190, 854866. https://doi.org/10.1016/j.jad.2015.05.007.CrossRefGoogle ScholarPubMed
Nuninga, J. O., Mandl, R. C. W., Boks, M. P., Bakker, S., Somers, M., Heringa, S. M., … Sommer, I. E. C. (2019). Volume increase in the dentate gyrus after electroconvulsive therapy in depressed patients as measured with 7 T. Molecular Psychiatry, https://doi.org/10.1038/s41380-019-0392-6.Google Scholar
Nusslock, R., & Alloy, L. B. (2017). Reward processing and mood-related symptoms: An RDoC and translational neuroscience perspective. Journal of Affective Disorders, 216, 316. https://doi.org/10.1016/j.jad.2017.02.001.CrossRefGoogle ScholarPubMed
Oltedal, L., Narr, K. L., Abbott, C., Anand, A., Argyelan, M., Bartsch, H., … Dale, A. M. (2018). Volume of the human hippocampus and clinical response following electroconvulsive therapy. Biological Psychiatry, 84(8), 574581. https://doi.org/10.1016/j.biopsych.2018.05.017.CrossRefGoogle ScholarPubMed
Philip, N. S., Barredo, J., van ‘t Wout-Frank, M., Tyrka, A. R., Price, L. H., & Carpenter, L. L. (2018). Network mechanisms of clinical response to transcranial magnetic stimulation in posttraumatic stress disorder and Major depressive disorder. Biological Psychiatry, 83(3), 263272. https://doi.org/10.1016/j.biopsych.2017.07.021.CrossRefGoogle ScholarPubMed
Poppenk, J., Evensmoen, H. R., Moscovitch, M., & Nadel, L. (2013). Long-axis specialization of the human hippocampus. Trends in Cognitive Sciences, 17(5), 230240. https://doi.org/10.1016/j.tics.2013.03.005.CrossRefGoogle ScholarPubMed
Price, J. L., & Drevets, W. C. (2010). Neurocircuitry of mood disorders. Neuropsychopharmacology: Official Publication of the American College of Neuropsychopharmacology, 35, 192216. https://doi.org/10.1038/npp.2009.104.CrossRefGoogle ScholarPubMed
Riva-Posse, P., Choi, K. S., Holtzheimer, P. E., Crowell, A. L., Garlow, S. J., Rajendra, J. K., … Mayberg, H. S. (2018). A connectomic approach for subcallosal cingulate deep brain stimulation surgery: Prospective targeting in treatment-resistant depression. Molecular Psychiatry, 23, 843849. https://doi.org/10.1038/mp.2017.59.CrossRefGoogle ScholarPubMed
Rubin-Falcone, H., Weber, J., Kishon, R., Ochsner, K., Delaparte, L., Doré, B., … Miller, J. M. (2020). Neural predictors and effects of cognitive behavioral therapy for depression: The role of emotional reactivity and regulation. Psychological Medicine, 50(1), 146160. https://doi.org/10.1017/S0033291718004154.CrossRefGoogle ScholarPubMed
Sartorius, A., Demirakca, T., Böhringer, A., Clemm von Hohenberg, C., Aksay, S. S., Bumb, J. M., … Ende, G. (2019). Electroconvulsive therapy induced gray matter increase is not necessarily correlated with clinical data in depressed patients. Brain Stimulation, 12(2), 335343. https://doi.org/10.1016/j.brs.2018.11.017.CrossRefGoogle Scholar
Sheline, Y. I., Barch, D. M., Price, J. L., Rundle, M. M., Vaishnavi, S. N., Snyder, A. Z., … Raichle, M. E. (2009). The default mode network and self-referential processes in depression. Proceedings of the National Academy of Sciences, 106(6), 19421947. https://doi.org/10.1073/pnas.0812686106.CrossRefGoogle ScholarPubMed
Sherman, S. M., & Guillery, R. W. (2017). Functional organization of thalamocortical relays. Journal of Neurophysiology, 76(3), 13671395. https://doi.org/10.1152/jn.1996.76.3.1367.CrossRefGoogle Scholar
Spaans, H. P., Sienaert, P., Bouckaert, F., Van Den Berg, J. F., Verwijk, E., Kho, K. H., … Kok, R. M. (2015). Speed of remission in elderly patients with depression: Electroconvulsive therapy V. medication. British Journal of Psychiatry, 206(1), 6771. https://doi.org/10.1192/bjp.bp.114.148213.CrossRefGoogle ScholarPubMed
Takamiya, A., Chung, J. K., Liang, K. C., Graff-Guerrero, A., Mimura, M., & Kishimoto, T. (2018). Effect of electroconvulsive therapy on hippocampal and amygdala volumes: Systematic review and meta-analysis. British Journal of Psychiatry, 212(1), 1926. https://doi.org/10.1192/bjp.2017.11.CrossRefGoogle ScholarPubMed
Takamiya, A., Kishimoto, T., Liang, K., Terasawa, Y., Nishikata, S., Tarumi, R., … Mimura, M. (2019c). Thalamic volume, resting-state activity, and their association with the efficacy of electroconvulsive therapy. Journal of Psychiatric Research, 117, 135141. https://doi.org/10.1016/j.jpsychires.2019.08.001.CrossRefGoogle Scholar
Takamiya, A., Nuninga, J.O., Mandl, R.C.W., Sommer, I.E.C., Mimura, M., & Kishimoto, T. (2019b). Volume increase of the dentate gyrus induced by ECT: Shedding light on the clinical relevance of plasticity in the hippocampus. The Journal of ECT 35, e57e58. https://doi.org/10.1097/YCT.0000000000000630.CrossRefGoogle Scholar
Takamiya, A., Plitman, E., Chung, J. K., Chakravarty, M., Graff-Guerrero, A., Mimura, M., & Kishimoto, T. (2019a). Acute and long-term effects of electroconvulsive therapy on human dentate gyrus. Neuropsychopharmacology, 44, 18051811. https://doi.org/10.1038/s41386-019-0312-0.CrossRefGoogle Scholar
Takano, H., Motohashi, N., Uema, T., Ogawa, K., Ohnishi, T., Nishikawa, M., … Matsuda, H. (2007). Changes in regional cerebral blood flow during acute electroconvulsive therapy in patients with depression: Positron emission tomographic study. The British Journal of Psychiatry, 190, 6368. https://doi.org/10.1192/bjp.bp.106.023036.CrossRefGoogle ScholarPubMed
Van Oostrom, I., Van Eijndhoven, P., Butterbrod, E., Van Beek, M. H., Janzing, J., Donders, R., … Tendolkar, I. (2018). Decreased cognitive functioning after electroconvulsive therapy Is related to increased hippocampal volume: Exploring the role of brain plasticity. Journal of ECT, 34(2), 117123. https://doi.org/10.1097/YCT.0000000000000483.CrossRefGoogle ScholarPubMed
Wang, Y., Bernanke, J., Peterson, B.S., McGrath, P., Stewart, J., Chen, Y., … Posner, J. (2019). The association between antidepressant treatment and brain connectivity in two double-blind, placebo-controlled clinical trials: A treatment mechanism study. The Lancet Psychiatry 6(8), 667674. https://doi.org/10.1016/S2215-0366(19)30179-8.CrossRefGoogle ScholarPubMed
Wang, J., Wei, Q., Wang, L., Zhang, H., Bai, T., Cheng, L., … Wang, K. (2018). Functional reorganization of intra- and internetwork connectivity in major depressive disorder after electroconvulsive therapy. Human Brain Mapping, 39(3), 14031411. https://doi.org/10.1002/hbm.23928.CrossRefGoogle ScholarPubMed
Whitfield-Gabrieli, S., Ghosh, S. S., Nieto-Castanon, A., Saygin, Z., Doehrmann, O., Chai, X. J., … Gabrieli, J. D. E. (2016). Brain connectomics predict response to treatment in social anxiety disorder. Molecular Psychiatry, 21(5), 680685. https://doi.org/10.1038/mp.2015.109.CrossRefGoogle ScholarPubMed
Zhang, A., Leow, A., Ajilore, O., Lamar, M., Yang, S., Joseph, J., … Kumar, A. (2012). Quantitative tract-specific measures of uncinate and cingulum in major depression using diffusion tensor imaging. Neuropsychopharmacology, 37(4), 959967. https://doi.org/10.1038/npp.2011.279.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Clinical characteristics of participants

Figure 1

Fig. 1. Hippocampal connectivity changes with clinical effect of ECT. Changes in depressive symptom following ECT positively correlated with changes in the right hippocampus-vmPFC connectivity, and negatively correlated with changes in the right hippocampus-SFG connectivity. Hip, hippocampus; vmPFC, ventromedial prefrontal cortex; SFG, superior frontal gyrus.

Figure 2

Table 2. Hippocampal connectivity changes associated with changes in clinical scores

Figure 3

Fig. 2. Results of multi-voxel pattern analysis (MVPA). MVPA identified six brain regions associated with improvement in depressive symptoms.

Supplementary material: File

Takamiya et al. supplementary material

Takamiya et al. supplementary material

Download Takamiya et al. supplementary material(File)
File 165.5 KB