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Increased hippocampal blood flow in people at clinical high risk for psychosis and effects of cannabidiol

Published online by Cambridge University Press:  17 October 2023

Cathy Davies
Affiliation:
Department of Psychosis Studies, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK Department of Neuroimaging, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK
Matthijs G Bossong
Affiliation:
Department of Psychiatry, University Medical Center Utrecht Brain Center, Utrecht University, Utrecht, The Netherlands
Daniel Martins
Affiliation:
Department of Neuroimaging, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK National Institute for Health Research (NIHR) Maudsley Biomedical Research Centre, South London and Maudsley NHS Foundation Trust, London, UK
Robin Wilson
Affiliation:
Department of Psychosis Studies, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK
Elizabeth Appiah-Kusi
Affiliation:
Department of Psychosis Studies, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK
Grace Blest-Hopley
Affiliation:
Department of Psychosis Studies, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK
Fernando Zelaya
Affiliation:
Department of Neuroimaging, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK
Paul Allen
Affiliation:
Department of Psychosis Studies, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK Department of Neuroimaging, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK
Michael Brammer
Affiliation:
Department of Neuroimaging, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK
Jesus Perez
Affiliation:
CAMEO Early Intervention Service, Cambridgeshire and Peterborough NHS Foundation Trust, Cambridge, UK Institute of Biomedical Research (IBSAL), Department of Medicine, Universidad de Salamanca, Salamanca, Spain
Philip McGuire
Affiliation:
Department of Psychiatry, University of Oxford, Oxford, UK NIHR Oxford Health Biomedical Research Centre, Oxford, UK Oxford Health NHS Foundation Trust, Oxford, UK
Sagnik Bhattacharyya*
Affiliation:
Department of Psychosis Studies, Institute of Psychiatry, Psychology & Neuroscience, King's College London, London, UK
*
Corresponding author: Sagnik Bhattacharyya; Email: [email protected]
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Abstract

Background

Hippocampal hyperperfusion has been observed in people at Clinical High Risk for Psychosis (CHR), is associated with adverse longitudinal outcomes and represents a potential treatment target for novel pharmacotherapies. Whether cannabidiol (CBD) has ameliorative effects on hippocampal blood flow (rCBF) in CHR patients remains unknown.

Methods

Using a double-blind, parallel-group design, 33 CHR patients were randomized to a single oral 600 mg dose of CBD or placebo; 19 healthy controls did not receive any drug. Hippocampal rCBF was measured using Arterial Spin Labeling. We examined differences relating to CHR status (controls v. placebo), effects of CBD in CHR (placebo v. CBD) and linear between-group relationships, such that placebo > CBD > controls or controls > CBD > placebo, using a combination of hypothesis-driven and exploratory wholebrain analyses.

Results

Placebo-treated patients had significantly higher hippocampal rCBF bilaterally (all pFWE<0.01) compared to healthy controls. There were no suprathreshold effects in the CBD v. placebo contrast. However, we found a significant linear relationship in the right hippocampus (pFWE = 0.035) such that rCBF was highest in the placebo group, lowest in controls and intermediate in the CBD group. Exploratory wholebrain results replicated previous findings of hyperperfusion in the hippocampus, striatum and midbrain in CHR patients, and provided novel evidence of increased rCBF in inferior-temporal and lateral-occipital regions in patients under CBD compared to placebo.

Conclusions

These findings suggest that hippocampal blood flow is elevated in the CHR state and may be partially normalized by a single dose of CBD. CBD therefore merits further investigation as a potential novel treatment for this population.

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, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Introduction

Psychotic disorders such as schizophrenia are usually preceded by a prodromal stage, characterized by attenuated psychotic symptoms and social, emotional and cognitive dysfunction (Fusar-Poli et al., Reference Fusar-Poli, Salazar De Pablo, Correll, Meyer-Lindenberg, Millan, Borgwardt and Arango2020b). Such individuals are said to be at Clinical High Risk for psychosis (CHR) and have a ~22% three-year risk of transitioning to the full-blown disorder (Fusar-Poli et al., Reference Fusar-Poli, Salazar De Pablo, Correll, Meyer-Lindenberg, Millan, Borgwardt and Arango2020b). The neurobiological mechanisms underlying psychosis risk and onset are incompletely understood (Millan et al., Reference Millan, Andrieux, Bartzokis, Cadenhead, Dazzan, Fusar-Poli and Weinberger2016) but compelling evidence implicates hippocampal dysfunction in its pathophysiology (Knight et al., Reference Knight, Mccutcheon, Dwir, Grace, Daly, Mcguire and Modinos2022; Lieberman et al., Reference Lieberman, Girgis, Brucato, Moore, Provenzano, Kegeles and Small2018; Tamminga, Stan, & Wagner, Reference Tamminga, Stan and Wagner2010). Specifically, preclinical models suggest that hippocampal hyperactivity is key to the development of psychosis and arises due to NMDA receptor hypofunction on GABAergic interneurons, leading to disinhibition of hippocampal pyramidal cells (Lisman et al., Reference Lisman, Coyle, Green, Javitt, Benes, Heckers and Grace2008; Lodge & Grace, Reference Lodge and Grace2007) (online Supplementary Fig S1). This is thought to drive hypermetabolism and elevated blood volumes/flow in the hippocampus (Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013) as well as downstream midbrain-striatal hyperdopaminergia (Grace & Gomes, Reference Grace and Gomes2019; Modinos, Allen, Grace, & McGuire, Reference Modinos, Allen, Grace and McGuire2015), with the consequent induction of psychotic-like phenotypes in animals and symptoms in humans (online Supplementary Fig S1).

These findings are consistent with in vivo evidence of increased cerebral blood volumes (CBV) in the hippocampus in patients with psychosis (McHugo et al., Reference McHugo, Talati, Armstrong, Vandekar, Blackford, Woodward and Heckers2019; Schobel et al., Reference Schobel, Lewandowski, Corcoran, Moore, Brown, Malaspina and Small2009; Talati et al., Reference Talati, Rane, Kose, Blackford, Gore, Donahue and Heckers2014; Talati, Rane, Skinner, Gore, & Heckers, Reference Talati, Rane, Skinner, Gore and Heckers2015) and at baseline in CHR individuals who go on to transition (Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013, Reference Schobel, Lewandowski, Corcoran, Moore, Brown, Malaspina and Small2009). However, numerous studies in patients with established illness have not found differences in hippocampal resting cerebral blood flow (rCBF, or ‘perfusion’) (for reviews see (Guimarães, Machado-de-Sousa, Crippa, Guimarães, & Hallak, Reference Guimarães, Machado-de-Sousa, Crippa, Guimarães and Hallak2016; Percie du Sert et al., Reference Percie du Sert, Unrau, Gauthier, Chakravarty, Malla, Lepage and Raucher-Chéné2023; Sukumar, Sabesan, Anazodo, & Palaniyappan, Reference Sukumar, Sabesan, Anazodo and Palaniyappan2020)). Although antipsychotics – which can impact rCBF (Goozée, Handley, Kempton, & Dazzan, Reference Goozée, Handley, Kempton and Dazzan2014) – may be an important confounder here, few of the studies of antipsychotic-naïve or -free patients conducted to date (Bojesen et al., Reference Bojesen, Glenthøj, Sigvard, Tangmose, Raghava, Ebdrup and Rostrup2023; Medoff, Holcomb, Lahti, & Tamminga, Reference Medoff, Holcomb, Lahti and Tamminga2001; Scheef et al., Reference Scheef, Manka, Daamen, Kühn, Maier, Schild and Jessen2010; Selvaggi et al., Reference Selvaggi, Jauhar, Kotoula, Pepper, Veronese, Santangelo and Howes2022) report significant hippocampal rCBF differences.

By contrast, previous work in CHR patients demonstrates that rCBF in the hippocampus is increased relative to controls (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018, Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016), with longitudinal reductions in hippocampal rCBF associated with remission from the CHR state (Allen et al., Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016). While only a minority of CHR individuals go on to develop frank psychosis (Fusar-Poli et al., Reference Fusar-Poli, Salazar De Pablo, Correll, Meyer-Lindenberg, Millan, Borgwardt and Arango2020b), this clinical group offers a unique opportunity to investigate the mechanisms underlying psychosis risk without the effects of both antipsychotic exposure and illness chronicity. Hippocampal rCBF has also been associated with prefrontal GABA levels (Modinos et al., Reference Modinos, Şimşek, Azis, Bossong, Bonoldi, Samson and McGuire2018b) and striatal dopamine function (Modinos et al., Reference Modinos, Richter, Egerton, Bonoldi, Azis, Antoniades and McGuire2021) in CHR individuals, which are implicated in the final common pathways to psychosis (Howes & Kapur, Reference Howes and Kapur2009). Hippocampal hyperactivity (and associated hyperperfusion) may therefore represent potential treatment targets. Importantly, as the CHR state progresses to the first episode of psychosis, functional perturbations originating in the hippocampus appear to spread to regions such as the frontal cortex (Lieberman et al., Reference Lieberman, Girgis, Brucato, Moore, Provenzano, Kegeles and Small2018; Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013), and excitotoxic as well as atrophic processes culminate in hippocampal volume loss (Ho et al., Reference Ho, Holt, Cheung, Iglesias, Goh, Wang and Zhou2017a, Reference Ho, Iglesias, Sum, Kuswanto, Sitoh, De Souza and Holt2017b; Vargas et al., Reference Vargas, Dean, Osborne, Gupta, Ristanovic, Ozturk and Mittal2017) and morphological alterations (Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013) (online Supplementary Fig S1). If functional hippocampal changes precede structural (atrophic) changes, treatments targeted to hippocampal hyperactivity during the CHR stage may prove more effective as preventative strategies. However, there are currently no licensed pharmacological interventions for people at CHR (Davies et al., Reference Davies, Cipriani, Ioannidis, Radua, Stahl, Provenzani and Fusar-Poli2018a, Reference Davies, Radua, Cipriani, Stahl, Provenzani, McGuire and Fusar-Poli2018b), which remains a critical unmet need.

One of the most promising candidate treatments is cannabidiol (CBD), a phytocannabinoid constituent of the cannabis plant (Davies & Bhattacharyya, Reference Davies and Bhattacharyya2019). Compared to the main intoxicating cannabinoid in cannabis, delta-9-tetrahydrocannabinol (THC), which has psychotomimetic (Bhattacharyya et al., Reference Bhattacharyya, Fusar-Poli, Borgwardt, Martin-Santos, Nosarti, O'Carroll and McGuire2009; D'Souza et al., Reference D'Souza, Perry, MacDougall, Ammerman, Cooper, Wu and Krystal2004; Englund et al., Reference Englund, Morrison, Nottage, Hague, Kane, Bonaccorso and Kapur2013; Morrison et al., Reference Morrison, Zois, McKeown, Lee, Holt, Powell and Murray2009; Sherif, Radhakrishnan, D'Souza, & Ranganathan, Reference Sherif, Radhakrishnan, D'Souza and Ranganathan2016) and potential anxiogenic effects, CBD is non-intoxicating and has anxiolytic (Bergamaschi et al., Reference Bergamaschi, Queiroz, Chagas, De Oliveira, De Martinis, Kapczinski and Crippa2011; Crippa et al., Reference Crippa, Nogueira Derenusson, Borduqui Ferrari, Wichert-Ana, Duran, Martin-Santos and Hallak2011) and antipsychotic properties (Crippa, Guimarães, Campos, & Zuardi, Reference Crippa, Guimarães, Campos and Zuardi2018; Leweke et al., Reference Leweke, Piomelli, Pahlisch, Muhl, Gerth, Hoyer and Koethe2012; McGuire et al., Reference McGuire, Robson, Cubala, Vasile, Morrison, Barron and Wright2018). However, the mechanisms underlying these effects remain unclear. In healthy volunteers and patients with established psychosis, CBD modulates blood-oxygen-level-dependent (BOLD) haemodynamic responses to fMRI tasks in several regions, particularly medial temporal cortex and striatum, as well as functional connectivity between these regions (Bhattacharyya et al., Reference Bhattacharyya, Crippa, Allen, Martin-Santos, Borgwardt, Fusar-Poli and McGuire2012, Reference Bhattacharyya, Falkenberg, Martin-Santos, Atakan, Crippa, Giampietro and McGuire2015, Reference Bhattacharyya, Morrison, Fusar-Poli, Martin-Santos, Borgwardt, Winton-Brown and McGuire2010; Fusar-Poli et al., Reference Fusar-Poli, Crippa, Bhattacharyya, Borgwardt, Allen, Martin-Santos and McGuire2009; Gunasekera, Davies, Martin-Santos, & Bhatthacharyya, Reference Gunasekera, Davies, Martin-Santos and Bhatthacharyya2020; O'Neill et al., Reference O'Neill, Wilson, Blest-Hopley, Annibale, Colizzi, Brammer and Bhattacharyya2021). In CHR patients, we previously demonstrated that a 600 mg dose of CBD partially normalizes mediotemporal and striatal function during verbal memory (Bhattacharyya et al., Reference Bhattacharyya, Wilson, Appiah-Kusi, O'Neill, Brammer, Perez and McGuire2018) and fear processing (Davies et al., Reference Davies, Wilson, Appiah-Kusi, Blest-Hopley, Brammer, Perez and Bhattacharyya2020), such that activation in the CBD group was intermediate between that of healthy controls and CHR patients under placebo. CBD has also been shown to modulate hippocampal perfusion. Two single-photon emission computed tomography (SPECT) studies found reductions in hippocampal blood flow following CBD in healthy individuals (Crippa et al., Reference Crippa, Zuardi, Garrido, Wichert-Ana, Guarnieri, Ferrari and Filho Busatto2004) and patients with social anxiety disorder (Crippa et al., Reference Crippa, Nogueira Derenusson, Borduqui Ferrari, Wichert-Ana, Duran, Martin-Santos and Hallak2011). Conversely, a more recent study using Arterial Spin Labeling (ASL) found that CBD increased hippocampal rCBF in healthy participants, a specific effect not found in five other regions-of-interest (ROIs) (Bloomfield et al., Reference Bloomfield, Green, Hindocha, Yamamori, Yim, Jones and Freeman2019). The presence of hippocampal effects across all three prior studies is encouraging and suggests that CBD may engage one of the most strongly implicated neurobiological treatment targets for people at CHR. However, whether CBD has ameliorative effects on hippocampal blood flow in CHR patients remains to be investigated.

To address this gap, in the present study we used ASL to examine hippocampal blood flow in three parallel groups: CHR patients randomized to a single 600 mg dose of CBD or placebo and healthy controls. On the basis of data from previous studies in CHR populations (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018, Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016), we selected bilateral ROIs within the hippocampus and assessed extra-hippocampal effects with exploratory wholebrain analyses. We first examined whether CHR patients under placebo conditions show elevated hippocampal blood flow compared to healthy controls. We then tested our primary hypothesis that CHR patients receiving CBD would show at least partial ‘normalization’ of hippocampal blood flow in the same regions identified as different in the placebo v. control analyses. That is, perfusion in the CBD group would be intermediate between that observed in healthy controls and the CHR placebo group.

Patients & methods

Participants

The study was registered (ISRCTN46322781) and received Research Ethics (Camberwell St Giles) approval. All participants provided written informed consent. Thirty-three antipsychotic-naive CHR individuals, aged 18–35, were recruited from specialist early detection services in the United Kingdom. CHR status was determined using the Comprehensive Assessment of At-Risk Mental States (CAARMS) criteria (Yung et al., Reference Yung, Pan Yuen, McGorry, Phillips, Kelly, Dell'olio and Buckby2005). Briefly, subjects met one or more of the following subgroup criteria: (a) attenuated psychotic symptoms, (b) brief limited intermittent psychotic symptoms (psychotic episode lasting <1 week, remitting without treatment), or (c) either schizotypal personality disorder or first-degree relative with psychosis, all coupled with functional decline (Yung et al., Reference Yung, Pan Yuen, McGorry, Phillips, Kelly, Dell'olio and Buckby2005). Nineteen age (within 3 years), sex and ethnicity-matched healthy controls were recruited locally by advertisement. Exclusion criteria included history of psychotic or manic episode, current DSM-IV diagnosis of substance dependence (except cannabis), IQ < 70, neurological disorder or severe intercurrent illness, and any contraindication to magnetic resonance imaging (MRI) or treatment with CBD. Participants were required to abstain from cannabis for 96 h, other recreational substances for 2 weeks, alcohol for 24 h and caffeine and nicotine for 6 h before attending. A urine sample prior to scanning was used to screen for illicit drug use and pregnancy.

Design, materials, procedure

Using a randomized, double-blind, placebo-controlled, three-arm parallel-group design, CHR participants were randomized to a single oral 600 mg dose of CBD (THC-Pharm) or a matched placebo capsule. This dose was selected based on previous findings that doses of 600–800 mg/day are effective in established psychosis (Leweke et al., Reference Leweke, Piomelli, Pahlisch, Muhl, Gerth, Hoyer and Koethe2012) and anxiety (Bergamaschi et al., Reference Bergamaschi, Queiroz, Chagas, De Oliveira, De Martinis, Kapczinski and Crippa2011). Psychopathology was measured at baseline (before drug administration) using the CAARMS (positive and negative symptoms) and State-Trait Anxiety Inventory (State Subscale). Following a standard light breakfast, participants were administered the capsule (at ~11AM) and 180 min later, underwent a battery of MRI sequences. This interval between drug administration and MRI acquisition was selected based on previous findings describing peak plasma concentrations at 180 min following oral administration (Martin-Santos et al., Reference Martin-Santos, Crippa, Batalla, Bhattacharyya, Atakan, Borgwardt and McGuire2012; Millar, Stone, Yates, & O'Sullivan, Reference Millar, Stone, Yates and O'Sullivan2018). Healthy control participants were investigated under identical conditions but did not receive any drug. Plasma CBD levels were sampled at baseline and at 120 and 300 min after drug administration.

MRI acquisition and image processing

All scans were acquired on a General Electric Signa HDx 3 T MR system with an 8-channel head coil. For image registration, high resolution T2-weighted Fast Spin Echo (FSE) and T1-weighted Spoiled Gradient Recalled images were acquired. Resting CBF was measured using pseudo-Continuous ASL acquired with a 3D-FSE spiral multi-shot readout. Acquisition parameters and preprocessing procedures (conducted using FMRIB Software Library; FSL/6.0.2) were in line with previous studies (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018, Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016; Modinos et al., Reference Modinos, Richter, Egerton, Bonoldi, Azis, Antoniades and McGuire2021; Modinos et al., Reference Modinos, Şimşek, Azis, Bossong, Bonoldi, Samson and McGuire2018b) and are detailed in the online Supplementary Methods.

Statistical analysis

Global blood flow

To exclude potential group differences in global CBF, we extracted mean CBF values from the MNI152 gray matter mask (thresholded at >0.50 probability) for each subject using fslmeants in FSL. We then conducted analyses of covariance (ANCOVA) in SPSS 27 using mean-centered age, sex, education and smoking as covariates. All subsequent analyses were conducted with global CBF as a nuisance covariate.

Hippocampal blood flow

Analyses of rCBF data were conducted using Statistical Parametric Mapping 12 (SPM12) in Matlab/R2018b using an ROI approach. Hippocampal ROIs were specified a priori using coordinates from a previous (Allen et al., Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016) (and replicated (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018)) study comparing CBF in CHR patients v. healthy controls, which have since been used in studies across the extended psychosis phenotype (Modinos et al., Reference Modinos, Egerton, McMullen, McLaughlin, Kumari, Barker and Zelaya2018a, Reference Modinos, Şimşek, Azis, Bossong, Bonoldi, Samson and McGuire2018b); MNI coordinates in right: x = 20, y = −28, z = −8 and left hippocampus: x = −22, y = −28, z = −8. 6 mm spheres around these coordinates (123 voxels per ROI) were combined into a single volume and used as an explicit mask (246 voxels in total). In line with our first objective, we used an independent samples t test to compare the placebo-treated CHR group with healthy controls to identify differences in rCBF (within our pre-defined ROIs) related to CHR status. In a second independent samples t test, we directly compared CHR patients under placebo with those under CBD to test whether CBD had effects on rCBF in the same ROIs. Finally, to test our primary hypothesis that rCBF in the CBD group would be intermediate between that of the healthy control and placebo groups (which may suggest partial normalization of rCBF by CBD), we examined whether a linear relationship in rCBF (controls > CBD > placebo; or placebo > CBD > controls) existed within the same ROIs using ANCOVA (flexible factorial). Linear trend (i.e. linear relationship) analyses are distinct from standard ANOVA in that they test for specific relationships (such as linear or quadratic) across groups, which are not tested by the standard F-test (Howell, Reference Howell2010). In line with previous CHR studies of CBF (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018, Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016), mean-centered age, sex, smoking status and years of education (the latter included due to significant group differences in our sample) were included in all analyses as nuisance covariates, as was mean global CBF (via global normalization in SPM). Results were considered significant after p < 0.05 with family-wise error (FWE) correction for multiple comparisons at the voxel level, as in previous CHR studies (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018; Modinos et al., Reference Modinos, Egerton, McMullen, McLaughlin, Kumari, Barker and Zelaya2018a).

Exploratory wholebrain analyses

For completeness, we examined the same contrasts as above at wholebrain level. We conducted a wholebrain search using the explicit gray matter mask (again thresholded at >0.50) and cluster-level inference (cluster-forming threshold: p < 0.005; cluster reported as significant at p < 0.05 using FWE cluster correction in SPM). Supplemental analyses to evaluate the robustness of significant wholebrain findings were conducted using FSL's randomize, as detailed in the online Supplementary Material.

Demographics

Analyses of baseline and demographic variables were conducted in SPSS using independent t tests for continuous data and chi-square tests for categorical data. Significance was set at p < 0.05.

Results

There were no between-group differences in the majority of demographic and baseline clinical characteristics, except for fewer years of education in the placebo group relative to controls (Table 1), as reported in our previous publications (Bhattacharyya et al., Reference Bhattacharyya, Wilson, Appiah-Kusi, O'Neill, Brammer, Perez and McGuire2018; Davies et al., Reference Davies, Wilson, Appiah-Kusi, Blest-Hopley, Brammer, Perez and Bhattacharyya2020; Wilson et al., Reference Wilson, Bossong, Appiah-Kusi, Petros, Brammer, Perez and Bhattacharyya2019). In the CBD group, mean (s.d.) plasma CBD levels were 126.4 nM (221.8) and 823.0 nM (881.5) at 120 and 300 min after drug intake, respectively (online Supplementary Fig S3). Three CHR individuals exited the scanner prior to the ASL sequence, and two CHR subjects’ data were corrupted at source, leaving n = 14 in the placebo group, n = 14 in the CBD group and n = 19 controls (see online Supplementary CONSORT details).

Table 1. Total sample sociodemographic and clinical characteristics

Abbreviations: CAARMS, Comprehensive Assessment of At-Risk Mental States; CBD, cannabidiol; CHR, Clinical High Risk for Psychosis; N, number of subjects; NA, not applicable; PCP, phencyclidine; STAI-S, State-Trait Anxiety Inventory-State Subscale; THC, Δ9-tetrahydrocannabinol. 1Controls were selected to have minimal drug use and hence were not compared with CHR participants on these parameters; 2Independent t test; 3Pearson chi-squared test; 4Controls tested negative on urine drug screen for all substances tested; 5Cannabis use less than 10 times lifetime (no current users); 6Note that this data are reported for all subjects who had ever used cannabis, regardless of whether they were current users.

Global CBF

There were no significant group differences in mean global gray matter CBF values (ml/100 g/min): healthy control (marginal mean ± s.e.) = 48.96 ± 2.92; CBD = 45.39 ± 2.88; placebo = 47.79 ± 3.27; F(2,40) = 0.38, p = 0.69.

Hippocampal blood flow – pairwise effects of CHR status and CBD

Pairwise t tests examining differences related to CHR status revealed that compared to healthy controls, placebo-treated patients had significantly greater rCBF in the hippocampus bilaterally (right hippocampus: MNI coordinates X = 22 Y = −24 Z = −4, T(26) = 5.29, ZE = 4.32, k = 90, p < 0.001 FWE; left hippocampus: MNI coordinates X = −24 Y = −24 Z = −10, T(26) = 4.01, ZE = 3.50, k = 96, p = 0.009 FWE; Figure 1A). There were no suprathreshold voxels in the CBD v. placebo pairwise comparison.

Figure 1. Hippocampal blood flow across CHR patients receiving placebo, CHR patients receiving CBD and healthy controls. Caption : (A) Increased blood flow (shown in red) in CHR patients in the placebo group relative to healthy controls in right (p < 0.001 FWE) and left hippocampus (p = 0.009 FWE), overlaid on a standard brain template. Hippocampal ROIs are depicted by the inner bounds of the blue circles. (B) Voxels where blood flow followed a linear pattern across groups (placebo > CBD > controls) in right (p = 0.035 FWE) and left hippocampus (p = 0.053 FWE), overlaid on a standard brain template. Hippocampal ROIs are depicted by the inner bounds of the blue circles. The right side of the brain is shown on the right of the axial and coronal images. The left side of the brain is shown in the sagittal images. (C) Plot showing group means ± 95% CIs of the covariate-adjusted mean rCBF values for the right hippocampal cluster (indicated in panel B) as extracted from the F-test design matrix for each subject using the MarsBaR toolbox in SPM (arbitrary units). The adjusted means ± s.d. (arbitrary units) were: placebo (M = 17.81, s.d. = 48.9), CBD (M = 9.59, s.d. = 47.8), and healthy controls (M = −21.98, s.d. = 42.0).

Hippocampal blood flow – between-group linear analyses

Our primary a priori analysis revealed a significant linear relationship in the right hippocampus, such that blood flow was highest in the placebo group, lowest in healthy controls, and intermediate in the CBD group (MNI coordinates X = 24 Y = −24 Z = −6, F(2,39) = 8.01, ZE = 3.03, k = 4, p = 0.035 FWE; Figure 1B, C). The relationship in the left hippocampus was not significant but followed the same pattern (placebo > CBD > controls) at trend-level (X = −26 Y = −24 Z = −10, F(2,39) = 7.30, ZE = 2.87, k = 8, p = 0.053 FWE; Figure 1B).

Exploratory wholebrain analyses

In pairwise analyses for main effect of CHR status, compared to healthy controls, placebo-treated patients had significantly higher CBF in two clusters spanning parts of the bilateral hippocampus, parahippocampal gyrus, midbrain/brainstem, thalamus, cerebellum and left striatum (mostly putamen) and amygdala (2 clusters, both p < 0.01 FWEcluster; Figure 2). In pairwise analyses for the main effect of CBD in CHR, we found significantly higher CBF in left inferior and middle temporal gyri (temporo-occipital parts) and lateral occipital regions in the CBD compared to the placebo group (p = 0.014 FWEcluster; Figure 2). There were no suprathreshold clusters in the wholebrain three-group linear analyses. Supplementary analyses conducted to test the robustness of these findings (using FSL's randomize rather than SPM) showed almost identical significant results for the placebo > control contrast. However, while the cluster found in the CBD > placebo contrast (above) was present at a relaxed statistical threshold, it was not significantly different between the groups (p = 0.15 FWEcluster; see online Supplementary Material).

Figure 2. Differences in CBF related to CHR status (placebo v. healthy controls) and effects of CBD in CHR patients (CBD v. placebo) from wholebrain analyses. Caption: Axial and sagittal sections showing significant clusters of group differences in CBF from wholebrain analyses. Two large significant clusters were identified for the placebo > control contrast (regions shown in red). Cluster 1 spanned portions of the left hippocampus, parahippocampal gyrus, amygdala, midbrain/brainstem, thalamus, putamen, pallidum and cerebellum (cluster 1 peak MNI coordinates X = −26 Y = 10 Z = −8, T(26) = 5.17, ZE = 4.25, k = 735, p = 0.008 FWEcluster). Cluster 2 spanned portions of the right thalamus, parahippocampal gyrus, lingual gyrus, temporal fusiform cortex, cerebellum, midbrain/brainstem and hippocampus (cluster 2 peak MNI coordinates X = 20 Y = −22 Z = −16, T(26) = 4.85, ZE = 4.05, k = 1271, p < 0.001 FWEcluster). One significant cluster was identified in the CBD > placebo analysis (regions shown in yellow), which spanned portions of the left lateral occipital cortex (inferior division) and middle and inferior temporal gyri (temporo-occipital parts) (peak MNI coordinates X = −44 Y = −80 Z = 6, T(21) = 4.51, ZE = 3.75, k = 638, p = 0.014 FWEcluster). There were no significant results for the control > placebo contrast, the placebo > CBD contrast, nor either of the three-way linear contrasts. The right side of the brain is shown on the right of the axial images. The sagittal sections are ordered from right to left hemispheres (top row to bottom row).

Discussion

This is the first study to investigate the effects of CBD on cerebral blood flow in patients at CHR for psychosis. We first established that hippocampal rCBF is elevated in CHR patients under placebo compared to healthy controls. To test our primary hypothesis that CBD would at least partially normalize any such alterations in hippocampal rCBF, we then examined whether a linear relationship existed between the groups. In line with our predictions, our key finding was that hippocampal blood flow was indeed highest in the placebo-treated CHR group, lowest in healthy controls and significantly intermediate in the CBD-treated CHR group. Together, these findings provide the first – albeit preliminary – in vivo evidence that CBD may engage and partially normalize one of the key neurobiological treatment targets for patients at risk of psychosis. Given the current lack of effective pharmacotherapies for CHR patients (Davies et al., Reference Davies, Cipriani, Ioannidis, Radua, Stahl, Provenzani and Fusar-Poli2018a, Reference Davies, Radua, Cipriani, Stahl, Provenzani, McGuire and Fusar-Poli2018b), CBD represents a promising compound for future preventive studies.

Hippocampal blood flow is elevated in CHR patients

Our first key finding was that hippocampal blood flow is increased in CHR (placebo) patients v. controls. This is consistent with studies to have addressed this issue previously (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018, Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016) as well as contemporary models suggesting that hippocampal hyperactivity is present prior to psychosis onset and plays an upstream role in its progression (Lieberman et al., Reference Lieberman, Girgis, Brucato, Moore, Provenzano, Kegeles and Small2018; Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013). In using ROIs based on hippocampal clusters previously found to be altered in CHR patients (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018, Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016), our results provide a further external replication of elevated rCBF in these regions in an independent CHR sample. Notably, in line with prior work (Allen et al., Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016; Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013) we found hyperperfusion in the hippocampus bilaterally, whereas some previous studies using the same hippocampal ROIs find effects only on the right side, both in CHR (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018) and high schizotypy (Modinos et al., Reference Modinos, Egerton, McMullen, McLaughlin, Kumari, Barker and Zelaya2018a) samples.

However, despite substantial evidence of elevated CBV in the hippocampus (and/or specific subfields, particularly CA1) in psychosis (McHugo et al., Reference McHugo, Talati, Armstrong, Vandekar, Blackford, Woodward and Heckers2019; Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013, Reference Schobel, Lewandowski, Corcoran, Moore, Brown, Malaspina and Small2009; Talati et al., Reference Talati, Rane, Kose, Blackford, Gore, Donahue and Heckers2014, Reference Talati, Rane, Skinner, Gore and Heckers2015), elevated hippocampal rCBF is not always found in vivo in patients with first-episode and/or established illness (Bojesen et al., Reference Bojesen, Glenthøj, Sigvard, Tangmose, Raghava, Ebdrup and Rostrup2023; Horn et al., Reference Horn, Federspiel, Wirth, Müller, Wiest, Wang and Strik2009; Ota et al., Reference Ota, Ishikawa, Sato, Okazaki, Maikusa, Hori and Kunugi2014; Pinkham et al., Reference Pinkham, Loughead, Ruparel, Wu, Overton, Gur and Gur2011; Scheef et al., Reference Scheef, Manka, Daamen, Kühn, Maier, Schild and Jessen2010; Talati et al., Reference Talati, Rane, Skinner, Gore and Heckers2015; Walther et al., Reference Walther, Federspiel, Horn, Razavi, Wiest, Dierks and Müller2011) (for reviews and meta-analyses see (Guimarães et al., Reference Guimarães, Machado-de-Sousa, Crippa, Guimarães and Hallak2016; Percie du Sert et al., Reference Percie du Sert, Unrau, Gauthier, Chakravarty, Malla, Lepage and Raucher-Chéné2023; Sukumar et al., Reference Sukumar, Sabesan, Anazodo and Palaniyappan2020)). Why elevated hippocampal rCBF would be more readily observed – so far, at least – in studies of patients at CHR rather than with established psychosis remains unclear. One potential contributing factor is that antipsychotics impact rCBF (Goozée et al., Reference Goozée, Handley, Kempton and Dazzan2014) – but not CBV (Schobel et al., Reference Schobel, Lewandowski, Corcoran, Moore, Brown, Malaspina and Small2009) – and although this is typically reported within basal ganglia (Bojesen et al., Reference Bojesen, Glenthøj, Sigvard, Tangmose, Raghava, Ebdrup and Rostrup2023; Hawkins et al., Reference Hawkins, Wood, Vernon, Bertolino, Sambataro, Dukart and Mehta2017), effects are also seen in hippocampus (Lahti, Holcomb, Weiler, Medoff, & Tamminga, Reference Lahti, Holcomb, Weiler, Medoff and Tamminga2003; Medoff et al., Reference Medoff, Holcomb, Lahti and Tamminga2001). However, several studies have investigated rCBF in antipsychotic-free or -naïve patients (Bojesen et al., Reference Bojesen, Glenthøj, Sigvard, Tangmose, Raghava, Ebdrup and Rostrup2023; Medoff et al., Reference Medoff, Holcomb, Lahti and Tamminga2001; Scheef et al., Reference Scheef, Manka, Daamen, Kühn, Maier, Schild and Jessen2010; Selvaggi et al., Reference Selvaggi, Jauhar, Kotoula, Pepper, Veronese, Santangelo and Howes2022) and few (Medoff et al., Reference Medoff, Holcomb, Lahti and Tamminga2001) report significant hippocampal differences. Another possibility is that the cascading pathophysiology is illness stage-specific and evolves over the course of psychosis progression (Millan et al., Reference Millan, Andrieux, Bartzokis, Cadenhead, Dazzan, Fusar-Poli and Weinberger2016). This would be consistent with evidence that functional changes (observed in the CHR state) precede structural changes (seen after psychosis onset and in those who do not remit), with initial CA1 hypermetabolism spreading to other subfields and extra-hippocampal regions (such as frontal cortex) in those who transition, before hippocampal volume loss and morphological changes become apparent (Ho et al., Reference Ho, Holt, Cheung, Iglesias, Goh, Wang and Zhou2017a, Reference Ho, Iglesias, Sum, Kuswanto, Sitoh, De Souza and Holt2017b; Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013, Reference Schobel, Lewandowski, Corcoran, Moore, Brown, Malaspina and Small2009). Overall, several studies (including the present one) now show that hippocampal rCBF is elevated in people at CHR (Allen et al., Reference Allen, Azis, Modinos, Bossong, Bonoldi, Samson and McGuire2018, Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016), a patient group where important factors such as antipsychotic exposure and illness chronicity (Kraguljac & Lahti, Reference Kraguljac and Lahti2021) are minimal. However, it should be noted that the majority of patients meeting CHR criteria (78% at 3 years, 63% at 10–11 years (Fusar-Poli et al., Reference Fusar-Poli, De Micheli, Signorini, Baldwin, de Pablo and McGuire2020a, Reference Fusar-Poli, Salazar De Pablo, Correll, Meyer-Lindenberg, Millan, Borgwardt and Arango2020b)) do not go on to develop psychosis. As such, further research measuring rCBF and CBV longitudinally over the course of psychosis progression is required to unravel the precise nature, temporal sequence and relevance of these findings to the mechanisms of psychosis risk v. frank illness.

CBD may attenuate hippocampal blood flow

Our second key finding – that hippocampal blood flow in CBD-treated CHR patients is intermediate between controls and placebo-treated patients – is translationally relevant, given previous evidence (above) linking hippocampal hypermetabolism in the CHR state with the onset of psychosis (Schobel et al., Reference Schobel, Chaudhury, Khan, Paniagua, Styner, Asllani and Small2013) and longitudinal reductions in hippocampal CBF associating with CHR remission (Allen et al., Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016). The reduction of hippocampal perfusion (as suggested here) would thus seem a plausible therapeutic target for novel antipsychotic treatments. Elevated hippocampal rCBF and blood volumes are also positively associated with symptom severity across psychosis and CHR patients (Schobel et al., Reference Schobel, Lewandowski, Corcoran, Moore, Brown, Malaspina and Small2009), as well as delusional thinking in non-help-seeking healthy individuals (Wolthusen et al., Reference Wolthusen, Coombs, Boeke, Ehrlich, DeCross, Nasr and Holt2018). A partial normalization of hippocampal rCBF by CBD could, therefore, underlie or contribute to the therapeutic effects of CBD that have been reported in patients with established psychosis (Leweke et al., Reference Leweke, Piomelli, Pahlisch, Muhl, Gerth, Hoyer and Koethe2012; McGuire et al., Reference McGuire, Robson, Cubala, Vasile, Morrison, Barron and Wright2018) (see online Supplementary Material for discussion of potential mechanisms). However, our cross-sectional study was designed and powered to examine acute neurophysiological rather than symptom effects and as such, future longitudinal studies administering CBD to a larger sample are needed to evaluate clinical efficacy.

Our findings are consistent with previous literature on the effects of CBD. Using the same patient and control sample, we previously demonstrated that CBD has effects on task-based BOLD haemodynamic readouts (Bhattacharyya et al., Reference Bhattacharyya, Wilson, Appiah-Kusi, O'Neill, Brammer, Perez and McGuire2018; Davies et al., Reference Davies, Wilson, Appiah-Kusi, Blest-Hopley, Brammer, Perez and Bhattacharyya2020; Wilson et al., Reference Wilson, Bossong, Appiah-Kusi, Petros, Brammer, Perez and Bhattacharyya2019), finding the same commensurate pattern of placebo > CBD > controls (or vice versa) in mediotemporal regions during fear processing and verbal memory fMRI (Bhattacharyya et al., Reference Bhattacharyya, Wilson, Appiah-Kusi, O'Neill, Brammer, Perez and McGuire2018; Davies et al., Reference Davies, Wilson, Appiah-Kusi, Blest-Hopley, Brammer, Perez and Bhattacharyya2020). CBF is intrinsically linked to BOLD responses via neurovascular coupling (Kim, Taylor, Wang, Zou, & Ress, Reference Kim, Taylor, Wang, Zou and Ress2020), but its acquisition does not require the cognitive or other manipulation needed for task-based fMRI contrasts (Alsop et al., Reference Alsop, Detre, Golay, Günther, Hendrikse, Hernandez-Garcia and Zaharchuk2015). As such, our results extend previous work by suggesting that CBD may also attenuate basal resting-state hippocampal activity in CHR patients (see online Supplementary Discussion). Albeit in the context of our linear between-group results, the direction of CBD effects we observed is also in line with two previous SPECT studies, which found significant reductions in hippocampal rCBF following CBD in healthy people and those with anxiety disorders (Crippa et al., Reference Crippa, Nogueira Derenusson, Borduqui Ferrari, Wichert-Ana, Duran, Martin-Santos and Hallak2011, Reference Crippa, Zuardi, Garrido, Wichert-Ana, Guarnieri, Ferrari and Filho Busatto2004). Conversely, the direction of our effects contrasts with the only other study to have examined CBD using ASL, which found a significant increase in hippocampal rCBF in healthy individuals (Bloomfield et al., Reference Bloomfield, Green, Hindocha, Yamamori, Yim, Jones and Freeman2019). In our view, the most likely explanation for this difference is that the effects of CBD differ as a function of the sample population and more specifically, the presence v. absence of baseline pathophysiology. Several lines of disparate evidence support this notion. For example, CBD has been shown to have different effects on reward processing-related activity (Gunasekera et al., Reference Gunasekera, Wilson, Neill, Blest-hopley, Daly and Bhattacharyya2022; Lawn et al., Reference Lawn, Hill, Hindocha, Yim, Yamamori, Jones and Bloomfield2020; Wilson et al., Reference Wilson, Bossong, Appiah-Kusi, Petros, Brammer, Perez and Bhattacharyya2019), GABA levels (Pretzsch et al., Reference Pretzsch, Freyberg, Voinescu, Lythgoe, Horder, Mendez and McAlonan2019a) and resting-state brain activity (Pretzsch et al., Reference Pretzsch, Voinescu, Mendez, Wichers, Ajram, Ivin and McAlonan2019b) across various healthy and clinical populations. Collectively, these findings suggest that the direction of CBD's effects may depend on the specific clinical v. healthy population under study, with CBD potentially having effects in the direction towards normalization in those with baseline dysfunction. A broader implication is that if effects in clinical populations cannot accurately be extrapolated from findings in healthy cohorts, future pharmacological studies to establish group-specific target engagement remain of particular value.

Although we found significant effects in our a priori regions and in the direction that appears to be of therapeutic and translational relevance, it is worth noting that the resulting cluster of voxels (with statistics based on voxel peak) in the linear relationship analyses was small (k = 4), and we did not find any suprathreshold effects in the direct CBD v. placebo pairwise analysis. A significant cluster with greater spatial extent, and significant CBD v. placebo pairwise differences, would have provided more convincing evidence of CBD effects, and thus we await future replication and confirmation/refutation of these findings in future studies with larger sample sizes. However, regarding the latter point, the rationale for performing the three-way linear analyses – as implemented in our previous publications (Bhattacharyya et al., Reference Bhattacharyya, Wilson, Appiah-Kusi, O'Neill, Brammer, Perez and McGuire2018; Davies et al., Reference Davies, Wilson, Appiah-Kusi, Blest-Hopley, Brammer, Perez and Bhattacharyya2020; Wilson et al., Reference Wilson, Bossong, Appiah-Kusi, Petros, Brammer, Perez and Bhattacharyya2019) – was that we do not necessarily expect that a single dose of CBD will fully reverse aberrant rCBF in CHR patients. Rather, we hypothesized that a signal of change towards normalization in the CBD group (i.e. a significant linear relationship, suggestive of ‘partial normalization’ effects) would provide initial evidence of disease-target engagement, in a direction indicative of therapeutic effects. Based on our initial findings here, future studies administering CBD repeatedly over longer durations are warranted.

Exploratory wholebrain results

Outside of the hippocampus, in exploratory wholebrain analyses we found significant hyperperfusion in CHR (placebo) patients compared to controls in each of the major nodes implicated in psychosis pathophysiology by preclinical models and extant literature (Grace & Gomes, Reference Grace and Gomes2019; Lodge & Grace, Reference Lodge and Grace2011). This included the striatum, midbrain, thalamus and cerebellum, as well as bilateral hippocampi. Very few CHR perfusion studies have utilized a wholebrain approach, but one study reported corresponding hyperperfusion in most of these regions (Allen et al., Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016), although another study did not (Kindler et al., Reference Kindler, Schultze-Lutter, Hauf, Dierks, Federspiel, Walther and Hubl2018). Effects in these regions also correspond with results of previous ROI-based studies, which include increased putamen rCBF in CHR patients (Kindler et al., Reference Kindler, Schultze-Lutter, Hauf, Dierks, Federspiel, Walther and Hubl2018) which was correlated with positive symptom severity. In the same sample as the present study, we recently combined hippocampal glutamate data with wholebrain CBF maps and found an atypical relationship between glutamate and striatal-insula perfusion in CHR-placebo patients relative to controls (Davies et al., Reference Davies, Bossong, Martins, Wilson, Appiah-Kusi, Blest-Hopley and Bhattacharyya2023), suggesting that striatal perfusion abnormalities may be linked to aberrant hippocampal neurochemistry. Greater perfusion in the putamen and thalamus has also been identified as a potential marker of genetic susceptibility for schizophrenia spectrum disorders in a neuroimaging twin study (Legind et al., Reference Legind, Broberg, Brouwer, Mandl, Ebdrup, Anhøj and Rostrup2019). Conversely, although both increased (Allen et al., Reference Allen, Chaddock, Egerton, Howes, Bonoldi, Zelaya and McGuire2016) and decreased (Kindler et al., Reference Kindler, Schultze-Lutter, Hauf, Dierks, Federspiel, Walther and Hubl2018) prefrontal perfusion has been observed in CHR and established psychosis groups (Schobel et al., Reference Schobel, Lewandowski, Corcoran, Moore, Brown, Malaspina and Small2009), we did not find differences here in the present exploratory analyses.

In terms of wholebrain CBD effects, we found significantly increased CBF in inferior-temporal and lateral-occipital regions in CBD-treated relative to placebo-treated CHR patients. A previous SPECT study in healthy individuals reported attenuated perfusion in medial-occipital and inferior-temporal regions following CBD, albeit at a relaxed significance threshold (Crippa et al., Reference Crippa, Zuardi, Garrido, Wichert-Ana, Guarnieri, Ferrari and Filho Busatto2004). The exploratory nature of our findings here combined with the paucity of prior literature means that their relevance is uncertain. Moreover, in view of the potential divergent effects of CBD on CBF across samples, these wholebrain effects may well differ in healthy or other clinical populations.

Limitations

In addition to the limited spatial extent of the cluster identified in our primary (linear relationship) results, several further limitations warrant consideration. The first is that our study was parallel-group rather than within-subject. Although we used a randomized, double-blind design and there were no baseline differences between the two CHR groups (including in measures of substance use), the possibility that any between-group differences we observed were attributable to between-subject variability, as opposed to an effect of CBD, cannot be completely excluded. Future work administering both placebo and CBD in the same CHR (and healthy) individuals would address this issue and permit full factorial analyses. Such a design would also rule out potential expectation effects in the CHR placebo group in the contrast with controls. In terms of our patient group, we recruited a representative sample of CHR individuals as typically found in specialist CHR services (Fusar-Poli et al., Reference Fusar-Poli, Spencer, De Micheli, Curzi, Nandha and McGuire2020c). However, the CHR population is clinically heterogeneous (Fusar-Poli et al., Reference Fusar-Poli, Salazar De Pablo, Correll, Meyer-Lindenberg, Millan, Borgwardt and Arango2020b) and thus the effects of CBD may be greater (or different) in specific subgroups of patients. Future studies with larger sample sizes are needed to stratify results by transition status or, for example, the three component subgroups of the CAARMS (Fusar-Poli et al., Reference Fusar-Poli, Salazar De Pablo, Correll, Meyer-Lindenberg, Millan, Borgwardt and Arango2020b). Finally, this study reports on the acute neurophysiological effects of CBD and it is possible that the effects may differ after a sustained period of treatment. Future work by our group aims to address this issue while examining the effects of CBD on psychotic symptoms.

Conclusion

Our findings indicate that a single dose of CBD may partially normalize aberrant hippocampal perfusion in CHR patients, a potential pathophysiological marker implicated in psychosis risk. Moreover, this effect occurred in the same region we show to be altered in CHR patients under placebo relative to healthy controls. CBD therefore merits further investigation as a candidate novel treatment for this group.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0033291723002775.

Acknowledgements

The authors wish to thank the study volunteers for their participation, Brandon Gunasekera (IoPPN, King's College London) for his technical advice, and the radiographers at the Centre for Neuroimaging Sciences, King's College London, who carried out the MRI scans.

Authors’ contributions

Substantial contributions to conception and design (SB, PMG, PA, MGB, FZ), acquisition of data (RW, EAK, GBH), analysis and/or interpretation of data (CD, SB, DM, MGB, FZ), drafting of the article (CD, SB) or revising it critically for important intellectual content (all authors), study supervision (SB). Final approval of the version to be published: all authors. CD and SB agree to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Funding statement

This study was supported by grant MR/J012149/1 from the Medical Research Council (MRC). SB has also received support from the National Institute for Health Research (NIHR) (NIHR Clinician Scientist Award; NIHR CS-11-001), the NIHR Mental Health Biomedical Research Centre at South London and Maudsley National Health Service (NHS) Foundation Trust and King's College London. This study represents independent research supported by the NIHR/Wellcome Trust King's Clinical Research Facility and NIHR Maudsley Biomedical Research Centre at South London and Maudsley NHS Foundation Trust and King's College London. The views expressed are those of the author(s) and not necessarily those of the NHS, NIHR or the Department of Health and Social Care. The funders had no role in the design and conduct of the study; collection, management, analysis, and interpretation of the data; preparation, review, or approval of the manuscript; and decision to submit the manuscript for publication. No other disclosures or any competing financial interests were reported.

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.

Pre-print

A pre-print version of this manuscript was deposited on the medRxiv pre-print server: https://doi.org/10.1101/2023.02.22.23286306.

Open access

For the purposes of open access, the author has applied a Creative Commons Attribution (CC BY) license to any Accepted Author Manuscript version arising from this submission.

References

Allen, P., Azis, M., Modinos, G., Bossong, M. G., Bonoldi, I., Samson, C., … McGuire, P. (2018). Increased resting hippocampal and basal ganglia perfusion in people at ultra high risk for psychosis: Replication in a second cohort. Schizophrenia Bulletin, 44(6), 13231331. https://doi.org/10.1093/schbul/sbx169CrossRefGoogle ScholarPubMed
Allen, P., Chaddock, C. A., Egerton, A., Howes, O. D., Bonoldi, I., Zelaya, F., … McGuire, P. (2016). Resting hyperperfusion of the hippocampus, midbrain, and basal ganglia in people at high risk for psychosis. American Journal of Psychiatry, 173(4), 392399. https://doi.org/10.1176/appi.ajp.2015.15040485CrossRefGoogle ScholarPubMed
Alsop, D. C., Detre, J. A., Golay, X., Günther, M., Hendrikse, J., Hernandez-Garcia, L., … Zaharchuk, G. (2015). Recommended implementation of arterial spin-labeled perfusion MRI for clinical applications: A consensus of the ISMRM Perfusion Study group and the European consortium for ASL in dementia. Magnetic Resonance in Medicine, 73(1), 102116. https://doi.org/10.1002/mrm.25197CrossRefGoogle Scholar
Bergamaschi, M. M., Queiroz, R. H. C., Chagas, M. H. N., De Oliveira, D. C. G., De Martinis, B. S., Kapczinski, F., … Crippa, J. A. S. (2011). Cannabidiol reduces the anxiety induced by simulated public speaking in treatment-nave social phobia patients. Neuropsychopharmacology, 36(6), 12191226. https://doi.org/10.1038/npp.2011.6CrossRefGoogle Scholar
Bhattacharyya, S., Crippa, J. A., Allen, P., Martin-Santos, R., Borgwardt, S., Fusar-Poli, P., … McGuire, P. K. (2012). Induction of psychosis by Δ9-tetrahydrocannabinol reflects modulation of prefrontal and striatal function during attentional salience processing. Archives of General Psychiatry, 69(1), 2736. https://doi.org/10.1001/archgenpsychiatry.2011.161CrossRefGoogle ScholarPubMed
Bhattacharyya, S., Falkenberg, I., Martin-Santos, R., Atakan, Z., Crippa, J. a, Giampietro, V., … McGuire, P. (2015). Cannabinoid modulation of functional connectivity within regions processing attentional salience. Neuropsychopharmacology, 40, 13431352. https://doi.org/10.1038/npp.2014.258CrossRefGoogle ScholarPubMed
Bhattacharyya, S., Fusar-Poli, P., Borgwardt, S., Martin-Santos, R., Nosarti, C., O'Carroll, C., … McGuire, P. (2009). Modulation of mediotemporal and ventrostriatal function in humans by Δ9-tetrahydrocannabinol. Archives of General Psychiatry, 66(4), 442. https://doi.org/10.1001/archgenpsychiatry.2009.17CrossRefGoogle ScholarPubMed
Bhattacharyya, S., Morrison, P. D., Fusar-Poli, P., Martin-Santos, R., Borgwardt, S., Winton-Brown, T., … McGuire, P. K. (2010). Opposite effects of delta-9-tetrahydrocannabinol and cannabidiol on human brain function and psychopathology. Neuropsychopharmacology, 35(3), 764774. https://doi.org/10.1038/npp.2009.184CrossRefGoogle ScholarPubMed
Bhattacharyya, S., Wilson, R., Appiah-Kusi, E., O'Neill, A., Brammer, M., Perez, J., … McGuire, P. (2018). Effect of cannabidiol on medial temporal, midbrain, and striatal dysfunction in people at clinical high risk of psychosis: A randomized clinical trial. JAMA Psychiatry, 75(11), 11071117. https://doi.org/10.1001/jamapsychiatry.2018.2309CrossRefGoogle ScholarPubMed
Bloomfield, M. A. P., Green, S., Hindocha, C., Yamamori, Y., Yim, J. L. L., Jones, A. P. M., … Freeman, T. P. (2019). The effects of acute cannabidiol on cerebral blood flow and its relationship to memory: An arterial spin labelling magnetic resonance imaging study. European Neuropsychopharmacology, 29, S693. https://doi.org/10.1177/0269881120936419Google Scholar
Bojesen, K. B., Glenthøj, B. Y., Sigvard, A. K., Tangmose, K., Raghava, J. M., Ebdrup, B. H., & Rostrup, E. (2023). Cerebral blood flow in striatum is increased by partial dopamine agonism in initially antipsychotic-naïve patients with psychosis. Psychological Medicine, 111. https://doi.org/10.1017/S0033291723000144Google ScholarPubMed
Crippa, J. A., Guimarães, F. S., Campos, A. C., & Zuardi, A. W. (2018). Translational investigation of the therapeutic potential of cannabidiol (CBD): Toward a new age. Frontiers in Immunology, 9(SEP), 116. https://doi.org/10.3389/fimmu.2018.02009CrossRefGoogle Scholar
Crippa, J. A., Nogueira Derenusson, G., Borduqui Ferrari, T., Wichert-Ana, L., Duran, F. L. S., Martin-Santos, R., … Hallak, J. E. C. (2011). Neural basis of anxiolytic effects of cannabidiol (CBD) in generalized social anxiety disorder: A preliminary report. Journal of Psychopharmacology, 25(1), 121130. https://doi.org/10.1177/0269881110379283CrossRefGoogle ScholarPubMed
Crippa, J. A., Zuardi, A. W., Garrido, G. E. J., Wichert-Ana, L., Guarnieri, R., Ferrari, L., … Filho Busatto, G. (2004). Effects of cannabidiol (CBD) on regional cerebral blood flow. Neuropsychopharmacology, 29(2), 417426. https://doi.org/10.1038/sj.npp.1300340CrossRefGoogle ScholarPubMed
Davies, C., & Bhattacharyya, S. (2019). Cannabidiol as a potential treatment for psychosis. Therapeutic Advances in Psychopharmacology, 9, 116. https://doi.org/10.1177/2045125319881916CrossRefGoogle ScholarPubMed
Davies, C., Bossong, M. G., Martins, D., Wilson, R., Appiah-Kusi, E., Blest-Hopley, G., … Bhattacharyya, S. (2023). Hippocampal glutamate, resting perfusion and the effects of cannabidiol in psychosis risk. Schizophrenia Bulletin Open, sgad022. https://doi.org/10.1093/schizbullopen/sgad022CrossRefGoogle Scholar
Davies, C., Cipriani, A., Ioannidis, J. P. A., Radua, J., Stahl, D., Provenzani, U., … Fusar-Poli, P. (2018a). Lack of evidence to favor specific preventive interventions in psychosis: A network meta-analysis. World Psychiatry, 17(2), 196209. https://doi.org/10.1002/wps.20526CrossRefGoogle ScholarPubMed
Davies, C., Radua, J., Cipriani, A., Stahl, D., Provenzani, U., McGuire, P., & Fusar-Poli, P. (2018b). Efficacy and acceptability of interventions for attenuated positive psychotic symptoms in individuals at clinical high risk of psychosis: A network meta-analysis. Frontiers in Psychiatry, 9(JUN), 117. https://doi.org/10.3389/fpsyt.2018.00187CrossRefGoogle ScholarPubMed
Davies, C., Wilson, R., Appiah-Kusi, E., Blest-Hopley, G., Brammer, M., Perez, J., … Bhattacharyya, S. (2020). A single dose of cannabidiol modulates medial temporal and striatal function during fear processing in people at clinical high risk for psychosis. Translational Psychiatry, 10(1), 311. https://doi.org/10.1038/s41398-020-0862-2CrossRefGoogle ScholarPubMed
D'Souza, D. C., Perry, E., MacDougall, L., Ammerman, Y., Cooper, T., Wu, Y., … Krystal, J. H. (2004). The psychotomimetic effects of intravenous delta-9-tetrahydrocannabinol in healthy individuals: Implications for psychosis. Neuropsychopharmacology, 29(8), 15581572. https://doi.org/10.1038/sj.npp.1300496CrossRefGoogle ScholarPubMed
Englund, A., Morrison, P. D., Nottage, J., Hague, D., Kane, F., Bonaccorso, S., … Kapur, S. (2013). Cannabidiol inhibits THC-elicited paranoid symptoms and hippocampal-dependent memory impairment. Journal of Psychopharmacology, 27(1), 1927. https://doi.org/10.1177/0269881112460109CrossRefGoogle ScholarPubMed
Fusar-Poli, P., Crippa, J. A., Bhattacharyya, S., Borgwardt, S. J., Allen, P., Martin-Santos, R., … McGuire, P. K. (2009). Distinct effects of Δ9-tetrahydrocannabinol and cannabidiol on neural activation during emotional processing. Archives of General Psychiatry, 66(1), 95. https://doi.org/10.1001/archgenpsychiatry.2008.519CrossRefGoogle ScholarPubMed
Fusar-Poli, P., De Micheli, A., Signorini, L., Baldwin, H., de Pablo, G. S., & McGuire, P. (2020a). Real-world long-term outcomes in individuals at clinical risk for psychosis: The case for extending duration of care. EClinicalMedicine, 28(100578), 19. https://doi.org/10.1016/j.eclinm.2020.100578CrossRefGoogle ScholarPubMed
Fusar-Poli, P., Salazar De Pablo, G., Correll, C. U., Meyer-Lindenberg, A., Millan, M. J., Borgwardt, S., … Arango, C. (2020b). Prevention of psychosis: Advances in detection, prognosis, and intervention. JAMA Psychiatry, 77(7), 755765. https://doi.org/10.1001/jamapsychiatry.2019.4779CrossRefGoogle ScholarPubMed
Fusar-Poli, P., Spencer, T., De Micheli, A., Curzi, V., Nandha, S., & McGuire, P. (2020c). Outreach and support in South-London (OASIS) 2001—2020: Twenty years of early detection, prognosis and preventive care for young people at risk of psychosis. European Neuropsychopharmacology, 39, 111122. https://doi.org/10.1016/j.euroneuro.2020.08.002CrossRefGoogle ScholarPubMed
Goozée, R., Handley, R., Kempton, M. J., & Dazzan, P. (2014). A systematic review and meta-analysis of the effects of antipsychotic medications on regional cerebral blood flow (rCBF) in schizophrenia: Association with response to treatment. Neuroscience and Biobehavioral Reviews, 43, 118136. https://doi.org/10.1016/j.neubiorev.2014.03.014CrossRefGoogle ScholarPubMed
Grace, A. A., & Gomes, F. V. (2019). The circuitry of dopamine system regulation and its disruption in schizophrenia: Insights into treatment and prevention. Schizophrenia Bulletin, 45(1), 148157. https://doi.org/10.1093/schbul/sbx199CrossRefGoogle ScholarPubMed
Guimarães, T. M., Machado-de-Sousa, J. P., Crippa, J. A. S., Guimarães, M. R. C., & Hallak, J. E. C. (2016). Arterial spin labeling in patients with schizophrenia: A systematic review. Archives of Clinical Psychiatry (São Paulo), 43, 151156. https://doi.org/10.1590/0101-60830000000103CrossRefGoogle Scholar
Gunasekera, B., Davies, C., Martin-Santos, R., & Bhatthacharyya, S. (2020). The Yin and Yang of Cannabis—A systematic review of human neuroimaging evidence of the differential effects of delta-9-tetrahydrocannabinol and cannabidiol. Biological Psychiatry: Cognitive Neuroscience and Neuroimaging, 6(6), 636645. https://doi.org/10.1016/j.bpsc.2020.10.007Google ScholarPubMed
Gunasekera, B., Wilson, R., Neill, A. O., Blest-hopley, G., Daly, O. O., & Bhattacharyya, S. (2022). Cannabidiol attenuates insular activity during motivational salience processing in patients with early psychosis. Psychological Medicine, 53(10), 47324741. https://doi.org/10.1017/S0033291722001672CrossRefGoogle ScholarPubMed
Hawkins, P. C. T., Wood, T. C., Vernon, A. C., Bertolino, A., Sambataro, F., Dukart, J., … Mehta, M. A. (2017). An investigation of regional cerebral blood flow and tissue structure changes after acute administration of antipsychotics in healthy male volunteers. Human Brain Mapping, 39(1), 319331. https://doi.org/10.1002/hbm.23844CrossRefGoogle ScholarPubMed
Ho, N. F., Holt, D. J., Cheung, M., Iglesias, J. E., Goh, A., Wang, M., … Zhou, J. (2017a). Progressive decline in hippocampal CA1 volume in individuals at ultra-high-risk for psychosis who do not remit: Findings from the longitudinal youth at risk study. Neuropsychopharmacology, 42(6), 13611370. https://doi.org/10.1038/npp.2017.5CrossRefGoogle Scholar
Ho, N. F., Iglesias, J. E., Sum, M. Y., Kuswanto, C. N., Sitoh, Y. Y., De Souza, J., … Holt, D. J. (2017b). Progression from selective to general involvement of hippocampal subfields in schizophrenia. Molecular Psychiatry, 22(1), 142152. https://doi.org/10.1038/mp.2016.4CrossRefGoogle ScholarPubMed
Horn, H., Federspiel, A., Wirth, M., Müller, T. J., Wiest, R., Wang, J.-J., & Strik, W. (2009). Structural and metabolic changes in language areas linked to formal thought disorder. The British Journal of Psychiatry, 194(2), 130138. https://doi.org/10.1192/bjp.bp.107.045633CrossRefGoogle ScholarPubMed
Howell, D. C. (2010). Statistical methods for psychology (7th ed). Belmont, CA, Australia: Thomson Wadsworth.Google Scholar
Howes, O. D., & Kapur, S. (2009). The dopamine hypothesis of schizophrenia: Version III - The final common pathway. Schizophrenia Bulletin, 35(3), 549562. https://doi.org/10.1093/schbul/sbp006CrossRefGoogle ScholarPubMed
Kim, J. H., Taylor, A. J., Wang, D. J., Zou, X., & Ress, D. (2020). Dynamics of the cerebral blood flow response to brief neural activity in human visual cortex. Journal of Cerebral Blood Flow & Metabolism, 40(9), 18231837. https://doi.org/10.1177/0271678X19869034CrossRefGoogle ScholarPubMed
Kindler, J., Schultze-Lutter, F., Hauf, M., Dierks, T., Federspiel, A., Walther, S., … Hubl, D. (2018). Increased striatal and reduced prefrontal cerebral blood flow in clinical high risk for psychosis. Schizophrenia Bulletin, 44(1), 182192. https://doi.org/10.1093/schbul/sbx070CrossRefGoogle ScholarPubMed
Knight, S., Mccutcheon, R., Dwir, D., Grace, A. A., Daly, O. O., Mcguire, P., … Modinos, G. (2022). Hippocampal circuit dysfunction in psychosis. Translational Psychiatry, 12(344), 113. https://doi.org/10.1038/s41398-022-02115-5Google ScholarPubMed
Kraguljac, N. V., & Lahti, A. C. (2021). Neuroimaging as a window into the pathophysiological mechanisms of schizophrenia. Frontiers in Psychiatry, 12, 613764. https://doi.org/10.3389/fpsyt.2021.613764CrossRefGoogle ScholarPubMed
Lahti, A. C., Holcomb, H. H., Weiler, M. A., Medoff, D. R., & Tamminga, C. A. (2003). Functional effects of antipsychotic drugs: Comparing clozapine with haloperidol. Biological Psychiatry, 53(7), 601608. https://doi.org/10.1016/S0006-3223(02)01602-5CrossRefGoogle ScholarPubMed
Lawn, W., Hill, J., Hindocha, C., Yim, J., Yamamori, Y., Jones, G., … Bloomfield, M. A. (2020). The acute effects of cannabidiol on the neural correlates of reward anticipation and feedback in healthy volunteers. Journal of Psychopharmacology, 34(9), 969980. https://doi.org/10.1177/0269881120944148CrossRefGoogle ScholarPubMed
Legind, C. S., Broberg, B. V., Brouwer, R., Mandl, R. C. W., Ebdrup, B. H., Anhøj, S. J., … Rostrup, E. (2019). Heritability of cerebral blood flow and the correlation to schizophrenia spectrum disorders: A pseudo-continuous arterial spin labeling twin study. Schizophrenia Bulletin, 45(6), 12311241. https://doi.org/10.1093/schbul/sbz007CrossRefGoogle ScholarPubMed
Leweke, F. M., Piomelli, D., Pahlisch, F., Muhl, D., Gerth, C. W., Hoyer, C., … Koethe, D. (2012). Cannabidiol enhances anandamide signaling and alleviates psychotic symptoms of schizophrenia. Translational Psychiatry, 2(3), e94e94. https://doi.org/10.1038/tp.2012.15CrossRefGoogle ScholarPubMed
Lieberman, J. A., Girgis, R. R., Brucato, G., Moore, H., Provenzano, F., Kegeles, L., … Small, S. A. (2018). Hippocampal dysfunction in the pathophysiology of schizophrenia: A selective review and hypothesis for early detection and intervention. Molecular Psychiatry, 23(8), 17641772. https://doi.org/10.1038/mp.2017.249CrossRefGoogle ScholarPubMed
Lisman, J. E., Coyle, J. T., Green, R. W., Javitt, D. C., Benes, F. M., Heckers, S., & Grace, A. a. (2008). Circuit-based framework for understanding neurotransmitter and risk gene interactions in schizophrenia. Trends in Neurosciences, 31(5), 234242. https://doi.org/10.1016/j.tins.2008.02.005CrossRefGoogle ScholarPubMed
Lodge, D. J., & Grace, A. A. (2007). Aberrant hippocampal activity underlies the dopamine dysregulation in an animal model of schizophrenia. Journal of Neuroscience, 27(42), 1142411430. https://doi.org/10.1523/JNEUROSCI.2847-07.2007CrossRefGoogle Scholar
Lodge, D. J., & Grace, A. A. (2011). Hippocampal dysregulation of dopamine system function and the pathophysiology of schizophrenia. Trends in Pharmacological Sciences, 32(9), 507513. https://doi.org/10.1016/j.tips.2011.05.001CrossRefGoogle ScholarPubMed
Martin-Santos, R., Crippa, J. A., Batalla, A., Bhattacharyya, S., Atakan, Z., Borgwardt, S., … McGuire, P. K. (2012). Acute effects of a single, oral dose of d9–tetrahydrocannabinol (THC) and cannabidiol (CBD) administration in healthy volunteers. Current Pharmaceutical Design, 18(32), 49664979. https://doi.org/10.2174/138161212802884780CrossRefGoogle ScholarPubMed
McGuire, P., Robson, P., Cubala, W. J., Vasile, D., Morrison, P. D., Barron, R., … Wright, S. (2018). Cannabidiol (CBD) as an adjunctive therapy in schizophrenia: A multicenter randomized controlled trial. American Journal of Psychiatry, 175(3), 225231. https://doi.org/10.1176/appi.ajp.2017.17030325CrossRefGoogle ScholarPubMed
McHugo, M., Talati, P., Armstrong, K., Vandekar, S. N., Blackford, J. U., Woodward, N. D., & Heckers, S. (2019). Hyperactivity and reduced activation of anterior hippocampus in early psychosis. American Journal of Psychiatry, 176(12), 10301038. https://doi.org/10.1176/appi.ajp.2019.19020151CrossRefGoogle ScholarPubMed
Medoff, D. R., Holcomb, H. H., Lahti, A. C., & Tamminga, C. A. (2001). Probing the human hippocampus using rCBF: Contrasts in schizophrenia. Hippocampus, 11(5), 543550. https://doi.org/10.1002/hipo.1070CrossRefGoogle ScholarPubMed
Millan, M. J., Andrieux, A., Bartzokis, G., Cadenhead, K., Dazzan, P., Fusar-Poli, P., … Weinberger, D. (2016). Altering the course of schizophrenia: Progress and perspectives. Nature Reviews Drug Discovery, 15(7), 485515. https://doi.org/10.1038/nrd.2016.28CrossRefGoogle Scholar
Millar, S. A., Stone, N. L., Yates, A. S., & O'Sullivan, S. E. (2018). A systematic review on the pharmacokinetics of cannabidiol in humans. Frontiers in Pharmacology, 9, 1365. https://doi.org/10.3389/fphar.2018.01365CrossRefGoogle ScholarPubMed
Modinos, G., Allen, P., Grace, A. A., & McGuire, P. (2015). Translating the MAM model of psychosis to humans. Trends in Neurosciences, 38(3), 129138. https://doi.org/10.1016/j.tins.2014.12.005CrossRefGoogle ScholarPubMed
Modinos, G., Egerton, A., McMullen, K., McLaughlin, A., Kumari, V., Barker, G. J., … Zelaya, F. (2018a). Increased resting perfusion of the hippocampus in high positive schizotypy: A pseudocontinuous arterial spin labeling study. Human Brain Mapping, 39, 40554064. https://doi.org/10.1002/hbm.24231CrossRefGoogle ScholarPubMed
Modinos, G., Richter, A., Egerton, A., Bonoldi, I., Azis, M., Antoniades, M., … McGuire, P. (2021). Interactions between hippocampal activity and striatal dopamine in people at clinical high risk for psychosis: Relationship to adverse outcomes. Neuropsychopharmacology, 46(8), 14681474. https://doi.org/10.1038/s41386-021-01019-0CrossRefGoogle ScholarPubMed
Modinos, G., Şimşek, F., Azis, M., Bossong, M., Bonoldi, I., Samson, C., … McGuire, P. (2018b). Prefrontal GABA levels, hippocampal resting perfusion and the risk of psychosis. Neuropsychopharmacology, 43(13), 26522659. https://doi.org/10.1038/s41386-017-0004-6CrossRefGoogle ScholarPubMed
Morrison, P. D., Zois, V., McKeown, D. A., Lee, T. D., Holt, D. W., Powell, J. F., … Murray, R. M. (2009). The acute effects of synthetic intravenous Delta9-tetrahydrocannabinol on psychosis, mood and cognitive functioning. Psychological Medicine, 39(10), 16071616. https://doi.org/10.1017/S0033291709005522CrossRefGoogle ScholarPubMed
O'Neill, A., Wilson, R., Blest-Hopley, G., Annibale, L., Colizzi, M., Brammer, M., … Bhattacharyya, S. (2021). Normalization of mediotemporal and prefrontal activity, and mediotemporal-striatal connectivity, may underlie antipsychotic effects of cannabidiol in psychosis. Psychological Medicine, 51(4), 596606. https://doi.org/10.1017/S0033291719003519CrossRefGoogle ScholarPubMed
Ota, M., Ishikawa, M., Sato, N., Okazaki, M., Maikusa, N., Hori, H., … Kunugi, H. (2014). Pseudo-continuous arterial spin labeling MRI study of schizophrenic patients. Schizophrenia Research, 154(1), 113118. https://doi.org/10.1016/j.schres.2014.01.035CrossRefGoogle ScholarPubMed
Percie du Sert, O., Unrau, J., Gauthier, C. J., Chakravarty, M., Malla, A., Lepage, M., & Raucher-Chéné, D. (2023). Cerebral blood flow in schizophrenia: A systematic review and meta-analysis of MRI-based studies. Progress in Neuro-Psychopharmacology and Biological Psychiatry, 121, 110669. https://doi.org/10.1016/j.pnpbp.2022.110669CrossRefGoogle ScholarPubMed
Pinkham, A., Loughead, J., Ruparel, K., Wu, W.-C., Overton, E., Gur, R., & Gur, R. (2011). Resting quantitative cerebral blood flow in schizophrenia measured by pulsed arterial spin labeling perfusion MRI. Psychiatry Research: Neuroimaging, 194(1), 6472. https://doi.org/10.1016/j.pscychresns.2011.06.013CrossRefGoogle ScholarPubMed
Pretzsch, C. M., Freyberg, J., Voinescu, B., Lythgoe, D., Horder, J., Mendez, M. A., … McAlonan, G. M. (2019a). Effects of cannabidiol on brain excitation and inhibition systems; a randomised placebo-controlled single dose trial during magnetic resonance spectroscopy in adults with and without autism spectrum disorder. Neuropsychopharmacology, 44(8), 13981405. https://doi.org/10.1038/s41386-019-0333-8CrossRefGoogle ScholarPubMed
Pretzsch, C. M., Voinescu, B., Mendez, M. A., Wichers, R., Ajram, L., Ivin, G., … McAlonan, G. M. (2019b). The effect of cannabidiol (CBD) on low-frequency activity and functional connectivity in the brain of adults with and without autism spectrum disorder (ASD). Journal of Psychopharmacology, 33(9), 11411148. https://doi.org/10.1177/0269881119858306CrossRefGoogle ScholarPubMed
Scheef, L., Manka, C., Daamen, M., Kühn, K.-U., Maier, W., Schild, H. H., & Jessen, F. (2010). Resting-State perfusion in nonmedicated schizophrenic patients: A continuous arterial spin-labeling 3.0-T MR study. Radiology, 256(1), 253260. https://doi.org/10.1148/radiol.10091224CrossRefGoogle Scholar
Schobel, S. A., Chaudhury, N. H., Khan, U. A., Paniagua, B., Styner, M. A., Asllani, I., … Small, S. A. (2013). Imaging patients with psychosis and a mouse model establishes a spreading pattern of hippocampal dysfunction and implicates glutamate as a driver. Neuron, 78(1), 8193. https://doi.org/10.1016/j.neuron.2013.02.011CrossRefGoogle Scholar
Schobel, S. A., Lewandowski, N. M., Corcoran, C. M., Moore, H., Brown, T., Malaspina, D., & Small, S. A. (2009). Differential targeting of the CA1 subfield of the hippocampal formation by schizophrenia and related psychotic disorders. Archives of General Psychiatry, 66(9), 938946. https://doi.org/10.1001/archgenpsychiatry.2009.115CrossRefGoogle ScholarPubMed
Selvaggi, P., Jauhar, S., Kotoula, V., Pepper, F., Veronese, M., Santangelo, B., … Howes, O. D. (2022). Reduced cortical cerebral blood flow in antipsychotic-free first-episode psychosis and relationship to treatment response. Psychological Medicine, 53(11), 52355245. https://doi.org/10.1017/S0033291722002288CrossRefGoogle ScholarPubMed
Sherif, M., Radhakrishnan, R., D'Souza, D. C., & Ranganathan, M. (2016). Human laboratory studies on cannabinoids and psychosis. Biological Psychiatry, 79(7), 526538. https://doi.org/10.1016/j.biopsych.2016.01.011CrossRefGoogle ScholarPubMed
Sukumar, N., Sabesan, P., Anazodo, U., & Palaniyappan, L. (2020). Neurovascular uncoupling in schizophrenia: A bimodal meta-analysis of brain perfusion and glucose metabolism. Frontiers in Psychiatry, 11, 754. https://doi.org/10.3389/fpsyt.2020.00754CrossRefGoogle ScholarPubMed
Talati, P., Rane, S., Kose, S., Blackford, J. U., Gore, J., Donahue, M. J., & Heckers, S. (2014). Increased hippocampal CA1 cerebral blood volume in schizophrenia. NeuroImage: Clinical, 5, 359364. https://doi.org/10.1016/j.nicl.2014.07.004CrossRefGoogle ScholarPubMed
Talati, P., Rane, S., Skinner, J., Gore, J., & Heckers, S. (2015). Increased hippocampal blood volume and normal blood flow in schizophrenia. Psychiatry Research - Neuroimaging, 232(3), 219225. https://doi.org/10.1016/j.pscychresns.2015.03.007CrossRefGoogle ScholarPubMed
Tamminga, C. A., Stan, A. D., & Wagner, A. D. (2010). The hippocampal formation in schizophrenia. American Journal of Psychiatry, 167(10), 11781193. https://doi.org/10.1176/appi.ajp.2010.09081187CrossRefGoogle ScholarPubMed
Vargas, T., Dean, D. J., Osborne, K. J., Gupta, T., Ristanovic, I., Ozturk, S., … Mittal, V. A. (2017). Hippocampal subregions across the psychosis spectrum. Schizophrenia Bulletin, 44(5), 10911099. https://doi.org/10.1093/schbul/sbx160CrossRefGoogle Scholar
Walther, S., Federspiel, A., Horn, H., Razavi, N., Wiest, R., Dierks, T., … Müller, T. J. (2011). Resting state cerebral blood flow and objective motor activity reveal basal ganglia dysfunction in schizophrenia. Psychiatry Research: Neuroimaging, 192(2), 117124. https://doi.org/10.1016/j.pscychresns.2010.12.002CrossRefGoogle ScholarPubMed
Wilson, R., Bossong, M. G., Appiah-Kusi, E., Petros, N., Brammer, M., Perez, J., … Bhattacharyya, S. (2019). Cannabidiol attenuates insular dysfunction during motivational salience processing in subjects at clinical high risk for psychosis. Translational Psychiatry, 9(1), 203. https://doi.org/10.1038/s41398-019-0534-2CrossRefGoogle ScholarPubMed
Wolthusen, R. P. F., Coombs, G., Boeke, E. A., Ehrlich, S., DeCross, S. N., Nasr, S., & Holt, D. J. (2018). Correlation between levels of delusional beliefs and perfusion of the hippocampus and an associated network in a non–help-seeking population. Biological Psychiatry: Cognitive Neuroscience and Neuroimaging, 3(2), 178186. https://doi.org/10.1016/j.bpsc.2017.06.007Google Scholar
Yung, A. R., Pan Yuen, H., McGorry, P. D., Phillips, L. J., Kelly, D., Dell'olio, M., … Buckby, J. (2005). Mapping the onset of psychosis: The comprehensive assessment of at-risk mental states. Australian & New Zealand Journal of Psychiatry, 39(11–12), 964971. https://doi.org/10.1080/j.1440-1614.2005.01714.xCrossRefGoogle ScholarPubMed
Figure 0

Table 1. Total sample sociodemographic and clinical characteristics

Figure 1

Figure 1. Hippocampal blood flow across CHR patients receiving placebo, CHR patients receiving CBD and healthy controls. Caption: (A) Increased blood flow (shown in red) in CHR patients in the placebo group relative to healthy controls in right (p < 0.001 FWE) and left hippocampus (p = 0.009 FWE), overlaid on a standard brain template. Hippocampal ROIs are depicted by the inner bounds of the blue circles. (B) Voxels where blood flow followed a linear pattern across groups (placebo > CBD > controls) in right (p = 0.035 FWE) and left hippocampus (p = 0.053 FWE), overlaid on a standard brain template. Hippocampal ROIs are depicted by the inner bounds of the blue circles. The right side of the brain is shown on the right of the axial and coronal images. The left side of the brain is shown in the sagittal images. (C) Plot showing group means ± 95% CIs of the covariate-adjusted mean rCBF values for the right hippocampal cluster (indicated in panel B) as extracted from the F-test design matrix for each subject using the MarsBaR toolbox in SPM (arbitrary units). The adjusted means ± s.d. (arbitrary units) were: placebo (M = 17.81, s.d. = 48.9), CBD (M = 9.59, s.d. = 47.8), and healthy controls (M = −21.98, s.d. = 42.0).

Figure 2

Figure 2. Differences in CBF related to CHR status (placebo v. healthy controls) and effects of CBD in CHR patients (CBD v. placebo) from wholebrain analyses. Caption: Axial and sagittal sections showing significant clusters of group differences in CBF from wholebrain analyses. Two large significant clusters were identified for the placebo > control contrast (regions shown in red). Cluster 1 spanned portions of the left hippocampus, parahippocampal gyrus, amygdala, midbrain/brainstem, thalamus, putamen, pallidum and cerebellum (cluster 1 peak MNI coordinates X = −26 Y = 10 Z = −8, T(26) = 5.17, ZE = 4.25, k = 735, p = 0.008 FWEcluster). Cluster 2 spanned portions of the right thalamus, parahippocampal gyrus, lingual gyrus, temporal fusiform cortex, cerebellum, midbrain/brainstem and hippocampus (cluster 2 peak MNI coordinates X = 20 Y = −22 Z = −16, T(26) = 4.85, ZE = 4.05, k = 1271, p < 0.001 FWEcluster). One significant cluster was identified in the CBD > placebo analysis (regions shown in yellow), which spanned portions of the left lateral occipital cortex (inferior division) and middle and inferior temporal gyri (temporo-occipital parts) (peak MNI coordinates X = −44 Y = −80 Z = 6, T(21) = 4.51, ZE = 3.75, k = 638, p = 0.014 FWEcluster). There were no significant results for the control > placebo contrast, the placebo > CBD contrast, nor either of the three-way linear contrasts. The right side of the brain is shown on the right of the axial images. The sagittal sections are ordered from right to left hemispheres (top row to bottom row).

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