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Letter to the Editor: Haloperidol but not dopamine rapidly induces neuronal death: comments on ‘A systematic review of the effects of antipsychotic drugs on brain volume’

Published online by Cambridge University Press:  07 May 2013

PHILLIP GRANT*
Affiliation:
Personality Psychology and Individual Differences, Justus-Liebig-University Giessen, Otto-Behaghel-Straße 10F, 35394 Giessen, Germany
*
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Abstract

Type
Correspondence
Copyright
Copyright © Cambridge University Press 2013 

In a systematic review published in Psychological Medicine, Moncrieff & Leo (Reference Moncrieff and Leo2010) come to the conclusion that antipsychotics may be partly responsible for reductions in brain volume. Similar conclusions are reached by other reviewers, such as Navari & Dazzan (Reference Navari and Dazzan2009) and Zipursky et al. (Reference Zipursky, Reilly and Murray2012), whereby they additionally propose that first-generation antipsychotics (FGAs) make an impact on brain volume more strongly than second-generation antipsychotics (SGAs).

All three papers, however, call for more research into the mechanisms that actually convey these effects. Although Moncrieff & Leo (Reference Moncrieff and Leo2010) and Navari & Dazzan (Reference Navari and Dazzan2009) both suggest a potential neurotoxic effect of FGAs, they cite little research that may support the supposition of FGA neurotoxicity on the neuronal (i.e. the effects on the neuron) rather than solely the neural (i.e. the effects on the brain) or phenotypical level.

Noh et al. (Reference Noh, Kang, Kim, Sohn, Chung, Kim and Gwag2000) reported the dose-dependent induction of apoptosis through haloperidol in primary (not cell lines) mixed (neurons and glia) cortical cell cultures. These findings prove the neurotoxicity of haloperidol, but do not eliminate similar effects of increased dopamine levels (comparing healthy versus sick brains). Taking this into account, we replicated these results (Grant, Reference Grant2011), but additionally compared effects of dopamine incubation. We found a drastic dose-dependent induction of neuronal death (90% at highest concentrations) after 24 h in haloperidol-treated but not in dopamine-treated primary mixed cortical cultures. Additionally, we examined possible mediators of haloperidol neurotoxicity, finding substantial increases in indicators of oxidative stress. These findings mirror significant increases in oxidative damage markers found in animals induced by haloperidol but not by SGAs (e.g. Parikh et al. Reference Parikh, Khan and Mahadik2003) as well as in schizophrenic patients (e.g. Zhang et al. Reference Zhang, Tan, Cao, Wu, Xu, Shen and Zhou2006).

I would, therefore, draw two conclusions. First, haloperidol is indeed toxic at the neuronal level. Second, I believe that findings on the cell biology of schizophrenia and related factors may be of great importance and should therefore be incorporated into the field of schizophrenia research more than they currently are.

Declaration of Interest

None.

References

Grant, P (2011). Dopamine neurotoxicity, oxidative stress and schizophrenia: in vitro and in vivo studies of peroxisomal reactions to increased dopamine. Doctoral thesis, Justus-Liebig-Universität Giessen (geb.uni-giessen.de/geb/volltexte/2011/8495/index.html). Accessed April 2013.Google Scholar
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Noh, JS, Kang, HJ, Kim, EY, Sohn, S, Chung, YK, Kim, SU, Gwag, BJ (2000). Haloperidol-induced neuronal apoptosis: role of p38 and c-Jun-NH2-terminal protein kinase. Journal of Neurochemistry 75, 23272334.CrossRefGoogle Scholar
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Zhang, XY, Tan, YL, Cao, LY, Wu, GY, Xu, Q, Shen, Y, Zhou, DF (2006). Antioxidant enzymes and lipid peroxidation in different forms of schizophrenia treated with typical and atypical antipsychotics. Schizophrenia Research 81, 291300.CrossRefGoogle ScholarPubMed
Zipursky, RB, Reilly, TJ, Murray, RM (2012). The myth of schizophrenia as a progressive brain disease. Schizophrenia Bulletin. Published online 7 December 2012. doi:10.1093/schbul/sbs135.Google ScholarPubMed