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Reply to Vadhan et al. – Correspondence on Curran et al. (2018) ‘Which biological and self-report measures of cannabis use predict cannabis dependency and acute psychotic-like response’

Published online by Cambridge University Press:  07 March 2019

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Abstract

Type
Invited Letter Rejoinder
Copyright
Copyright © Cambridge University Press 2019 

We thank our esteemed colleagues at Colombia University for their interest in our recent publication in this journal (Curran et al., Reference Curran, Hindocha, Morgan, Shaban, Das and Freeman2018).

In our paper we aimed to investigate the relationship between a wide range of biological and self-report measures of cannabis use and two key outcomes: cannabis dependence and acute psychotic-like response to the drug. We included an unprecedented set of 15 different cannabis use measures taken from participants’ hair, urine, their own cannabis samples, and self-report to estimate exposure to delta-9-tetrahydrocannabinol (THC) and cannabidiol. We found that a combination of urinary and self-report measures was associated with both of these outcomes. Cannabis dependency was predicted by higher frequency of cannabis use and urinary THC-COOH/creatinine concentrations. Acute psychotic response to cannabis was predicted by a higher age of first use and lower urinary THC-COOH/creatinine concentrations, suggestive of tolerance to this acute effect.

In contrast, the letter by Vadhan et al. raises a separate question of whether psychosis proneness predicts the acute psychotic response to cannabis. Although this question is beyond the scope of our recent paper, we agree it is an important question. Indeed we have addressed this issue in previous publications. The first of these showed that a measure of psychosis-proneness (the Schizotypal Personality Questionnaire – SPQ, Raine, Reference Raine1991) predicted the acute psychotic response to cannabis (Mason et al., Reference Mason, Morgan, Dhiman, Patel, Parti, Patel and Curran2009). The acute psychotic response was measured with the Psychotomimetic State Inventory (PSI), the same measure we used in Curran et al. (Reference Curran, Hindocha, Morgan, Shaban, Das and Freeman2018). In a second study, we showed that variation at the rs2494732 locus of the AKT1 gene predicts the acute psychotic response to cannabis on the PSI. This parallels studies with people diagnosed with a psychotic disorder where the AKT1 rs2494732 polymorphism also interacts with cannabis to predict the risk of psychosis (van Winkel et al., Reference van Winkel, Henquet, Rosa, Papiol, Fananás, De Hert, Peuskens, van Os and Myin-Germeys2008, Reference van Winkel, van Beveren, Simons and Genetic2011; di Forti et al., Reference Di Forti, Iyegbe, Sallis, Kolliakou, Falcone, Paparelli, Sirianni, La Cascia, Stilo, Marques, Handley, Mondelli, Dazzan, Pariante, David, Morgan, Powell and Murray2012). Our previous paper (Morgan et al., Reference Morgan, Freeman, Powell and Curran2016) was focused on psychosis proneness, and did not include the same comprehensive set of 15 biological and subjective measure of cannabis use as Curran et al. (Reference Curran, Hindocha, Morgan, Shaban, Das and Freeman2018). However, it did include years of cannabis use and cannabis dependency as possible predictors. Using a multiple regression model we found that increased dosage of the C allele on the AKT1 rs2494732 genotype, increased baseline psychotic symptoms, and fewer years of cannabis use predicted acute psychotic symptoms following cannabis use. We hope that these analyses in our previous paper (Morgan et al., Reference Morgan, Freeman, Powell and Curran2016) sufficiently address the points raised by Vadhan et al.

In conclusion, we agree with Vadhan et al. that psychosis proneness is an important factor to consider when investigating the acute psychotic response to cannabis, as we have shown in our previous work (Mason et al., Reference Mason, Morgan, Dhiman, Patel, Parti, Patel and Curran2009; Morgan et al., Reference Morgan, Freeman, Powell and Curran2016). As the field progresses it will be important to investigate other predictors of vulnerability and resilience such as adolescent onset of use (Mokrysz et al., Reference Mokrysz, Freeman, Korkki, Griffiths and Curran2016) and comprehensive assessments of cannabis use (Curran et al., Reference Curran, Hindocha, Morgan, Shaban, Das and Freeman2018). Indeed, measures of cannabis use are typically poor in research studies at present, and require standardisation to improve precision when measuring cannabis use and its association with harms and benefits of use (Lorenzetti et al., Reference Lorenzetti, Solowij and Yücel2016; Hindocha et al., Reference Hindocha, Norberg and Tomko2017).

Author ORCIDs

H. Valerie Curran, 0000-0001-6011-6978.

References

Curran, HV, Hindocha, C, Morgan, CJA, Shaban, N, Das, RK and Freeman, TP (2018) Which biological and self-report measures of cannabis use predict cannabis dependency and acute psychotic-like response. Psychological Medicine 4, 17.Google Scholar
Di Forti, M, Iyegbe, C, Sallis, H, Kolliakou, A, Falcone, MA, Paparelli, A, Sirianni, M, La Cascia, C, Stilo, SA, Marques, TR, Handley, R, Mondelli, V, Dazzan, P, Pariante, C, David, AS, Morgan, C, Powell, J and Murray, RM (2012) Confirmation that the AKT1 (rs2494732) genotype influences the risk of psychosis in cannabis users. Biological Psychiatry 72, 811816.Google Scholar
Hindocha, C, Norberg, MM and Tomko, RL (2017) Solving the problem of cannabis quantification. Lancet 4, 643648.Google Scholar
Lorenzetti, V, Solowij, N and Yücel, M (2016) The role of cannabinoids in neuroanatomic alterations in cannabis users. Biological Psychiatry 79, e17e31.Google Scholar
Mokrysz, C, Freeman, TP, Korkki, S, Griffiths, K and Curran, HV (2016) Are adolescents more vulnerable to the harmful effects of cannabis than adults? A placebo-controlled study in human males. Translational Psychiatry 6, e961.Google Scholar
Morgan, CJA, Freeman, TP, Powell, J and Curran, HV (2016) AKT1 genotype moderates the acute psychotomimetic effects of naturalistically smoked cannabis in young cannabis smokers. Translational Psychiatry 6, e738.Google Scholar
Mason, O, Morgan, CJ, Dhiman, SK, Patel, A, Parti, N, Patel, A and Curran, HV (2009) Acute cannabis use causes increased psychotomimetic experiences in individuals prone to psychosis. Psychological Medicine 39, 951956.Google Scholar
Raine, A (1991) The SPQ: a scale for the assessment of schizotypal personality based on DSM-III-R criteria. Schizophrenia Bulletin 17, 555564.Google Scholar
van Winkel, R, Henquet, C, Rosa, A, Papiol, S, Fananás, L, De Hert, M, Peuskens, J, van Os, J and Myin-Germeys, I (2008) Evidence that the COMT(Val158Met) polymorphism moderates sensitivity to stress in psychosis: an experience-sampling study. American Journal of Medical Genetics. Part B, Neuropsychiatric Genetics 147B, 1017.Google Scholar
van Winkel, R, van Beveren, NJ, Simons, C and Genetic, R (2011) Outcome of Psychosis I. AKT1 moderation of cannabis-induced cognitive alterations in psychotic disorder. Neuropsychopharmacology 36, 25292537.Google Scholar