Hostname: page-component-78c5997874-ndw9j Total loading time: 0 Render date: 2024-11-16T16:11:20.499Z Has data issue: false hasContentIssue false
  • English
  • Français

Parkinson’s disease psychosis as a serotonin-dopamine imbalance syndrome

Published online by Cambridge University Press:  30 September 2016

Stephen M. Stahl
Rights & Permissions [Opens in a new window]

Abstract

Parkinson’s disease psychosis (PDP) is theoretically a serotonin-dopamine imbalance syndrome due to disruption of the normal balance between the serotonergic and dopaminergic neurotransmitter systems in key brain circuits.

Type
Brainstorms
Information
CNS Spectrums , Volume 21 , Issue 5 , October 2016 , pp. 355 - 359
Copyright
© Cambridge University Press 2016 

Take-Home Points

  • Psychosis, especially with visual hallucinations and delusions, may develop in up to half of patients with Parkinson’s disease.

  • Parkinson’s disease psychosis (PDP) may be caused in part by deposition of toxic alpha-synuclein–containing Lewy bodies in the cerebral cortex that hypothetically disrupt both serotonin and dopamine neurotransmission, with upregulation and overstimulation of cortical serotonin 5HT2A receptors and excessive release of downstream dopamine in mesolimbic brain circuits.

  • Blocking hypothetically excessive serotonin neurotransmission at serotonin 5HT2A receptors in patients with PDP theoretically restores the balance between serotonin and dopamine, reducing visual hallucinations and delusions without worsening motor symptoms.

Introduction

Parkinson’s disease begins with prominent motor symptoms caused by deposition of Lewy bodies containing alpha-synuclein in the substantia nigra,Reference Birkmayer and Birkmayer 1 Reference Kordower, Olanaw and Dodiya 3 and then progresses in over half the cases to psychosis with delusions and hallucinations called Parkinson’s disease psychosis (PDP).Reference Cummings 4 Reference Goldman, Vaughan and Goetz 7 Several causes are proposed for PDP, the most prominent theory being the accumulation of Lewy bodies in the cerebral cortex.Reference Cummings 4 Reference Ballard, Aarsland, Francis and Corbett 13 Lewy body deposition in the cerebral cortex is also thought to cause Lewy body dementia in patients who have the same visual hallucinations and delusions characteristic of PDP but who do not have early Lewy body deposition in substantia nigra nor motor symptoms of Parkinson’s disease.Reference Wirdefeldt, Bogdanovic, Westerberg, Payami, Schalling and Murdoch 12 Reference Wakabayashi, Hansen and Masliah 17 Other causes or contributors to PDP may include Alzheimer amyloid plaques/tau pathology in the cerebral cortexReference Jacobson, Morshed and Dugger 15 as well as high dosing of dopaminergic drugs used to treat the motor symptoms of Parkinson’s disease.Reference Cummings 4 , Reference Vaillancourt, Schonfeld, Kwak, Bohnen and Seidler 18 Reference MacDonald and Monchi 21 No matter what the cause, PDP seems to be a serotonin-dopamine imbalance syndrome due to a final common pharmacologic pathway in which serotonin activity at 5HT2A receptors, dopamine activity at D2 receptors, or both, become excessive.

Serotonin-Dopamine Imbalance Due to Cortical Lewy Bodies

Parkinson’s disease starts as a “substantia nigra synucleinopathy” with Lewy body deposition in the substantia nigra that causes motor symptoms.Reference Birkmayer and Birkmayer 1 Reference Kordower, Olanaw and Dodiya 3 Parkinson’s disease can progress to a “cortical synucleinopathy” with Lewy body deposition in the cerebral cortex that hypothetically causes PDP.Reference Cummings 4 Reference Ballard, Aarsland, Francis and Corbett 13 Although Parkinson’s disease is mostly known as a “dopamine deficiency syndrome” in the dorsal striatum due to loss of substantia nigra neurons thus causing akinesia, rigidity, and tremor,Reference Birkmayer and Birkmayer 1 Reference Kordower, Olanaw and Dodiya 3 it can theoretically progress to develop a superimposed “serotonin-dopamine excess syndrome” in the cerebral cortex and ventral striatum that causes PDP.Reference Huot, Hohnston and Darr 9 , Reference Ballanger, Strafella and van Eimeren 10 , Reference Birkmayer, Danielczyk, Neumayer and Riederer 22 That is, the normal balance between serotonin and dopamine (Figure 1) becomes initially distorted due to loss of substantia nigra projections to the dorsal striatum, causing dopamine deficiency there (Figure 2) and the classical motor symptoms of Parkinson’s disease.Reference Birkmayer and Birkmayer 1 Reference Kordower, Olanaw and Dodiya 3 Concomitantly, serotonin neurons in the raphe are also degenerating with initial loss of serotonin (Figure 2),Reference Birkmayer, Danielczyk, Neumayer and Riederer 22 Reference Kerenyi, Ricaurte and Schretlen 30 but this is less prominent than the dopamine loss and not clearly linked to motor symptoms, but possibly to nonmotor symptoms.

Figure 1 Serotonin-dopamine balance. Normally, serotonin and dopamine are balanced in neuronal circuits. Shown here are serotonin (5HT) 2A receptors regulating gamma amino butyric acid (GABA) and glutamate in the cerebral cortex and dopamine in the downstream ventral tegmental area and the ventral striatum.

Figure 2 Parkinson’s disease: nigrostriatal dopamine/D2 deficiency. In Parkinson’s disease, Lewy bodies accumulate in the substantia nigra, causing them to degenerate and lose their dopamine in nerve terminals projecting to the dorsal striatum. This causes a nigrostriatal dopamine/D2 deficiency resulting in the motor symptoms of Parkinson’s disease, namely akinesia, rigidity, and tremor.

As Lewy bodies accumulate in the cerebral cortex with the progression of Parkinson’s disease in some patients, pyramidal neurons containing serotonin receptors degenerate, and a well-documented upregulation and thus increase in the number of 5HT2A receptors occurs in the remaining neurons in the cerebral cortex.Reference Ballanger, Strafella and van Eimeren 10 , Reference Birkmayer, Danielczyk, Neumayer and Riederer 22 Reference Huot and Fox 28 Upregulation of 5HT2A receptors seems to occur in the motor cortex of Parkinson’s patients whether they have psychosis or not,Reference Huot, Hohnston and Darr 9 but upregulation of 5HT2A receptors seems to occur in the prefrontal and visual/temporal cortex areas only in patients with PDP,Reference Huot, Hohnston and Darr 9 although not all observers agree.Reference Cheng, Ferrier and Morris 29 Also in PDP there appears to be an increase in raphe serotonin levels,Reference Birkmayer, Danielczyk, Neumayer and Riederer 22 presumably due to enhanced serotonin turnover despite the loss of serotonergic raphe neurons (Figure 3). The resulting enhanced activity at upregulated 5HT2A receptors in the temporal cortex and in visual pathways hypothetically causes visual hallucinations.Reference Huot, Hohnston and Darr 9 , Reference Ballanger, Strafella and van Eimeren 10 , Reference Kometer, Schmidt, Jäncke and Vollenwider 31 Indeed, hallucinogenic drugs that stimulate these same 5HT2A receptors also cause striking visual hallucinations.Reference Kometer, Schmidt, Jäncke and Vollenwider 31 Reference McClue, Brazell and Stahl 33 Thus, there is robust pharmacologic rationale to explain why stimulation of 5HT2A receptors causes visual hallucinations, and why blocking hypothetically overstimulated 5HT2A receptors in PDP with the selective 5HT2A antagonist pimavanserinReference Stahl 34 Reference Friedman 37 or the nonselective 5HT2A antagonists quetiapine and clozapineReference Zahodne and Fernandez 38 , Reference Desmarais, Massoud, Filion, Nguyen and Bajsarowicz 39 reduces visual hallucinations.

Figure 3 Parkinson’s disease psychosis: cortical serotonin/5HT2A and mesolimbic dopamine/D2 excess superimposed upon nigrostriatal dopamine D2 deficiency. After the development of nigrostriatal dopamine/D2 deficiency and the motor symptoms of Parkinson’s disease shown in Figure 2, some patients progress to having Lewy bodies accumulate in cerebral cortex, upregulating 5HT2A receptors, resulting in their excessive activation and the development of visual hallucinations of PDP in visual and temporal brain circuits and downstream enhancement of ventral striatal dopamine, also causing delusions and auditory hallucinations of PDP.

Upregulated 5HT2A receptors in the prefrontal cortex hypothetically lead to downstream changes in the cortical-striatal and cortical-brainstem projections regulating dopamine release in the ventral striatum in patients with PDP (Figure 3).Reference Huot, Hohnston and Darr 9 , Reference Ballanger, Strafella and van Eimeren 10 , Reference Kometer, Schmidt, Jäncke and Vollenwider 31 When dopamine release is enhanced there, positive symptoms of psychosis are thought to be the consequence, namely delusions and auditory hallucinations.Reference Stahl 40 , Reference Meltzer and Stahl 41 This is the same pathophysiology long postulated for psychotic symptoms of schizophrenia in the so-called dopamine hypothesis.Reference Stahl 40 , Reference Meltzer and Stahl 41 Overall, this formulation comprises robust pharmacologic rationale to explain why blocking hypothetically overstimulated 5HT2A receptors in PDP would improve serotonin-dopamine imbalance, and thereby stop psychotic symptoms.

Serotonin-Dopamine Imbalance Due to Dopamine Treatments

Psychosis in Parkinson’s disease can also be associated with dopaminergic therapeutics, since it can correlate with dosing and blood levels of the drugs and improve with dose reduction.Reference Vaillancourt, Schonfeld, Kwak, Bohnen and Seidler 18 Reference MacDonald and Monchi 21 This may not necessarily occur only in Parkinson patients with Lewy body accumulation the cortex (Figure 3), but also for various additional and unknown reasons in certain other vulnerable patients (Figure 4).Reference Cummings 4 , Reference Vaillancourt, Schonfeld, Kwak, Bohnen and Seidler 18 Reference MacDonald and Monchi 21 That is, in the usual patient with Parkinson’s disease (Figure 2), administration of L-DOPA and similar dopamine stimulating agonists and agents appears to improve motor symptoms without causing psychosis. In these patients, stimulation of dopamine terminals in the dorsal striatum thus provides therapeutic benefit for motor symptoms but any concomitant stimulation of dopamine terminals in the ventral striatum does not cause psychosis, presumably due to the presence of a therapeutic window in these patients.Reference Birkmayer and Birkmayer 1 Reference Cummings 4 , Reference Vaillancourt, Schonfeld, Kwak, Bohnen and Seidler 18 Reference MacDonald and Monchi 21

Figure 4 L-DOPA psychosis: dorsal to ventral shift and dopamine overdose. In some patients with Parkinson’s disease, psychosis develops because of a dorsal to ventral shift in the sensitivity of the striatum to dopaminergic treatments. This results in over-activity of the ventral striatum, just like that postulated to occur in schizophrenia, and the production of psychotic symptoms such as delusions and auditory hallucinations, also just like those seen in schizophrenia.

However, in vulnerable Parkinson patients who may have early age of onset of their Parkinson’s disease, have a long duration of illness, or are in the later stages of the illness with severe motor symptoms, the improvement of motor symptoms by dopaminergic therapy can come at the expense of inducing concomitant positive psychotic symptoms such as delusions and hallucinations.Reference Cummings 4 , Reference Vaillancourt, Schonfeld, Kwak, Bohnen and Seidler 18 Reference MacDonald and Monchi 21 These same patients hypothetically have a dorsal to ventral shift in their sensitivity to exogenous dopamine administration such that both the dorsal and the ventral striata now respond to stimulation by dopamine.Reference Joutsa, Johansson, Seppänen, Noponen and Kaasinen 20 Too much dopamine stimulation of the dorsal striata may manifest as unwanted movement disorders such as dyskinesias or the on-off phenomenon whereas too much dopamine stimulation in the ventral striatum hypothetically manifests as positive symptoms of psychosis just as postulated to occur when this area of the brain is overstimulated in patients with these same symptoms who have schizophrenia. Dose reduction of dopaminergic stimulants or administration of D2 dopamine antagonists traditionally utilized for the treatment of schizophrenia may improve the psychosis of excessive dopaminergic therapy in Parkinson’s disease, but often at the expense of worsening motor behavior.

Pharmacologic Mechanism of Action of 5HT2A Antagonism in PDP: No Longer Between a Rock and a Hard Place

Traditional treatments for PDP included dose reduction of dopaminergic therapy if that was a contributing factor, or administration of antipsychotics, especially quetiapine or clozapine, assumed initially to work by blocking D2 dopamine receptors just as they do in schizophrenia.Reference Vaillancourt, Schonfeld, Kwak, Bohnen and Seidler 18 Reference MacDonald and Monchi 21 , Reference Zahodne and Fernandez 38 , Reference Desmarais, Massoud, Filion, Nguyen and Bajsarowicz 39 However, this often put both PDP patients and their clinicians between a rock and a hard place when trying to balance simultaneously the treatment of both PDP and motor symptoms of Parkinson’s disease, since what was good for psychotic symptoms was generally bad for motor symptoms.

Pimavanserin is a potent antagonist at 5HT2A receptors without any D2 dopamine antagonist properties.Reference Stahl 34 It is the first agent with proven antipsychotic actions for PDP and is effective for psychotic symptoms worsening motor symptoms.Reference Stahl 34 Reference Friedman 37 This antipsychotic efficacy of pimavanserin in PDP was at first surprising because longstanding dogma about the pharmacology of psychosis assumed that psychosis was due to excessive dopamine activity (such as that shown in Figure 4),Reference Stahl 40 , Reference Meltzer and Stahl 41 and the only way to treat psychosis was therefore to reduce dopamine activity directly either by dose reduction of dopamine stimulants or by administration of dopamine antagonists. However, pimavanserin appears to exert its antipsychotic effects in PDP without worsening motor symptoms by correcting the theoretical serotonin-dopamine imbalance in PDP that causes psychosis via direct interaction with 5HT2A receptors,Reference Stahl 34 leading to indirect actions on downstream dopamine release (Figure 3)Reference Stahl 40 without disrupting the serotonin-dopamine balance associated with motor symptoms (Figure 2).Reference Stahl 34 , Reference Stahl 40

Summary

PDP is associated with upregulated 5HT2A receptors in the cerebral cortex that presumably are the result of cortical Lewy body deposition and that theoretically set off a serotonin-dopamine imbalance syndrome associated with visual hallucinations and delusions. Blocking 5HT2A receptors improves PDP without worsening motor symptoms, hypothetically restoring balance in serotonin and dopamine neurotransmitter systems. Since 5HT2A receptors are also upregulated in dementia with Lewy bodies, it is possible that pimavanserin will also be effective in treating the visual hallucinations of Lewy body dementia.

References

1. Birkmayer, W, Birkmayer, JD. Dopamine action and disorders of neurotransmitter balance. Gerontology. 1987; 33(3–4): 168171.Google Scholar
2. Ravina, B, Marek, K, Eberly, S, et al. Dopamine transporter imaging is associated with long-term outcomes in Parkinson’s disease. Mov Disord. 2012; 27(11): 13921397.Google Scholar
3. Kordower, JH, Olanaw, CW, Dodiya, HB, et al. Disease duration and the integrity of the nigrostriatal system in Parkinson’s disease. Brain. 2013; 136(Pt 8): 24192431.CrossRefGoogle ScholarPubMed
4. Cummings, JL. Behavioral complications of drug treatment of Parkinson’s disease. J Am Geriatr Soc. 1991; 39(7): 708716.Google Scholar
5. Chang, A, Fox, SH. Psychosis in Parkinson’s disease: Epidemiology, pathophysiology, and management. Drugs. 2016; 76(11): 10931118.Google Scholar
6. Goldman, JG, Holden, S. Treatment of psychosis and dementia in Parkinson’s Disease. Curr Treat Options Neurol. 2014; 16(3): 281.Google Scholar
7. Goldman, JG, Vaughan, CL, Goetz, CG. An update expert opinion on management and research strategies in Parkinson’s disease psychosis. Expert Opin Pharmacother. 2011; 12(13): 20092024.Google Scholar
8. Paponabarrage, J, Martinez-Horta, S, Fernandez de Bobadilla, R, et al. Minor hallucinations occur in drug-naive Parkinson’s disease patients, even from the premotor phase. Mov Disord. 2016; 31(1): 4552.CrossRefGoogle Scholar
9. Huot, P, Hohnston, TH, Darr, T, et al. Increased 5HT2A receptors in the temporal cortex of parkinsonian patients with visual hallucinations. Mov Disord. 2010; 25(10): 13991408.Google Scholar
10. Ballanger, B, Strafella, AP, van Eimeren, T, et al. Serotonin 2A receptors and visual hallucinations in Parkinson disease. Arch Neurol. 2000; 67(4): 416421.Google Scholar
11. Kalia, LV, Kalia, SK. Alpha-synuclein and Lew pathology in Parkinson’s disease. Mov Disord. 2015; 28(4): 376381.Google Scholar
12. Wirdefeldt, K, Bogdanovic, N, Westerberg, L, Payami, H, Schalling, M, Murdoch, G. Expression of alpha-synuclein in the human brain: relation to Lewy body disease. Brain Res Mol Brain Res. 2001; 92(1–2): 5865.Google Scholar
13. Ballard, C, Aarsland, D, Francis, P, Corbett, A. Neuropsychiatric symptoms in patients with dementias associated with cortical Lewy bodies: pathophysiology, clinical features and pharmacological management. Drugs Aging. 2013; 30(8): 603611.Google Scholar
14. Boot, BP. Comprehensive treatment of dementia with Lewy bodies. Alzheimers Res Ther. 2015; 7(1): 4552.CrossRefGoogle ScholarPubMed
15. Jacobson, SA, Morshed, T, Dugger, BN, et al. Plaques and tangles as well as Lewy-type alpha synucleinopathy are associated with formed visual hallucinations. Parkinsonism Relat Disord. 2014; 20(9): 10091014.Google Scholar
16. Kundakar, AA, Hanson, PS, Erskine, D, et al. Analysis of primary visual cortex in dementia with Lewy bodies indicates GABAergic involvement associated with recurrent complex visual hallucinations. Acta Neuropathol Commun. 2016; 4(1): 66.Google Scholar
17. Wakabayashi, K, Hansen, LA, Masliah, E. Cortical Lewy body-containing neurons are pyramidal cells: laser confocal imaging of double-immunolabled sections with anti-ubiquitin and SMI32. Acta Neuropathol. 1995; 89: 404408.Google Scholar
18. Vaillancourt, DE, Schonfeld, D, Kwak, Y, Bohnen, NI, Seidler, R. Dopamine overdose hypothesis: evidence and clinical implications. Mov Disord. 2013; 28(14): 19201929.Google Scholar
19. MacDonald, AA, Mondhi, O, Seergobin, KN, Ganjavi, H, Tamjeedi, R, MacDonald, PA. Parkinson’s disease duration determines effect of dopaminergic therapy on ventral striatum function. Mov Disord. 2013; 28(2): 153160.CrossRefGoogle Scholar
20. Joutsa, J, Johansson, J, Seppänen, M, Noponen, T, Kaasinen, V. Dorsal-to-ventral shift in midbrain dopaminergic projections and increased thalamic/raphe serotonergic function in early Parkinson disease. J Nucl Med. 2015; 56(7): 10361041.Google Scholar
21. MacDonald, PA, Monchi, O. Differential effects of dopaminergic therapies on dorsal and ventral striatum in Parkinson’s disease: implications for cognitive function. Parkinson’s Disease. 2011, Article ID 572743, 2011. doi:10.4061/2011/572743.Google Scholar
22. Birkmayer, W, Danielczyk, W, Neumayer, E, Riederer, P. Nucleus ruber and L-dopa psychosis: biochemical post-mortem findings. J Neural Transm. 1974; 35(2): 93116.Google Scholar
23. Halliday, GM, Blumbergs, PC, Cotton, RGH, Blessing, WW, Geffen, LB. Loss of brainstem serotonin- and substance P-containing neurons in Parkinson’s disease. Brain Res. 1990; 510(1): 104107.Google Scholar
24. Fox, SH, Chuang, R, Brotchie, JM. Serotonin and Parkinson’s disease: on movement, mood and madness. Mov Disord. 2009; 24(9): 12551266.Google Scholar
25. Albin, RL, Koeppe, RA, Bohnen, NI, Wernette, K, Kilbourn, MA, Frey, KA. Spared caudal brainstem SERT binding in early Parkinson’s disease. J Cereb Blood Flow Metab. 2008; 28(3): 441444.Google Scholar
26. Ohno, Y, Shimizu, S, Tokudome, K, Kunisawa, N, Sasa, M. New insight into the therapeutic role of the serotonergic system in Parkinson’s disease. Prog Neurobiol. 2015; 134: 104121.CrossRefGoogle ScholarPubMed
27. Politis, M, Niccolini, F. Serotonin in Parkinson’s disease. Behav Brain Res. 2015; 277: 136145.Google Scholar
28. Huot, P, Fox, SH. The serotonergic system in motor and non-motor manifestations of Parkinson’s disease. Exp Brain Res. 2013; 230(4): 463476.Google Scholar
29. Cheng, AVT, Ferrier, IN, Morris, CM, et al. Cortical serotonin-S2 receptor binding in Lewy body dementia, Alzheimer’s and Parkinson’s diseases. J Neurol Sci. 1991; 106(1): 5055.Google Scholar
30. Kerenyi, L, Ricaurte, GA, Schretlen, DJ, et al. Positron emission tomography of striatal serotonin transporters in Parkinson disease. Arch Neurol. 2003; 60(9): 12231229.Google Scholar
31. Kometer, M, Schmidt, A, Jäncke, L, Vollenwider, FX. Activations of serotonin 2A receptors underlies the psilocybin-induced effects on αoscillations, N170 visual-evoked potentials, and visual hallucinations. J Neurosci. 2013; 33(25): 1054410551.Google Scholar
32. Sadzot, B, Baraban, JM, Glennon, RA, et al. Hallucinogenic drug interactions at human brain 5-HT2 receptors: implications for treating LSD-induced hallucinogenesis. Psychopharmacology (Berl). 1989; 98(4): 494499.Google Scholar
33. McClue, SJ, Brazell, C, Stahl, SM. Hallucinogenic drugs are partial agonists of the human platelet shape change response: a physiological model of the 5-HT2 receptor. Biol Psychiatry. 1989; 26(3): 297302.Google Scholar
34. Stahl, SM. Mechanism of action of pimavanserin in Parkinson’s disease psychosis: targeting serotonin 5HT2A and 5HT2C receptors. CNS Spectr. 2016; 21(4): 271275.CrossRefGoogle Scholar
35. Cummings, J, Isaacson, S, Mills, R, et al. Pimavanserin for patients with Parkinson’s disease psychosis: a randomized, placebo-controlled phase 3 trial. Lancet. 2014; 383(9916): 533540.Google Scholar
36. Hermanowicz, S, Hermanowicz, N. The safety, tolerability and efficacy of pimavanserin tartrate in the treatment of psychosis in Parkinson’s disease. Expert Rev Neurother. 2016; 16(6): 625633.CrossRefGoogle ScholarPubMed
37. Friedman, JH. Pimavanserin for the treatment of Parkinson’s disease psychosis. Expert Opin Pharmather. 2013; 14(14): 19691975.Google Scholar
38. Zahodne, LB, Fernandez, HH. Pathophysiology and treatment of psychosis in Parkinson’s disease: a review. Drugs Aging. 2008; 25(8): 665682.Google Scholar
39. Desmarais, P, Massoud, F, Filion, J, Nguyen, QD, Bajsarowicz, P. Quetiapine for psychosis in Parkinson disease and neurodegenerative parkinsonian disorders: a systematic review. J Geriatr Psychiatry Neurol. 2016; 29(4): 227236.Google Scholar
40. Stahl, SM. Stahl’s Essential Psychopharmacology, 4th ed. Cambridge, UK: Cambridge University Press; 2013.Google Scholar
41. Meltzer, HY, Stahl, SM. The dopamine hypothesis of schizophrenia: a review. Schizophr Bull. 1976; 2(1): 1976.Google Scholar
Figure 0

Figure 1 Serotonin-dopamine balance. Normally, serotonin and dopamine are balanced in neuronal circuits. Shown here are serotonin (5HT) 2A receptors regulating gamma amino butyric acid (GABA) and glutamate in the cerebral cortex and dopamine in the downstream ventral tegmental area and the ventral striatum.

Figure 1

Figure 2 Parkinson’s disease: nigrostriatal dopamine/D2 deficiency. In Parkinson’s disease, Lewy bodies accumulate in the substantia nigra, causing them to degenerate and lose their dopamine in nerve terminals projecting to the dorsal striatum. This causes a nigrostriatal dopamine/D2 deficiency resulting in the motor symptoms of Parkinson’s disease, namely akinesia, rigidity, and tremor.

Figure 2

Figure 3 Parkinson’s disease psychosis: cortical serotonin/5HT2A and mesolimbic dopamine/D2 excess superimposed upon nigrostriatal dopamine D2 deficiency. After the development of nigrostriatal dopamine/D2 deficiency and the motor symptoms of Parkinson’s disease shown in Figure 2, some patients progress to having Lewy bodies accumulate in cerebral cortex, upregulating 5HT2A receptors, resulting in their excessive activation and the development of visual hallucinations of PDP in visual and temporal brain circuits and downstream enhancement of ventral striatal dopamine, also causing delusions and auditory hallucinations of PDP.

Figure 3

Figure 4 L-DOPA psychosis: dorsal to ventral shift and dopamine overdose. In some patients with Parkinson’s disease, psychosis develops because of a dorsal to ventral shift in the sensitivity of the striatum to dopaminergic treatments. This results in over-activity of the ventral striatum, just like that postulated to occur in schizophrenia, and the production of psychotic symptoms such as delusions and auditory hallucinations, also just like those seen in schizophrenia.