Trial PaperDepressive DisordersNeuroimaging & Brain MeasuresTreatment-Resistant Depression (TRD)Psilocybin

Psilocybin for treatment-resistant depression: fMRI-measured brain mechanisms

Psilocybin with psychological support produced rapid symptom reductions in treatment‑resistant depression and, on fMRI, elicited post‑treatment decreases in temporal cortex cerebral blood flow including the amygdala (the latter correlating with symptom improvement) alongside increased resting‑state functional connectivity within the default‑mode network. Increased vmPFC–bilateral inferior lateral parietal connectivity and decreased parahippocampal–prefrontal connectivity predicted 5‑week response, prompting the authors to propose a post‑acute “reset” therapeutic mechanism distinct from acute psychedelic effects.

Authors

  • Robin Carhart-Harris
  • David Nutt
  • Leor Roseman

Published

Scientific Reports
individual Study

Abstract

Psilocybin with psychological support is showing promise as a treatment model in psychiatry but its therapeutic mechanisms are poorly understood. Here, cerebral blood flow (CBF) and blood oxygen-level dependent (BOLD) resting-state functional connectivity (RSFC) were measured with functional magnetic resonance imaging (fMRI) before and after treatment with psilocybin (serotonin agonist) for treatment-resistant depression (TRD). Quality pre and post treatment fMRI data were collected from 16 of 19 patients. Decreased depressive symptoms were observed in all 19 patients at 1-week post-treatment and 47% met criteria for response at 5 weeks. Whole-brain analyses revealed post-treatment decreases in CBF in the temporal cortex, including the amygdala. Decreased amygdala CBF correlated with reduced depressive symptoms. Focusing on a priori selected circuitry for RSFC analyses, increased RSFC was observed within the default-mode network (DMN) post-treatment. Increased ventromedial prefrontal cortex-bilateral inferior lateral parietal cortex RSFC was predictive of treatment response at 5-weeks, as was decreased parahippocampal-prefrontal cortex RSFC. These data fill an important knowledge gap regarding the post-treatment brain effects of psilocybin, and are the first in depressed patients. The post-treatment brain changes are different to previously observed acute effects of psilocybin and other ‘psychedelics’ yet were related to clinical outcomes. A ‘reset’ therapeutic mechanism is proposed.

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Research Summary of 'Psilocybin for treatment-resistant depression: fMRI-measured brain mechanisms'

Editorial

βBlossom's Take

This imaging follow-up is useful because it begins to make the post-acute psilocybin response in depression anatomically specific. The pattern of reduced amygdala perfusion, altered temporal cortex blood flow and changed default-mode connectivity gives a plausible mechanistic bridge between symptom change and the broader idea of a post-session reset.

Introduction

Psilocybin, a serotonin 2A receptor agonist and the active prodrug psilocin, is showing clinical promise when administered with preparatory and integrative psychological support, but the neural mechanisms that underlie its antidepressant effects remain poorly understood. Earlier human imaging work has mainly characterised the acute psychedelic state, reporting a more entropic brain configuration with modular disintegration and enhanced global connectivity that correlates with aspects of the subjective experience such as ego-dissolution. Few studies, however, have examined brain function beyond the acute phase (>12 hours) in clinical populations, leaving a gap about post-acute or 'after-glow' changes that might relate to mood improvement and longer-term outcomes. Carhart-Harris and colleagues set out to characterise cerebral blood flow (CBF) and resting-state functional connectivity (RSFC) changes before versus one day after psilocybin treatment in patients with treatment-resistant depression (TRD). Patients received two oral doses (10 mg then 25 mg one week apart) within an open-label clinical protocol. The investigators tested whether post-treatment CBF and BOLD RSFC would be altered relative to baseline and whether such changes would correlate with immediate mood improvements and with clinical response at a 5-week endpoint. A priori regions of interest (ROIs) implicated in depression and its treatment were selected for focussed analyses, and broader network-level assessments of 12 canonical resting-state networks were also performed.

Methods

This was an open-label clinical study of psilocybin for treatment-resistant major depression, conducted under ethical and regulatory approvals in the UK. Nineteen patients underwent pre-treatment and one-day post-treatment fMRI scanning; after quality control, 16 subjects were retained for arterial spin labelling (ASL) CBF analyses and 15 for BOLD RSFC analyses. The primary clinical outcome measure was the 16-item Quick Inventory of Depressive Symptoms (QIDS-SR16); a revised 24-hour version of the QIDS-SR16 was used to index state mood at the post-treatment scan. Clinical relationships were assessed both contemporaneously (Pearson's r for change from pre-treatment to scan 2) and for longer-term outcome (patients were split into responders and non-responders at 5 weeks, defined as >50% reduction in QIDS-SR16, and one-tailed t-tests were used for imaging comparisons given directional hypotheses). Imaging acquisition used a 3T Siemens Tim Trio scanner with a 12-channel head coil. CBF was measured with ASL and functional connectivity with BOLD resting-state scans. Four analysis packages were used (FSL, AFNI, Freesurfer, ANTS) and preprocessing included motion correction, scrubbing using a frame-wise displacement (FD) threshold of 0.5 with exclusion if >20% volumes were scrubbed, spatial normalisation to 2 mm MNI space, band-pass filtering (0.01–0.08 Hz), and regression of nine nuisance regressors (six motion and three anatomical regressors: ventricles, draining veins, and local white matter). Seed-based RSFC analyses used four a priori seeds: bilateral parahippocampus (PH), ventromedial prefrontal cortex (vmPFC), subgenual anterior cingulate cortex (sgACC), and bilateral amygdala; seeds were derived from standard atlases or prior work. Subject-level GLMs were run and higher-level comparisons used mixed-effects (FLAME 1 + 2), cluster-corrected (z > 2.3, p < 0.05). Network-level analyses employed 12 canonical resting-state networks (RSNs) identified from independent component analysis on Human Connectome Project data. Within-network integrity was quantified by dual regression to derive mean parameter-estimate (PE) values per RSN and paired t-tests compared pre- and post-treatment conditions; Bonferroni correction was applied across 11 RSNs (DMN was treated as a priori and not corrected). Between-network connectivity was computed as symmetric 12 × 12 PE matrices using GLMs (rather than Pearson correlations) and paired permutation tests (5000 permutations) tested condition differences. An exploratory analysis also examined whether acute-session ratings of 'peak' or 'mystical-type' experience covaried with post-acute RSFC changes.

Results

After data quality exclusions, 16 patients contributed to ASL CBF analyses (mean age 42.8 ± 10.1 years, 4 females) and 15 to BOLD RSFC analyses (mean age 42.8 ± 10.5 years, 4 females). Treatment with psilocybin was associated with rapid and statistically significant reductions in depressive symptoms. For the ASL sample, mean QIDS-SR16 dropped from 16.9 ± 5.1 (week prior to pre-treatment scan) to 8.8 ± 6.2 at the day of the post-treatment scan (change = -8.1 ± 6, t = -5.2, p < 0.001). From screening baseline (18.9 ± 3) to 5 weeks post-treatment the mean score fell to 10.9 ± 4.8 (change = -8 ± 5.1, t = -6.3, p < 0.001). In the BOLD sample, mean change values were -7.3 ± 5.3 (scan 1 to scan 2) and -8.2 ± 5.2 (baseline to 5 weeks), both highly significant (p < 0.001). Across the full cohort, all 19 patients showed some reduction in depressive symptoms at 1 week, with 12 meeting the response criterion, and at 5 weeks 47% met criteria for response. Whole-brain ASL contrasts revealed only decreases in absolute CBF post-treatment; significant clusters included left Heschl's gyrus, left precentral gyrus, left planum temporale, left superior temporal gyrus, left amygdala, right supramarginal gyrus and right parietal operculum. A decrease in amygdala CBF correlated with contemporaneous reductions in depressive symptoms between pre-treatment and one-day post (r = 0.59, p = 0.01). When responders and non-responders at 5 weeks were compared for CBF change, no significant group difference was detected (t = 0.11; p = 0.46). Seed-based RSFC analyses produced several regionally specific effects. Increased sgACC–posterior cingulate cortex/precuneus (PCC) RSFC was seen post-treatment, but this change did not correlate with symptom reductions at scan 2 nor predict 5-week response. Increased vmPFC–bilateral inferior-lateral parietal cortex (ilPC) RSFC was observed post-treatment; this increase did not correlate with immediate symptom change but was greater in responders at 5 weeks (t = 2.1; p = 0.03). Decreased parahippocampus (PH)–prefrontal cortex (PFC) RSFC was also observed post-treatment and was associated with treatment response at 5 weeks (t = -1.9; p = 0.04), though it did not correlate with immediate symptom change. Amygdala RSFC showed no significant post-treatment change. Network-level results indicated increases in within-network RSFC for the default-mode network (DMN) (t = 2.7, p = 0.018), dorsal attention network (DAN) (t = 2.2, p = 0.042) and posterior opercular network (POP) (t = 2.7, p = 0.016) after treatment; however, these effects did not survive Bonferroni correction (revised α = 0.0042) and did not correlate with clinical outcomes. Between-network analyses found decreased DMN–right frontoparietal (rFP) RSFC (t = -3.6, p = 0.0031) and increased sensorimotor–rFP RSFC (t = 2.2, p = 0.045), but these did not survive false-discovery-rate correction and were not related to symptom change or response. In an exploratory analysis, higher scores on an acute 'peak' or 'mystical' experience factor from the high-dose session were associated with larger decreases in PH RSFC with limbic regions (including bilateral amygdala) and DMN-related cortical regions (including the PCC).

Discussion

The investigators interpret their findings as evidence that post-acute brain changes one day after a high-dose psilocybin session differ markedly from the acute psychedelic state. Whereas the acute state is commonly associated with modular disintegration and increased global integration, the post-treatment pattern showed trends towards modular reintegration and minimal effects on global integration or segregation. In particular, decreases in CBF were found bilaterally in temporal cortex including the left amygdala, and the magnitude of amygdala perfusion reduction related to immediate mood improvement. Given prior reports of elevated amygdala blood flow and metabolism in depression, the authors view this as potentially remedial. An increase in DMN integrity was observed post-treatment across seed and network analyses, which contrasts with previous demonstrations of decreased DMN integrity during the acute psychedelic state. The authors note that reports of DMN abnormalities in depression are mixed; some studies have shown reduced DMN connectivity in patients that normalises following successful treatment such as electroconvulsive therapy. On this basis, Carhart-Harris and colleagues propose a 'reset' model whereby an acute period of modular disintegration permits subsequent re-integration or normalisation of networks like the DMN, accompanied by clinical improvement. Supporting this view, greater post-treatment increases in vmPFC–ilPC RSFC (a DMN node pairing) and greater decreases in PH–PFC RSFC were both predictive of sustained response at 5 weeks. The discussion acknowledges inconsistencies in the literature regarding acute and post-acute CBF changes across different psychedelics and administration routes, and suggests that future studies aiming to test the reset model should include both acute and post-acute imaging, ideally emphasising BOLD RSFC and EEG as more direct indices of brain function than CBF. Key limitations reported by the authors are the small sample size and the absence of a control condition; they also note that correction for multiple comparisons was applied to the full RSN analysis but not to the specific hypothesis-driven ROI tests. Finally, the investigators recommend that future work use more rigorous controls and disentangle the relative contributions of drug effects and the accompanying psychological support.

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METHODS

This study was approved by the National Research Ethics Service (NRES) committee London -West London and was conducted in accordance with the revised declaration of Helsinki (2000), the International Committee on Harmonisation Good Clinical Practice (GCP) guidelines and National Health Service (NHS) Research Governance Framework. Imperial College London sponsored the research which was conducted under a Home Office license for research with schedule 1 drugs. The Medicines and Healthcare products Regulatory Agency (MHRA) approved the study. All patients gave written informed consent, consistent with GCP. The matrix on the far right displays the between-condition differences in covariance (t values). The RSNs are: 1) medial visual network, 2) lateral visual network, 3) occipital pole network, 4) auditory network, 5) sensorimotor network, 6) DMN, 7) parietal cortex network, 8) the dorsal attention network, 9) the salience network, 10) posterior opercular network, 11) left frontoparietal network, 12) right frontoparietal network. White asterisks represent significant differences (P < 0.05, non-corrected). Both of the significant differences did not survive FDR correction for multiple comparisons. Imaging vs clinical outcomes. To explore relationships between significant imaging outcomes and the main clinical outcomes, we chose to focus on changes in depressive symptoms from: 1) pre-Treatment to scan 2 (i.e. one-day post-treatment), and 2) pre-Treatment to 5 weeks post-Treatment. The primary clinical outcome measure, the 16-item Quick Inventory of Depressive Symptoms (QIDS-SR16) was chosen for this purpose. Relationships between imaging outcomes and contemporaneous decreases in depressive symptoms were calculated using a standard Pearson's r, and relationships with the longer-term (i.e. at 5 weeks post-treatment) changes in depressive symptoms were calculated by splitting the sample into responders (>50% reduction in QIDS-SR16 scores) and non-responders at this time-point, and then performing a one-tailed t-test on the relevant imaging outcomes (one-tailed as directionality was unequivocally implied by the direction of the significant imaging outcome). We used a revised version of the QIDS-SR16 for 24-hour measurement for the post-treatment scan in order to get a contemporaneous, state-related index of depressive symptoms at this time-point.

RESULTS

Nineteen patients with diagnoses of treatment resistant major depression completed pre-treatment and one-day post-treatment fMRI scanning. Excessive movement or other artefact meant that three patients were removed from the ASL analyses and four from the RSFC (SI Appendix), leaving sample sizes of 16 (mean age = 42.8 ± 10.1 y, 4 females) and 15 (mean age = 42.8 ± 10.5 y, 4 females) for the ASL and BOLD analyses, respectively. Treatment with psilocybin produced rapid and sustained antidepressant effects. For the patients included in the ASL analysis (minus one patient whose scan 1 rating was not collected), the mean depression score (QIDS-SR16) for the week prior to the pre-treatment scan was 16.9 ± 5.1, and for the day of the post-treatment scan, it was 8.8 ± 6.2 (change = -8.1 ± 6, t = -5.2, p < 0.001). The mean QIDS-SR16 score at baseline (screening) was 18.9 ± 3, and for 5-weeks post-treatment, it was 10.9 ± 4.8 (change = -8 ± 5.1, t = -6.3, p < 0.001). Mean change values for those included in the BOLD analyses were -7.3 ± 5.3 (change from scan 1 to scan 2) and -8.2 ± 5.2 (change from baseline to 5 weeks post-treatment). Both contrasts were highly significant (t = -5.2 and -6.2, p < 0.001). Six of the 15 (BOLD) and 16 (ASL) patients met criteria for treatment response (≤50% reductions in QIDS-SR16 score) at 5 weeks. Of the full 19 patients, all showed some decrease in depressive symptoms at 1 week, with 12 meeting criteria for response (change = -10.2 ± 5.3, t = -6.4, p < 0.001). All but one patient showed some decrease in QIDS-SR16 score at week 5 (with one showing no change) and 47% met criteria for response (change = -9.2 ± 5.6, t = -6.7, p < 0.001). Whole-brain CBF was calculated pre and post treatment and contrasted (Fig.). Only decreases in CBF were observed post treatment (vs pre), and these reached statistical significance in the left Heschl's gyrus, left precentral gyrus, left planum temporale, left superior temporal gyrus, left amygdala, right supramarginal gyrus and right parietal operculum (Table). Based on previous findings of increased amygdala blood flow and metabolism in depression, reductions in amygdala CBF were compared with the reductions in depressive symptoms between scan 1 and 2 (i.e. decreased depressed mood at the time of scanning), and a significant relationship was found (r = 0.59; p = 0.01). After splitting the sample into responders and non-responders at 5-weeks post-treatment, and then comparing CBF changes in a t-test, no significant difference was found (t = 0.11; p = 0.46). Next, seed-based RSFC analyses were performed using the BOLD data. Based on previous data implicating their involvement in the pathophysiology of depression and response to treatments, four regions of interest (ROIs) were chosen: 1) the subgenual anterior cingulate cortex (sgACC), 2) the ventromedial prefrontal cortex (vmPFC), 3) the bilateral amygdala, and 4) the bilateral parahippocampus (PH) (Figsand SI Appendix, Table). Increased sgACC RSFC was observed with the posterior cingulate cortex/precuneous (PCC) post-treatment (Fig.) but this effect did not correlate with reductions in depressive symptoms between scan 1 and 2 (r = -0.2; p = 0.24) and nor did it predict treatment response at 5 weeks (t = -1.3; p = 0.11). Increased vmPFC RSFC was observed with the bilateral inferior-lateral parietal cortex (ilPC) post-treatment. This effect did not correlate with reductions in depressive symptoms between scan 1 and 2 (r = -0.26; p = 0.17) but did predict treatment response at 5 weeks, with responders showing significantly greater vmPFC-ilPC RSFC increases than non-responders (t = 2.1; p = 0.03). Decreased PH RSFC was observed with a PFC cluster incorporating the lateral and medial prefrontal cortex. This effect did not correlate with reductions in depressive symptoms between scan 1 and 2 (r = 0.08; p = 0.38) but did relate to treatment response at 5 weeks, with responders showing significantly greater PH-PFC RSFC decreases than non-responders (t = -1.9, p = 0.04). Amygdala RSFC was not significantly altered post treatment. Analyses of within network RSFC using 12 previously identified canonical RSNs 14 revealed increased default-mode network (DMN) (t = 2.7, p = 0.018), dorsal attention network (DAN) (t = 2.2, p = 0.042), and posterior opercular network (POP) (t = 2.7, p = 0.016) RSFC post-treatment; however, these changes failed to survive Bonferonni correction for multiple comparisons (revised α = 0.05/11 = 0.0042) and did not correlate with depression outcomes, e.g. the relationship between change in DMN RSFC and reduced QIDS-SR16 scores between scan 1 and 2 were non-significant (r = 0.25; p = 0.18) and neither were changes in DMN RSFC predictive of outcomes at 5 weeks (t = 0.58; p = 0.28). Analyses of between network RSFC using the same 12 RSNs, revealed decreased RSFC between the DMN and right frontoparietal network (rFP) (t = -3.6, p = 0.0031) and increased RSFC between the sensorimotor network (SM) and rFP (t = 2.2, p = 0.045) (Fig.); however, these effects did not survive FDR correction for multiple comparisons and did not relate to reduced QID-16 scores between scan 1 and 2, nor response at 5 weeks. Lastly, based on indications from previous workwe explored the possibility that the quality of the acute 'psychedelic' experience may have mediated the post-acute brain changes. We focused on a rating scale factor related to 'peak' or 'mystical' experience and used scores for the high-dose psilocybin session as a covariate in a PH RSFC analysis. The PH was specifically chosen due to previous work implicating its involvement in related states. Results revealed that patients scoring highest on 'peak' or 'mystical' experience had the greatest decreases in PH RSFC in limbic (e.g. bilateral amygdala) and DMN-related cortical regions (e.g. the PCC). See the supplementary file for the relevant maps and discussion.

CONCLUSION

The present study goes some way to addressing an important knowledge gap concerning the post-acute brain effects of serotonergic psychedelics. Its findings suggest that changes in brain activity observed just one-day after a high dose psychedelic experience are very different to those found during the acute psychedelic state. Specifically, whereas the acute psychedelic state in healthy volunteers is characterised by modular disintegrationand global integration, there are trends towards modular (re)integration and minimal effects on global integration/segregation post psilocybin for depression. Relating the blood flow findings to what has been seen previously in the acute psychedelic state is somewhat more complicated due to inconsistencies in this literature -likely due to analysis approaches and interpretation: Here we saw decreased CBF bilaterally in the temporal lobes, including the left amygdala one-day post treatment. Decreased absolute CBF in subcortical and high-level association cortices have been previously reported with intravenous (I.V.)and now oral psilocybinbut increased CBF and metabolism have also been reported with I.V. LSD, oral psilocybin, and oral ayahuasca. Much recent research has focused on the involvement of the default-mode network in psychiatric disorders, and particularly depression. We previously observed decreased DMN functional integrity under psilocybinand LSD, and others have with ayahuasca. Here however, increased DMN integrity was observed one-day post treatment with psilocybin, both via seed (i.e. vmPFC and sgACC) and network-based approaches. Previous work has suggested that increased DMN integrity may be a marker of depressed mood and specifically, depressive rumination. On this basis, increased DMN integrity post psilocybin may be surprising. The post-treatment increases in within-DMN RSFC and sgACC-PCC RSFC did not relate to symptom improvements but vmPFC-ilPC RSFC did (see Fig.). This apparent divergence from previous findingsis intriguing, and deserves further discussion (below). It should be noted that findings of elevated within-DMN RSFC in depression are not entirely consistent in the literature. For example, using a DMN-focused analysis, precuneus-DMN RSFCwas found to be lower in patients than in healthy controls, and normalised after treatment with electroconvulsive therapy (ECT) -and only in responders-consistent with the present findings. Lower precuneus-DMN RSFC in depression was also seen in a separate study and the degree of this abnormality correlated with autobiographical memory deficits. In another study, lower PCC-dmPFC and PCC-ilPC RSFC were seen in first-episode depressed patients relative to healthy controls. In the present study, we saw increased within-DMN RSFC post treatment with psilocybin, and increased vmPFC-bilateral ilPC RSFC was predictive of treatment response at 5 weeks (Fig.). These findings suggest a commonality in the antidepressant action of ECT and psilocybinin which DMN integrity is decreased acutely (at least by the latter) and increased (or normalised) post-acutely, accompanied by improvements in mood. This process might be likened to a 'reset' mechanism in which acute modular disintegration (e.g. in the DMN) enables a subsequent re-integration and resumption of normal functioning. Recent meta-analyses of studies of resting-state CBF in depression have yielded relatively mixed results, although findings of increased thalamicand sgACC metabolism are relatively consistent. Here, we did not find any post-treatment changes in thalamic or sgACC CBF with psilocybin, either in whole-brain or ROI-based analyses. We did observe decreased CBF bilaterally in the temporal cortex however, including the left medial temporal lobe and specifically, the left amygdala. Given previous findings of elevated resting-state amygdala CBF and metabolism in mood disorders, the reduction in amygdala CBF observed here, and its relation to symptom severity, could be viewed as a possible remediation effect. Moreover, generalised decreases in CBF are (again) consistent with what has been previously reported with ECT, i.e. most studies have documented an increase in CBF in the acute 'ictal' state, including in the amygdala; however, the post-ictal period is characterised by decreased CBF, and often in those regions that were most perfused during seizure. Acutely increased CBF has previously been reported with ayahuascaand LSDand increased glucose metabolism has been observed in the acute state with oral 31 but not I.V. psilocybin. Thus, a post-acute reversal of acute increases in CBF could be seen as consistent with the post-treatment 'reset' mechanism proposed above -although recent work has laid into question whether oral psilocybin does indeed cause increases in brain absolute CBF. It would be challenging (but not impossible) to carry out acute and post-acute imaging in future trials of psilocybin for depression, and this may be necessary if the 'reset' model is to be properly tested. In such a study, we would advise focusing on BOLD RSFC (and perhaps simultaneous EEG-related measures) rather than CBF, due to RSFC and EEG offering more direct and reliable indices of brain activity and function than more difficult to interpret measures such as CBF. The inclusion of a healthy control group, exposed to a consistent treatment procedure, would further strengthen the design of such a study, as would the inclusion of a placebo and/or active comparator arm. The present study's other major positive finding was a decrease in RSFC between the bilateral parahippocampus and the PFC, an effect that (like increased vmPFC-ilPC RSFC) was predictive of treatment response at 5 weeks. Curiously, a post-hoc exploratory analysis suggested that acute 'peak' or 'mystical-type' experiences under psilocybin may mediate the post-acute changes in parahippocampal RSFC (including decreased PH-PCC RSFC). Focusing on parahippocampal-PFC RSFC, this has generally been found to be elevated in depression, and consistently so across the duration of a resting-state scan. Prefrontal-limbic circuitry has been linked with top-down suppression of affective responsivenessand lower resting-state amygdala-vmPFC RSFC in combination with amygdala hyperfusion was found to relate to state-anxiety in healthy individuals, corroborating separate findings. Seven days of citalopram has been found to reduce amygdala-vmPFCand dorso-medial PFC-left hippocampal RSFCin healthy volunteers, somewhat consistent with the present findings. In conclusion, here we document for the first time, changes in resting-state brain blood flow and functional connectivity post-treatment with psilocybin for treatment-resistant depression. Decreased blood flow was found to correlate (in the amygdala) with reductions in depressive mood. Increased within-DMN RSFC was observed post-treatment, using both seed and network-based analyses, and specific increases in RSFC between the vmPFC and bilateral ilPC nodes of the DMN were greatest in individuals who maintained treatment-response at 5 weeks. Finally, decreased PH-PFC RSFC was observed post-treatment and this was also predictive of treatment-response at 5 weeks. An exploratory post-hoc analysis revealed that acute 'peak' or 'mystical' experience during the high-dose psilocybin session was predictive of these changes in PH RSFC. This study is limited by its small sample size and absence of a control condition. Moreover, correction for multiple testing was applied to the full RSN but not the specific (hypothesis-based) ROI analyses. Future research with more rigorous controls should serve to challenge and develop the present study's findings and inferences. Assessing the relative contributions of, and potential interactions between, the different treatment factors (e.g. the drug and the accompanying psychological support) may be a particularly informative next step.

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Shinozuka, K., Tewarie, P. K. B., Luppi, A. et al. · Biorxiv (2024)

5 cited
Show all 112 papers
Brain dynamics predictive of response to psilocybin for treatment-resistant depression

Vohryzek, J., Cabral, J., Lord, L. D. et al. · Brain Communications (2024)

31 cited
Exploring mechanisms of psychedelic action using neuroimaging

Erritzoe, D., Timmermann, C., Godfrey, K. et al. · Nature Mental Health (2024)

30 cited
28 cited
Psilocybin-assisted group therapy in patients with cancer diagnosed with a major depressive disorder

Agrawal, M., Richards, B. D., Richards, W. A. et al. · Cancer (2023)

69 cited
Beyond the 5-HT2A Receptor: Classic and Nonclassic Targets in Psychedelic Drug Action

Cameron, L. P., Benetatos, J., Lewis, V. et al. · Journal of Neuroscience (2023)

81 cited
Mechanisms and molecular targets surrounding the potential therapeutic effects of psychedelics

Jaster, A. M., González-Maeso, J. · Molecular Psychiatry (2023)

49 cited
Neuroimaging in psychedelic drug development: Past, present, and future

Wall, M. B., Harding, R., Zafar, R. et al. · Molecular Psychiatry (2023)

38 cited
Dynamic Functional Hyperconnectivity after Psilocybin Intake is Primarily Associated with Oceanic Boundlessness

Mortaheb, S., Fort, L. D., Mason, N. L. et al. · Biological Psychiatry (2023)

20 cited
Altered State of Consciousness and Mental Imagery as a Function of N, N-dimethyltryptamine Concentration in Ritualistic Ayahuasca Users

Ramaekers, J. G., Mallaroni, P., Kloft, L. et al. · Journal of Cognitive Neuroscience (2023)

15 cited
9 cited
N, N-Dimethyltryptamine (DMT)-Occasioned Familiarity and the Sense of Familiarity Questionnaire (SOF-Q)

Lawrence, D. W., Timmermann, C. · Journal of Psychoactive Drugs (2023)

3 cited
Increased low-frequency brain responses to music after psilocybin therapy for depression

Wall, M. B., Lam, C., Ertl, N. et al. · Journal of Affective Disorders (2023)

35 cited
Pilot study of single-dose psilocybin for serotonin reuptake inhibitor-resistant body dysmorphic disorder

Feusner, J. D., Wheaton, M. G., Gomez, G. J. et al. · Journal of Psychiatric Research (2023)

73 cited
Changes in music-evoked emotion and ventral striatal functional connectivity after psilocybin therapy for depression

Wall, M., Nutt, D. J., Kaelen, M. et al. · Journal of Psychopharmacology (2022)

37 cited
Low doses of lysergic acid diethylamide (LSD) increase reward-related brain activity

Glazer', J., Murray, C. H., Nusslock', R. et al. · Neuropsychopharmacology (2022)

50 cited
34 cited
Neural Mechanisms and Psychology of Psychedelic Ego Dissolution

Stoliker, D., Egan, G. F., Friston, K. J. et al. · Pharmacological Reviews (2022)

11 cited
9 cited
Postpartum depression: A role for psychedelics?

Jairaj, C., Rucker, J. · Journal of Psychopharmacology (2022)

13 cited
Psychedelic Therapy for Body Dysmorphic Disorder

Johnson, S., Letheby, C. · Journal of Psychedelic Studies (2022)

1 cited
Psychedelic Resting-state Neuroimaging: A Review and Perspective on Balancing Replication and Novel Analyses

McCulloch, D. E-W., Knudsen, G. M., Barrett, F. S. et al. · Neuroscience and Biobehavioral Reviews (2022)

114 cited
The Effects of Psilocybin in Adults with Major Depressive Disorder and The General Population

Gill, H., Puramat, P., Patel, P. et al. · Psychiatry Research (2022)

15 cited
Increased global integration in the brain after psilocybin therapy for depression

Daws, R. E., Timmermann, C., Giribaldi, B. et al. · Nature Medicine (2022)

425 cited
Psychedelic Therapy's Transdiagnostic Effects: A Research Domain Criteria (RDoC) Perspective

Dursun, S. M., Kelly, J. R., Gillan, C. M. et al. · Frontiers in Psychiatry (2021)

63 cited
Psilocybin therapy increases cognitive and neural flexibility in patients with major depressive disorder

Doss, M. K., Považan, M., Rosenberg, M. D. et al. · Translational Psychiatry (2021)

335 cited
Psychedelics as Novel Therapeutics in Alzheimer’s Disease: Rationale and Potential Mechanisms

Garcia-Romeu, A., Darcy, S., Jackson, H. et al. · Current Topics in Behavioral Neurosciences (2021)

33 cited
From Psychiatry to Neurology: Psychedelics as Prospective Therapeutics for Neurodegenerative Disorders

Nichols, C. D., Wiatr, K., Figiel, M. et al. · Journal of Neurochemistry (2021)

75 cited
The kappa opioid receptor and the sleep of reason: Cortico-subcortical imbalance following salvinorin-A

Ona, G., Sampedro, F., Romero, S. et al. · International Journal of Neuropsychopharmacology (2021)

17 cited
The effects of tryptamine psychedelics in the brain: a meta-analysis of functional and review of molecular imaging studies

Castelhano, J. M., Lima, G. M., Teixeira, M. et al. · Frontiers in Pharmacology (2021)

34 cited
Attitudes and Beliefs about the Therapeutic Use of Psychedelic Drugs among Psychologists in the United States

Davis, A. K., Agin-Liebes, G. I., España, M. et al. · Journal of Psychoactive Drugs (2021)

100 cited
Improving cognitive functioning in major depressive disorder with psychedelics: a dimensional approach

Kuiperes, Z., Schreiber, R. · Neurobiology of Learning and Memory (2021)

49 cited
Does psychedelic therapy have a transdiagnostic action and prophylactic potential?

Kočárová, C., Horacek, J., Carhart-Harris, R. L. · Frontiers in Psychiatry (2021)

94 cited
Psilocybin as a Novel Pharmacotherapy for Treatment-Refractory Anorexia Nervosa

Rodan, S., Aouad, P., McGregor, I. S. et al. · OBM Neurobiology (2021)

9 cited
2 cited
Psychedelic perceptions: mental health service user attitudes to psilocybin therapy

Corrigan, K., Haran, M., Mccandliss, C. et al. · Irish Journal of Medical Science (2021)

74 cited
Decreased brain modularity after psilocybin therapy for depression

Daws, R. E., Timmermann, C., Giribaldi, B. et al. · Research Square (2021)

11 cited
A continuum hypothesis of psychotomimetic rapid antidepressants

Haarsma, J., Harmer, C. J., Tamm, S. · Brain and Neuroscience Advances (2021)

10 cited
72 cited
Naturalistic Use of Mescaline Is Associated with Self-Reported Psychiatric Improvements and Enduring Positive Life Changes

Agin-Liebes, G. I., Lancelotta, R., Uthaug, M. V. et al. · ACS Pharmacology and Translational Science (2021)

119 cited
Psychedelic Harm Reduction and Integration: A Transtheoretical Model for Clinical Practice

Palhano-Fontes, F., Gorman, I., Nielson, E. M. et al. · Frontiers in Psychology (2021)

136 cited
Optimal dosing for psilocybin pharmacotherapy: Considering weight-adjusted and fixed dosing approaches

Garcia-Romeu, A., Barrett, F. S., Carbonaro, T. M. et al. · Journal of Psychopharmacology (2021)

99 cited
Psilocin acutely disrupts sleep and affects local but not global sleep homeostasis in laboratory mice

Thomas, C. W., Blanco-Duque, C., Breant, B. et al. · Translational Psychiatry (2021)

4 cited
Lasting effects of a single psilocybin dose on resting-state functional connectivity in healthy individuals

McCulloch, D. E-W., Madsen, M. K., Stenbæk, D. S. et al. · Journal of Psychopharmacology (2021)

12 cited
Positive expectations predict improved mental-health outcomes linked to psychedelic microdosing

Kaertner, L. S., Steinborn, M. B., Kettner, H. et al. · Scientific Reports (2021)

152 cited
143 cited
Psychedelic Medicines in Major Depression: Progress and Future Challenges

Bouso, J. C., Ona, G., Dos Santos, R. G. et al. · Advances in Experimental Medicine and Biology (2021)

6 cited
12 cited
The History of Psychedelics in Psychiatry

Nichols, D. E., Walter, H. · Pharmacopsychiatry (2020)

128 cited
The Effects of Daytime Psilocybin Administration on Sleep: Implications for Antidepressant Action

Dudysová, D., Janků, K., Šmotek, M. et al. · Frontiers in Pharmacology (2020)

36 cited
Pivotal Mental States

Brouwer, A., Carhart-Harris, R. L. · Journal of Psychopharmacology (2020)

145 cited
Therapeutic effects of classic serotonergic psychedelics: A systematic review of modern-era clinical studies

Andersen, K. A. A., Carhart-Harris, R. L., Nutt, D. J. et al. · Acta Psychiatrica Scandinavica (2020)

345 cited
The Emerging Role of Psilocybin and MDMA in the Treatment of Mental Illness

Gill, H., Gill, B., Chen-Li, D. et al. · Expert Review of Neurotherapeutics (2020)

61 cited
Classic Psychedelics as a Psychotherapeutic Aid in the Treatment of Stimulant Use Disorder: a Case Report

Johnson, S., Black, Q. C. · International Journal of Mental Health and Addiction (2020)

2 cited
Transient Stimulation with Psychoplastogens Is Sufficient to Initiate Neuronal Growth

Greb, A. C., Vargas, M. V., Duim, W. C. et al. · ACS Pharmacology and Translational Science (2020)

123 cited
Psychedelics and virtual reality: parallels and applications

Aday, J. S., Davoli, C. C., Bloesch, E. K. · Therapeutic Advances in Psychopharmacology (2020)

50 cited
12 cited
Ethics and ego dissolution: the case of psilocybin

Smith, W. R., Sisti, D. · Journal of Medical Ethics (2020)

140 cited
LSD flattens the functional hierarchy of the human brain

Girn, M., Roseman, L., Bernhardt, B. et al. · Biorxiv (2020)

27 cited
Subacute Effects of the Psychedelic Ayahuasca on the Salience and Default Mode Networks

Pasquini, L., Palhano-Fontes, F., Araújo, D. B. · Journal of Psychopharmacology (2020)

99 cited
Psychedelic Psychiatry’s Brave New World

Nutt, D. J., Erritzoe, D., Carhart-Harris, R. L. · Cell (2020)

322 cited
Preliminary report on the effects of a low dose of LSD on resting-state amygdala functional connectivity

Bershad, A. K., Preller, K. H., Lee, R. et al. · Biological Psychiatry (2020)

95 cited
Long-term effects of psychedelic drugs: A systematic review

Aday, J. S., Mitzkovitz, C. M., Bloesch, E. K. et al. · Neuroscience and Biobehavioral Reviews (2020)

253 cited
Effects of ayahuasca on mental health and quality of life in naïve users: A longitudinal and cross-sectional study combination

Jiménez-Garrido, D. F., Gómez-Sousa, M., Ona, G. et al. · Scientific Reports (2020)

109 cited
Natural Psychoplastogens As Antidepressant Agents

Benko, J., Vranková, S. · Molecules (2020)

18 cited
Emotions and brain function are altered up to one month after a single high dose of psilocybin

Barrett, F. S., Doss, M. K., Sepeda, N. D. et al. · Scientific Reports (2020)

371 cited
Classic psychedelics as therapeutics for psychiatric disorders

Nichols, C. D., Hendricks, P. S. · Handbook of Behavioral Neuroscience (2020)

10 cited
Psilocybin-assisted therapy of major depressive disorder using Acceptance and Commitment Therapy as a therapeutic frame

Sloshower, J., Guss, J., Krause, R. et al. · Journal of Contextual Behavioral Science (2020)

164 cited
Psychological flexibility mediates the relations between acute psychedelic effects and subjective decreases in depression and anxiety

Davis, A. K., Barrett, F. S., Griffiths, R. R. · Journal of Contextual Behavioral Science (2020)

367 cited
In vivo production of psilocybin in E. coli

Adams, A. M., Kaplan, N. A., Wei, Z. et al. · Metabolic Engineering (2019)

83 cited
REBUS and the Anarchic Brain: Toward a Unified Model of the Brain Action of Psychedelics

Carhart-Harris, R. L., Friston, K. J. · Pharmacological Reviews (2019)

1128 cited
Modulation of Serum Brain-Derived Neurotrophic Factor by a Single Dose of Ayahuasca: Observation From a Randomized Controlled Trial

Galvão-Coelho, N. L., de Almeida, R. N., de Menezes Galvão, A. C. et al. · Frontiers in Psychology (2019)

172 cited
Psychedelic drugs-a new era in psychiatry?

Nutt, D. J. · Dialogues in Clinical Neuroscience (2019)

131 cited
Cessation and reduction in alcohol consumption and misuse after psychedelic use

Garcia-Romeu, A., Davis, A. K., Fire Erowid et al. · Journal of Psychopharmacology (2019)

283 cited
Classic psychedelics: An integrative review of epidemiology, therapeutics, mystical experience, and brain network function

Johnson, M. W., Hendricks, P. S., Barrett, F. S. et al. · Pharmacology and Therapeutics (2019)

518 cited
5-methoxy-N,N-dimethyltryptamine (5-MeO-DMT) used in a naturalistic group setting is associated with unintended improvements in depression and anxiety

Davis, A. K., So, S., Lancelotta, R. et al. · The American Journal of Drug and Alcohol Abuse (2019)

139 cited
Microdosing psychedelics: personality, mental health, and creativity differences in microdosers

Anderson, T., Petranker, R., Rosenbaum, D. et al. · Psychopharmacology (2019)

169 cited
Psychiatry might need some psychedelic therapy

Johnson, M. W. · International Review of Psychiatry (2018)

11 cited
Current perspectives on psychedelic therapy: use of serotonergic hallucinogens in clinical interventions

Richards, W. A., Garcia-Romeu, A. · International Review of Psychiatry (2018)

Increased amygdala responses to emotional faces after psilocybin for treatment-resistant depression

Roseman, L., Demetriou, L., Wall, M. B. et al. · Neuropharmacology (2018)

237 cited
76 cited
Psychedelics and music: neuroscience and therapeutic implications

Barrett, F. S., Preller, K. H., Kaelen, M. · International Review of Psychiatry (2018)

83 cited
Psychedelics as anti-inflammatory agents

Flanagan, T. W., Nichols, C. D. · International Review of Psychiatry (2018)

256 cited
Psilocybin modulates functional connectivity of the amygdala during emotional face discrimination

Grimm, O., Kraehenmann, R., Preller, K. H. et al. · European Neuropsychopharmacology (2018)

94 cited
Taking Psychedelics Seriously

Byock, I. · Journal of Palliative Medicine (2018)

164 cited
The entropic brain - revisited

Carhart-Harris, R. L. · Neuropharmacology (2018)

539 cited
Psilocybin with psychological support for treatment-resistant depression: six-month follow-up

Carhart-Harris, R. L., Bolstridge, &. M., Day, C. M. J. et al. · Psychopharmacology (2017)

965 cited
Psilocybin with psychological support improves emotional face recognition in treatment-resistant depression

Stroud, J., Freeman, T. P., Leech, R. et al. · Psychopharmacology (2017)

100 cited
Serotonin and brain function: a tale of two receptors

Carhart-Harris, R. L., Nutt, D. J. · Journal of Psychopharmacology (2017)

727 cited
Psilocybin for treatment-resistant depression:... — Research Summary & Context | Blossom