Hostname: page-component-cd9895bd7-hc48f Total loading time: 0 Render date: 2024-12-21T17:07:53.241Z Has data issue: false hasContentIssue false

Correspondence on Curran et al. (2018): ‘Which biological and self-report measures of cannabis use predict cannabis dependency and acute psychotic-like effects’

Published online by Cambridge University Press:  29 January 2019

Nehal P. Vadhan*
Affiliation:
Departments of Psychiatry and Molecular Medicine, Hofstra Northwell School of Medicine and the Center for Psychiatric Neuroscience, Feinstein Institute for Medical Research, Manhasset, NY, USA
Cheryl M. Corcoran
Affiliation:
Department of Psychiatry, Icahn School of Medicine at Mount Sinai, New York, NY, USA
John G. Keilp
Affiliation:
Department of Psychiatry, Columbia University Medical Center and the New York State Psychiatric Institute, New York, NY, USA
Margaret Haney
Affiliation:
Department of Psychiatry, Columbia University Medical Center and the New York State Psychiatric Institute, New York, NY, USA
*
Author for correspondence: Nehal P. Vadhan, E-mail: nvadhan@northwell.edu
Rights & Permissions [Opens in a new window]

Abstract

Type
Correspondence
Copyright
Copyright © Cambridge University Press 2019 

To the Editor:

The interactions between cannabis use, use disorder and psychosis is an important topic that is worthy of systematic investigation. Therefore, we read with great interest our colleagues’ article ‘Which biological and self-report measures of cannabis use predict cannabis dependency and acute psychotic-like effects’, recently published in Psychological Medicine (Curran et al., Reference Curran, Hindocha, Morgan, Shaban, Das and Freeman2018). Within the framework of this otherwise well-conducted study, we respectfully suggest that accounting for the participants’ predisposition to psychosis in the study methodology would have strengthened the findings.

The investigators employed a series of clinical and biological measures in the context of participants’ (verified) naturalistic use and nonuse of cannabis, and found that: (1) cannabis intoxication increased the level of psychotic-like symptoms overall, and (2) evidence of greater recent delta-9-tetrahydrocannabinol (Δ9-THC) exposure was associated with decreased psychotic-like effects of, but greater dependency, on cannabis. Essentially, while cannabis may have acute psychotic-like effects, more experience with cannabis is associated with lower psychotic-like effects but a greater likelihood of cannabis dependence. While this is a reasonable and well-supported conclusion, and the study had many methodological strengths, the investigators neglected to address a potential major factor in the acute psychotic-like effects of cannabis – namely, the predisposition to psychosis.

A substantial literature, employing a variety of methodologies and populations, has examined the psychotic-like sequelae of cannabis in the broad psychosis spectrum. Naturalistic/clinical studies have demonstrated that cannabis use is concurrently and prospectively associated with increases in psychotic-like experiences/symptoms in such individuals (e.g. Verdoux et al., Reference Verdoux, Gindre, Sorbara, Tournier and Swendsen2003; Henquet et al., Reference Henquet, Krabbendam, Spauwen, Kaplan, Lieb, Wittchen and van Os2004; Hides et al., Reference Hides, Dawe, Kavanagh and Young2006; Corcoran et al., Reference Corcoran, Kimhy, Stanford, Khan, Walsh, Thompson, Schobel, Harkavy-Friedman, Goetz, Colibazzi, Cressman and Malaspina2008; Henquet et al., Reference Henquet, van Os, Kuepper, Delespaul, Smits, Campo and Myin-Germeys2010). Further, placebo-controlled drug administration studies have shown, compared to healthy cannabis users, evidence consistent with a stronger psychotic-like effect of (or psychosis-associated neurochemical response to) active cannabis/Δ9-THC in individuals at genetic (Henquet et al., Reference Henquet, Rosa, Krabbendam, Papiol, Fananás, Drukker, Ramaekers and van Os2006), familial (Kuepper et al., Reference Kuepper, Ceccarini, Lataster, van Os, van Kroonenburgh, van Gerven, Marcelis, Van Laere and Henquet2013), clinical (Vadhan et al., Reference Vadhan, Corcoran, Bedi, Keilp and Haney2017), or realized (D'Souza et al., Reference D'Souza, Abi-Saab, Madonick, Forselius-Bielen, Doersch, Braley, Gueorguieva, Cooper and Krystal2005; Henquet et al., Reference Henquet, Rosa, Krabbendam, Papiol, Fananás, Drukker, Ramaekers and van Os2006; Kuepper et al., Reference Kuepper, Ceccarini, Lataster, van Os, van Kroonenburgh, van Gerven, Marcelis, Van Laere and Henquet2013) risk for a psychotic disorder. Finally, naturalistic studies have converged on these findings of differential effects (Henquet et al., Reference Henquet, van Os, Kuepper, Delespaul, Smits, Campo and Myin-Germeys2010; Spriggens and Hides, Reference Spriggens and Hides2015) and prospective cohort observation studies have provided further clinical significance (McHugh et al., Reference McHugh, McGorry, Yung, Lin, Wood, Hartmann and Nelson2017).

Although it could be argued that such populations were outside the scope of the Curran et al. (Reference Curran, Hindocha, Morgan, Shaban, Das and Freeman2018) study, individuals who have psychotic-like experiences are overrepresented in the cannabis-using population (van Os et al., Reference van Os, Linscott, Myin-Germeys, Delespaul and Krabbendam2008), and about 20% of individuals from our extensive database of nontreatment-seeking cannabis users endorsed having CHR-level psychotic-like experiences (unpublished data) on a screening questionnaire (Miller et al., Reference Miller, Chicchetti, Markovich, McGlashan and Woods2004). This suggests the presence of a subpopulation of, at minimum, psychosis-prone individuals within the larger population of nontreatment-seeking cannabis users. If it is possible for the investigators to identify these individuals within their study (perhaps by the baseline Brief Psychiatric Rating Scale measures), a series of interesting analyses could be accomplished. For example, the notion that cannabis’ psychotic-like effects are stronger in psychosis-predisposed individuals could be tested, and the similarities and differences in the interrelationships between previous cannabis exposure, dependency and psychotic-like effects, between these cannabis user subtypes could be assessed.

Author ORCIDs

Nehal P. Vadhan, 0000-0003-0162-4256.

Conflict of interest

None.

References

Corcoran, CM, Kimhy, D, Stanford, A, Khan, S, Walsh, J, Thompson, J, Schobel, S, Harkavy-Friedman, J, Goetz, R, Colibazzi, T, Cressman, V and Malaspina, D (2008) Temporal association of cannabis use with symptoms in individuals at clinical high risk for psychosis. Schizophrenia Research 106, 286293.Google Scholar
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 effects? Psychological Medicine 4, 17.Google Scholar
D'Souza, DC, Abi-Saab, WM, Madonick, S, Forselius-Bielen, K, Doersch, A, Braley, G, Gueorguieva, R, Cooper, TB and Krystal, JH (2005) Delta-9-tetrahydrocannabinol effects in schizophrenia: implications for cognition, psychosis, and addiction. Biological Psychiatry 57, 594608.Google Scholar
Henquet, C, Krabbendam, L, Spauwen, J, Kaplan, C, Lieb, R, Wittchen, HU and van Os, J (2004) Prospective cohort study of cannabis use, predisposition for psychosis, and psychotic symptoms in young people. British Medical Journal 330, 11.Google Scholar
Henquet, C, Rosa, A, Krabbendam, L, Papiol, S, Fananás, L, Drukker, M, Ramaekers, JG and van Os, J (2006) An experimental study of catechol-o-methyltransferase Val158Met moderation of delta-9-tetrahydrocannabinol-induced effects on psychosis and cognition. Neuropsychopharmacology 31, 27482757.Google Scholar
Henquet, C, van Os, J, Kuepper, R, Delespaul, P, Smits, M, Campo, JA and Myin-Germeys, I (2010) Psychosis reactivity to cannabis use in daily life: an experience sampling study. British Journal of Psychiatry 196, 447453.Google Scholar
Hides, L, Dawe, S, Kavanagh, DJ and Young, RM (2006) Psychotic symptom and cannabis relapse in recent-onset psychosis. Prospective study. British Journal of Psychiatry 189, 137143.Google Scholar
Kuepper, R, Ceccarini, J, Lataster, J, van Os, J, van Kroonenburgh, M, van Gerven, JM, Marcelis, M, Van Laere, K and Henquet, C (2013) Delta-9-tetrahydrocannabinol-induced dopamine release as a function of psychosis risk: 18F-fallypride positron tomography study. PLoS ONE 8, e70378.Google Scholar
McHugh, MJ, McGorry, PD, Yung, AR, Lin, A, Wood, SJ, Hartmann, JA and Nelson, B (2017) Cannabis-induced attenuated psychotic symptoms: implications for prognosis in young people at ultrahigh risk for psychosis. Psychological Medicine 47, 616626.Google Scholar
Miller, TJ, Chicchetti, DV, Markovich, PJ, McGlashan, TH and Woods, SW (2004) The SIPS screen: a brief self-report screen to detect the schizophrenia prodrome. Schizophrenia Research 70, 78.Google Scholar
Spriggens, L and Hides, L (2015) Patterns of cannabis use, psychotic-like experiences and personality styles in young cannabis users. Schizophrenia Research 165, 38.Google Scholar
Vadhan, NP, Corcoran, CM, Bedi, G, Keilp, JG and Haney, M (2017) Acute effects of smoked marijuana in marijuana smokers at clinical high-risk for psychosis: a preliminary study. Psychiatry Research 257, 372374.Google Scholar
van Os, J, Linscott, RJ, Myin-Germeys, I, Delespaul, P and Krabbendam, L (2008) A systematic review and meta-analysis of the psychosis continuum: evidence for a psychosis proneness–persistence–impairment model of psychotic disorder. Psychological Medicine 39, 179195.Google Scholar
Verdoux, H, Gindre, C, Sorbara, F, Tournier, M and Swendsen, JD (2003) Effects of cannabis and psychosis vulnerability in daily life: an experience sampling test study. Psychological Medicine 33, 2332.Google Scholar