SchizophreniaHealthy VolunteersPsilocybin

Psilocybin-Induced Deficits in Automatic and Controlled Inhibition are Attenuated by Ketanserin in Healthy Human Volunteers

This placebo-controlled, double-blind study (n=16) investigated the effects of psilocybin (18.2mg/70kg) on sensorimotor gating, an automatic ability to filter unnecessary information, and controlled response inhibition, a deliberate ability to ignore conflicting information in healthy volunteers. Psilocybin disrupted both of these processes, and this effect was reversed by selectively blocking the serotonergic pathway with ketanserin (40mg) pretreatment.

Authors

  • Franz Vollenweider
  • Matthias Kometer
  • Boris Quednow

Published

Neuropsychopharmacology
individual Study

Abstract

Introduction

The serotonin-2A receptor (5-HT2AR) has been implicated in the pathogenesis of schizophrenia and related inhibitory gating and behavioural inhibition deficits of schizophrenia patients. The hallucinogen psilocybin disrupts automatic forms of sensorimotor gating and response inhibition in humans, but it is unclear so far whether the 5-HT2AR or 5-HT1AR agonist properties of its bioactive metabolite psilocin account for these effects. Thus, we investigated whether psilocybin-induced deficits in automatic and controlled inhibition in healthy humans could be attenuated by the 5-HT2A/2CR antagonist ketanserin.

Methods

A total of 16 healthy participants received placebo, ketanserin (40 mg p.o.), psilocybin (260 μg/kg p.o.), or psilocybin plus ketanserin in a double-blind, randomized, and counterbalanced order. Sensorimotor gating was measured by prepulse inhibition (PPI) of the acoustic startle response. The effects on psychopathological core dimensions and behavioural inhibition were assessed by the altered states of consciousness questionnaire (5D-ASC), and the Color-Word Stroop Test.

Results

Psilocybin decreased PPI at short lead intervals (30 ms), increased all 5D-ASC scores, and selectively increased errors in the interference condition of the Stroop Test. Stroop interference and Stroop effect of the response latencies were increased under psilocybin as well. Psilocybin-induced alterations were attenuated by ketanserin pretreatment, whereas ketanserin alone had no significant effects.

Discussion

These findings suggest that the disrupting effects of psilocybin on automatic and controlled inhibition processes are attributable to 5-HT2AR stimulation. Sensorimotor gating and attentional control deficits of schizophrenia patients might be due to changes within the 5-HT2AR system.

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Research Summary of 'Psilocybin-Induced Deficits in Automatic and Controlled Inhibition are Attenuated by Ketanserin in Healthy Human Volunteers'

Editorial

βBlossom's Take

This study is useful because it ties a classic psychedelic effect to a specific receptor mechanism and a specific cognitive domain. By showing that ketanserin attenuates psilocybin-related inhibition deficits, it strengthens the case for 5-HT2A involvement without collapsing the whole experience into one receptor story.

Introduction

Automatic and controlled information-processing deficits, including impairments in early and late inhibitory gating, are considered core features of schizophrenia and have been linked to the serotonin system. Quednow and colleagues note that early automatic inhibition (sensorimotor gating) and controlled behavioural inhibition have been associated specifically with serotonin-2A receptors (5-HT2A R), and that changes at this receptor might contribute to the inhibitory deficits seen in schizophrenia. The hallucinogen psilocybin is metabolised to psilocin, which acts at multiple 5-HT receptor subtypes including 5-HT2A and 5-HT1A, and prior studies have shown that psilocybin alters prepulse inhibition (PPI) and certain measures of cognitive control in humans; however, it remained unclear which receptor actions (5-HT2A vs 5-HT1A or others) mediate these effects. This study set out to test whether the 5-HT2A/2C receptor antagonist ketanserin would attenuate psilocybin-induced deficits in automatic and controlled inhibition in healthy volunteers. Using a placebo-controlled, double-blind, randomized, counterbalanced design, the investigators examined effects on sensorimotor gating (PPI), behavioural inhibition and attentional control (a trial-by-trial Color–Word Stroop Test), and subjective altered states of consciousness (5D-ASC), comparing placebo, ketanserin, psilocybin, and psilocybin plus ketanserin conditions. The working hypothesis was that ketanserin pretreatment would reduce psilocybin-induced disruptions of PPI and Stroop interference and prevent the altered state of consciousness induced by psilocybin.

Methods

Sixteen healthy volunteers (13 males, 3 females; mean age 29.7 years, range 24–39), mostly students or academics, were recruited and screened for medical and psychiatric health. Screening included medical examination, ECG, blood tests, a semi-structured psychiatric interview, and psychometric questionnaires; high scores on FPI subscales associated with adverse reactions to hallucinogens were exclusionary but did not lead to exclusions in this sample. Limited prior recreational drug exposure was reported by a few participants. The study received ethical approval and participants gave written informed consent. Psilocybin capsules (prepared as 1 mg and 5 mg doses) and ketanserin (40 mg, oral) plus matched lactose placebo were administered in identical gelatin capsules. Each subject completed four experimental sessions separated by 4-week intervals in a randomized, counterbalanced, double-blind manner, receiving: placebo, psilocybin (reported in the extracted text as 260 mg/kg, oral), ketanserin (40 mg, oral), and psilocybin plus ketanserin. Ketanserin or placebo was given approximately 1 hour after arrival (0900 hours) and psilocybin or placebo given 40 minutes later. Startle/PPI measures were taken 60 minutes after psilocybin administration, the Stroop task at 85 minutes, and the 5D-ASC questionnaire at about 125 minutes, aligning with the reported plateau of psilocybin effects. Prepulse inhibition of the acoustic startle response was assessed in a 15-minute session with 52 trials presented in pseudorandom order on a continuous 70-dB background. The session included pulse-alone trials and three trial types: pulse-alone, prepulse–pulse trials (prepulse durations 20 ms, prepulse intensities 78 dB or 86 dB, interstimulus intervals (ISIs) 30 ms or 120 ms), and no-stimulus trials. Prepulse intensity conditions were pooled for analysis. Startle measures analysed were mean startle reactivity, % habituation, and %PPI (standard formula). Trials with no recorded startle were counted as errors and subjects with >50% error/rejections would have been excluded; none were excluded. Subjective effects were measured with the 5D-ASC visual-analogue questionnaire assessing oceanic boundlessness (OB), anxious ego dissolution (AED), and visionary restructuralization (VR). Cognitive control was tested using a computerized trial-by-trial Color–Word Stroop Test with 192 trials across four conditions (congruent, conflict, neutral non-word XXXX, neutral word), with spoken responses recorded for reaction time (RT) and errors. Stroop facilitation, interference, and total Stroop effect were computed from condition contrasts. Statistical analysis used repeated-measures ANOVA for startle/PPI (factors: drug, prepulse intensity, ISI), for Stroop (drug, condition), and for 5D-ASC (drug, dimension), with Tukey post-hoc tests where indicated; Pearson correlations explored relationships between PPI, Stroop measures, and 5D-ASC change scores. Significance threshold was p<0.05.

Results

Psilocybin produced robust subjective alterations on the 5D-ASC. A two-way ANOVA (drug by 5D-ASC dimension) showed a main effect of drug (F(3,45)=48.3, p<0.0001) and post-hoc tests indicated psilocybin versus placebo increases on all scales (all p<0.0002). The effect was most pronounced on oceanic boundlessness (OB) (drug by dimension interaction F(6,90)=17.2, p<0.0001). Ketanserin alone did not induce symptoms but significantly reduced psilocybin-induced psychotomimetic effects on OB and VR (psilocybin vs ketanserin+psilocybin, both p<0.0002); reduction of AED was present but not significant overall, although subscale analyses showed ketanserin significantly attenuated psilocybin-induced thought disorder (p<0.00005) and fear of losing control over thinking (p<0.02). Startle reactivity and habituation were largely unchanged by psilocybin. A block by drug ANOVA revealed significant main effects of block (F(2,30)=79.2, p<0.0001) and drug (F(3,45)=8.13, p=0.0002). Post-hoc tests showed psilocybin alone did not alter startle amplitude (NS), whereas ketanserin (p<0.0015) and ketanserin plus psilocybin (p<0.015) reduced startle reactivity. There was no significant drug by block interaction, indicating no differences in habituation across conditions. For %PPI, an initial four-way ANOVA (pretreatment * treatment * intensity * ISI) identified an interaction of pretreatment by treatment and ISI (F(1,15)=4.21, p<0.05), reflecting differential drug effects at the two ISIs. Post-hoc comparisons showed that psilocybin decreased %PPI at the short 30 ms ISI (p<0.008), and this deficit was reversed by ketanserin pretreatment (effect no longer significant). At the long 120 ms ISI, psilocybin produced a slight non-significant increase in %PPI while ketanserin produced a slight non-significant decrease. Main effects of prepulse intensity (F(1,15)=43.4, p<0.0001) and ISI (F(1,15)=36.7, p<0.0001) were present. Adjusting for smoking status did not alter these outcomes. On the Stroop task, psilocybin selectively impaired performance in the conflict condition. Error rates showed main effects of drug (F(3,45)=6.26, p<0.001), condition (F(3,45)=17.9, p<0.0001), and a drug by condition interaction (F(9,135)=2.39, p<0.015); post-hoc tests indicated increased errors under psilocybin in the conflict condition (p<0.0001), an effect reversed by ketanserin (p<0.0001). Reaction time analyses showed main effects of drug (F(3,45)=9.51, p<0.0001), condition (F(3,45)=61.6, p<0.00001), and their interaction (F(9,135)=3.62, p<0.0005). Psilocybin increased RTs across all conditions (all p<0.00003), and ketanserin substantially reduced these latency increases; ketanserin alone had no significant effects. Psilocybin significantly increased Stroop interference and the total Stroop effect compared with placebo and ketanserin, and these increases were neutralised by ketanserin co-administration. Psilocybin alone did not change facilitation, although the psilocybin+ketanserin condition showed enhanced facilitation; ketanserin alone did not alter interference, Stroop effect, or facilitation. Correlation analyses pooling peak-effect data for psilocybin and psilocybin+ketanserin (n=32) found that the reduction in %PPI at the 30 ms ISI correlated with increases in OB (R=0.47, p<0.01) and VR (R=0.40, p<0.05) scores, but not with Stroop measures. Changes in AED scores correlated with Stroop interference in the neutral X (R=0.40, p<0.05) and neutral W (R=0.35, p<0.05) conditions; subscale analyses implicated thought disorder and loss of control over thinking/body as driving these associations.

Discussion

Quednow and colleagues interpret their findings as evidence that the disruptive effects of psilocybin on both automatic (sensorimotor gating) and controlled (Stroop interference) inhibition are mediated predominantly by stimulation of 5-HT2A receptors, because pretreatment with the 5-HT2A/2C antagonist ketanserin abolished the psilocybin-induced deficits and substantially attenuated the subjective hallucinogenic effects. The authors replicate a prior pattern in which psilocybin reduced PPI at short ISIs and observed a non-significant increase at a longer ISI; they propose that short-interval PPI disruption is attributable to 5-HT2A R action, whereas long-interval effects might involve 5-HT1A or interactions among receptor subtypes, noting that ketanserin did not block the small PPI enhancement at 120 ms. The investigators discuss that psilocybin increased Stroop interference and error rates in the conflict condition, a profile similar to findings in schizophrenia, and argue that these results reflect impaired conflict monitoring and response inhibition rather than a primary working memory deficit. Ketanserin’s prevention of Stroop deficits supports a role for 5-HT2A R stimulation in those processes. The authors consider potential contributions of 5-HT2C R but present several lines of animal and pharmacological evidence suggesting 5-HT2C R agonism is unlikely to account for the observed impairments. They also note that, unlike some prior reports, ketanserin produced a slight reduction in startle amplitude in their study and that methodological differences between studies may explain inconsistent ketanserin effects on PPI. Although PPI and Stroop performance appear to be modulated by similar 5-HT2A R mechanisms, the lack of a direct correlation between PPI and Stroop measures in this study leads the authors to propose that different regional 5-HT2A R populations mediate the two effects: subcortical structures implicated in the startle circuit (for example striatum or thalamus) for PPI, and cortical regions such as the anterior cingulate cortex and dorsolateral prefrontal cortex for Stroop interference. They cite imaging and receptor-occupancy data consistent with strong psilocybin effects in prefrontal areas. The study is presented as the first challenge experiment to examine both automatic and controlled inhibition and associated psychopathological symptoms with a hallucinogenic drug in healthy humans, and the authors propose that 5-HT2A R alterations across cortical and subcortical regions may contribute to the varied inhibitory deficits observed in schizophrenia.

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RESULTS

All data were analyzed using STATISTICA 7.1. for Windows (StatSoft). Startle and PPI data were analyzed using repeated measures analyses of variance (ANOVA) with drug (placebo, psilocybin, ketanserin, psilocybin + ketanserin), PP intensity (78 dB, 86 dB), and ISI (30 ms, 120 ms) as within-subject factors. An ANOVA with the repeated measurement factors drug and Stroop condition (word, XXXX, incongruent, congruent) was used to test for significant effects of psilocybin on the Stroop task, while a repeated measurement ANOVA with 5D-ASC dimensions and drug as within-subject factors were used to examine the effect on the 5D-ASC scale. Based on significant main effects or interactions, Tukey's post-hoc comparisons were performed. With exception of the 5D-ASC scores under placebo, all dependent variables were normally distributed. Pearson's product moment correlations were conducted to explore the relationship between %PPI and Stroop task. The criterion for significance was set at po0.05.

CONCLUSION

The present study demonstrated that the 5-HT 2A/2C R antagonist ketanserin abolished the disrupting effects of the 5-HT 2A/2B/2C/1A R agonist psilocybin on automatic (sensorimotor gating) and controlled (Stroop interference) inhibition processes. Moreover, we again replicated our previous findings that most of the subjective hallucinogenic effects of psilocybin are substantially neutralized by ketanserin. In a previous study, we found that psilocybin reduced PPI at short (30 ms), had no effect at medium (60 ms), and increased PPI at long (120 and 240 ms) ISIs. We found a similar pattern in the present study, although the increase of PPI in the 120 ms ISI condition was not significant. The lacking significance regarding the increase at 120 ms might be due to the fact that a somewhat higher dose of psilocybin was used in the present study (260 mg/kg) compared with the dose with which we found the significant effect in our previous study (215 mg/kg), and that the response in the 120 ISI condition appears to follow an inverse-U relationship (no significant increase at 315 mg/ kg,. Moreover, indirect stimulation of all 5-HT receptors by SSRI has also shown no effect on PPI at 60 and 120 ms ISIs in previous studies, which is in line with our present results. We previously hypothesized that the reduction of PPI at short ISIs is caused by the 5-HT 2A R agonist action of psilocybin, whereas the increase at long ISIs might be due to its 5-HT 1A R agonist action. The present results strongly suggest that the psilocybin-induced PPI disruption at short ISIs is generated by the action of psilocybin at 5-HT 2A Rs. This finding further supports the assumption that PPI deficits in schizophrenia might be induced by 5-HT 2A R changes. Moreover, as demonstrated in two previous studies, psilocybin again showed no significant effect on startle reactivity or habituation. Furthermore, we found a slight and non-significant reduction of startle reactivity by ketanserin, which is partly in line with a previous study reporting that the same dose of ketanserin (40 mg) significantly reduced startle amplitude. In contrast,also described that ketanserin disrupts PPIFa finding that we could not replicate. However, the PPI-disrupting effects bymight be the result of the strong reduction in startle amplitude found in their experiment. Although, Graham's and our experimental setups were similar, the different results may have been because of some specific parametric differences in prepulse durations, trial sequences, and the lack of startle-alone trials before assessing PPI. Furthermore, it appears unlikely that an effect of ketanserin on startle amplitude influenced our main findings because the inclusion of startle amplitude as a covariate did not change our results. Our results are partly in line with the finding that selective 5-HT 1A R agonists decrease PPI only at ISIs 4100 ms. However, the psilocybin-induced increase of PPI at 120 ms seen in the present and our previous experimentseems not to be caused by the 5-HT 1A R agonistic properties of the compound. This effect might be induced by an interaction between the 5-HT 1A , 5-HT 2A , or 5-HT 2C R because ketanserin did not block the small PPI enhancing effect of psilocybin at 120 ms. To investigate the contribution of 5-HT 1A , 5-HT 2A , and HT 2C Rs on the PPI-changing effects of psilocybin, further studies should incorporate a blockade of these receptor types in combination with a variety of short and long ISI ranging from 30-240 ms. Psilocybin significantly increased RT and error rates particularly in the conflict condition of a computerized trial-by-trial Stroop Test, a pattern of results that is similar to that reported for schizophrenia patients. Ketanserin prevented these deficits in the conflict condition, suggesting that the 5-HT 2A R agonist action of psilocybin disturbed processes that influence performance in the conflict condition of the Stroop Test. Performance in the Stroop Test is based upon mechanisms that involve the active selection and maintenance of an appropriate task rule, including working memory, attentional control, conflict monitoring, and inhibition processes. We have previously demonstrated that psilocybin impairs attentional processes, while working memory is less affected. Furthermore, the psilocybin-induced disturbance of attentional tracking ability could not be blocked by ketanserin, suggesting a primary involvement of 5-HT 1A R in this effect. In addition, it was shown that psilocybin also impairs performance in the IOR Task, which is supposed to reflect an automatic inhibitory mechanism of attention. Taken together, these findings suggest that the effect of psilocybin on the performance in the conflict condition of the Stroop Test might rather be explained by a dysfunction of conflict monitoring and/or inhibition processes than by an effect on working memory or attention per se. The different interactions of psilocybin and ketanserin on various cognitive functions might be explained by the fact that immunohistochemical studies have demonstrated that 5-HT 1A Rs are colocalized with 5-HT 2A Rs receptors in cortical pyramidal cells, where both receptor subtypes displayed opposing effects when they were stimulated. Specifically, studies in rats have shown that 5-HT 1A and 5-HT 2A Rs in the medial prefrontal cortex (mPFC) exert opposite action on attentional functioning and aspects of executive functioning. Thus, the results ofare not necessarily in conflict with the present findings. Our data are consistent with two early studies showing that performance on the classical card version of the Stroop Test is disrupted by the 5-HT 2A/2B/2C , 5-HT 1A/1B/1D , and 5-HT 6/7 R agonist LSD. However, LSD also affected the performance in the congruent conditions (cards A and B), even though the effect was most pronounced in the conflict condition (card C;. That the 5-HT system is crucially involved in processes involved in the performance of the Stroop Test has been shown by several studies: (1) acute tryptophan depletion reduces RT interference in the Stroop Test; (2) performance in the conflict condition of the Eriksen Flanker Taskas well as in congruent conditions of the Stroop Testdepends on a promoter polymorphism of the tryptophan-hydroxylase 2 gene (TPH2 -703 G/T), which has an impact on 5-HT synthesis; and (3) Stroop interference was correlated with the 5-HT transporter density within the DLPFC measured with [ 11 C]DASB positron emission tomography (PET;. Based on the present findings, we speculate that deficits in conflict monitoring and response inhibition in schizophrenia might be caused by changes in 5-HT 2A RFan assumption that might be supported by the finding that the 5-HT 2A/2B/2C , 5-HT 1A , and 5-HT 7 R antagonist cyproheptadine improved RT in the conflict condition of the Stroop Test in chronic schizophrenia patients, whereas the partial 5-HT 1A R agonist buspirone had no effect on Stroop performance in a comparable patient population. Given that ketanserin blocks not only the 5-HT 2A but also to a lesser extend the 5-HT 2C R, one might speculate that the 5-HT 2C R might also be involved the psilocybin-induced impairments of PPI and Stroop performance seen in this study. An involvement of 5-HT 2C R in the effects of hallucinogens has recently proposed based on the observation that 5-HT 2C R knock-out mice display a 50% reduction of DOI-induced head-twitch responseFa proposed animal model of human hallucinosis. However, the psilocin-induced impairments of automatic and controlled inhibition reported here is unlikely to be caused by 5-HT 2C R agonism for several reasons: (1) the selective 5-HT 2C R agonist WAY-163909 reverses MK-801-and DOIinduced PPI deficits and does not change or rather increase PPI when given alone, (2) the selective 5-HT 2C R antagonist SDZ SER-082 does not block DOI-induced PPI deficits, and (3) 5-HT 2C R agonists enhance while 5-HT 2C R antagonists impair behavioral inhibition in rodents. In contrast to a previous study, we did not find a significant correlation between Stroop Test performance and PPI. However, Scholes and Martin-Iverson used an attentional modulation gating paradigm and calculated PPI by an uncommon technique (non-linear regression fit of peak response), which might be not comparable with our approach. Earlier studies employing similar PPI techniques as in the present study also did not find associations between PPI and Stroop Test performance. Thus, although PPI and Stroop interference are obviously modulated by similar 5-HT 2A R mechanisms, the inhibitory processes engaged in each of the tasks might tap into different regional 5-HT 2A R populations. Animal research has shown that a DOI application in the ventral pallidum disrupts PPI and that this effect was blocked by highly selective 5-HT 2A R antagonists. Thus, psilocybin-induced PPI deficits at short ISIs may depend primarily on 5-HT 2A R stimulation located in more basic modulatory structures of the startle circuit such as the striatum or the thalamus. In contrast, Stroop interference depends on activation of the ACC and DLPFC. These regions display a high density of 5-HT 2A R, and [ 18 F]fluorodeoxyglucose PET studies revealed that psilocybin strongly increases glucose metabolism in these areas during resting state, especially in the ACC. Finally, preliminary data from our lab have shown that 5-HT 2A R occupation in the ACC and mPFC measured with [ 18 F]altanserin PET was correlated with the intensity of the hallucinogenic action of psilocybin. Thus, although PPIdisrupting effects of psilocybin might be mediated rather by striatal 5-HT 2A R, the effect on Stroop interference might be explained by overstimulation of 5-HT 2A R in the prefrontal cortex and the ACC. 5-HT 2A R changes in different brain areas might therefore contribute to diverse alterations in several stages of information processing found in schizophrenia. To our knowledge, this is the first study investigating the automatic and controlled inhibition processes as well as the psychopathological symptoms via challenge with a hallucinogenic drug in healthy human volunteers. The present study suggests that a stimulation of 5-HT 2A R disrupts sensorimotor gating and Stroop interference, and that these processes likely depend on different regional 5-HT 2A R populations. We therefore propose that 5-HT 2A R changes in cortical and subcortical brain regions might contribute to varied inhibitory deficits of schizophrenia patients.

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