Tardive Dyskinesia: Outcome of Antipsychotic Treatment and Brain Damage?

Kostrzewa, Richard M., Kostrzewa, John P., Brus, Ryszard

01 January 2014

Tardive dyskinesia (TD), marked by abnormal involuntary movements and frequently expressed as perioral activity, represents an adverse outcome of prolonged antipsychotic therapy, occurring in approximately 5 % of patients per treatment year. Although neuronal mechanisms underlying TD are largely unknown, more recent experimental studies in animal models of TD are providing insight into the neuronal mechanisms associated with TD and implicating newer treatment approaches. It is now evident that a predominance in the ratio of dopamine (DA) D1:D2 receptor (R) activation accounts for induction of perioral movements in rodent models of TD, in nonhuman primate models of TD, and in humans with TD. Experimentally, TD is produced in animal models of TD, in a manner analogous to that by which TD is produced in humans - by continuous and prolonged administration of a DA D2R antagonist (i.e., an antipsychotic drug). More recently, in a rodent model of TD, it has been shown that a lesion of dopaminergic - mainly nigroneostriatal - neurons reduces the time latency for occurrence of TD, also increases the severity of perioral activity, and results in permanence of TD after complete removal of D2R antagonist treatment. The induction of perioral activity is related to DAR supersensitivity but unrelated to numbers of D2R and D2R in the neostriatum, a brain region associated with perioral activity. More apropos, serotoninergic systems are now recognized as having a greater role in effecting perioral activity, and it appears that 5-HT2C receptor antagonists are most effective in abating perioral activity in a rodent model of TD. These processes and mechanisms, topics addressed in this chapter, highlight a newer understanding of mechanisms underlying TD and provide insight into new approaches towards treatment of TD in humans.

5

7-dihydroxytryptamine

5- HT receptor 2

5-hydroxytryptamine

6- hydroxydopamine

D receptor 1

D receptor 2

dopamine

haloperidol

perioral movements

receptor supersensitivity

serotonin

tardive dyskinesia

vacuous chewing

Biomedical Sciences

Ingestão da tintura de valeriana officinalis protege da discinesia orofacial induzida por reserpina em ratos / Intake of the valeriana officinalis tincture protects against orofacial dyskinesia induced by reserpine in rats

Pereira, Romaiana Picada

15 April 2009

Conselho Nacional de Desenvolvimento Científico e Tecnológico / Considering the hypothesis that GABA and oxidative stress are involved in the development of oral movements associated with important neuropathologies, the present study investigated the possible ability of V. officinalis in the prevention of vacuous chewing movements (VCMs) induced by reserpine in rats. Adult male rats were treated with reserpine (1 mg/kg, s.c.) and/or with V. officinalis (in the drinking water). VCMs, locomotor activity and oxidative stress measurements were evaluated. The neuroprotective effect of V. officinalis against iron-induced cell toxicity was investigated in brain cortical slices. Furthermore, we carried out the identification of valeric acid and gallic acid by HPLC in the V. officinalis tincture. Our findings demonstrate that reserpine caused a marked increase on VCMs and the co-treatment with V. officinalis was able to reduce the intensity of VCM. Reserpine did not induce oxidative stress in cerebral structures (cortex, hippocampus, striatum and substantia nigra). However, a significant positive correlation between DCF-oxidation (an estimation of oxidative stress) in the cortex and VCMs (p<0.05) was observed. Moreover, a tendency for a negative correlation between Na+K+- ATPase activity in substantia nigra and the number of VCMs was observed (p= 0.06). In vitro, V. officinalis protected brain cortical slices viability against Fe(II)-induced neurotoxicity. In conclusion, V. officinalis had in vitro and in vivo neuroprotective effects in rats, i.e., reduced Fe(II) neurotoxicity and reserpine-induced VCMs, probably via modulation of oxidative stress in specific brain nucleus and its GABA-mimetic action. However, the mechanisms involved in this protective activity needs to further investigated to better understand the action of V. officinalis. / Considerando as hipóteses do papel da neurotransmissão gabaérgica e do estresse oxidativo no desenvolvimento de movimentos orais associados a neuropatologias importantes, o presente estudo investigou a possível habilidade da tintura de V. officinalis na prevenção dos movimentos de mascar no vazio (MMV) induzidos por reserpina em ratos. Os animais foram tratados com reserpina (1 mg/Kg, s.c.) e/ou com V. officinalis (na água de beber). MMV, atividade locomotora e medidas de estresse oxidativo foram avaliadas. O efeito neuroprotetor da V. officinalis contra a toxicidade celular induzida por ferro foi investigada em fatias de córtex cerebral. Além disso, fez-se a identificação do ácido valérico e do ácido gálico por HPLC na tintura de V. officinalis. Os resultados demonstram que a reserpina causou um aumento nos MMV quando comparado com o seu veículo e o co-tratamento com V. officinalis foi capaz de reduzir a intensidade dos MMV. A reserpina não alterou de forma significativa alguns parâmetros de estresse oxidativo analisados nas estruturas do cérebro (córtex, hipocampo, estriado e substantia nigra). Porém, uma correlação positiva entre os níveis de oxidação da DCF (uma estimativa do estresse oxidativo) no cortex e o número de MMV (p<0.05) foi observada. Além disso, foi observada uma tendência a haver uma correlação negativa entre a atividade da Na+/K+- ATPase na substantia nigra e o número de MMV (p= 0.055). In vitro, V. officinalis protegeu as fatias de córtex cerebral contra a neurotoxicidade induzida por ferro. Desta forma, pode-se concluir que a V. officinalis apresentou efeitos neuroprotetores em ratos tanto in vitro quanto in vivo, ou seja, reduziu a neurotoxicidade induzida por ferro e os MMV induzidos por reserpina, provavelmente via modulação do estresse oxidativo em núcleos específicos do cérebro e sua ação gabamimética. Porém, os mecanismos envolvidos nesta atividade protetora necessitam de mais investigações para melhor entender a ação da V. officinalis.

Valeriana officinalis

Reserpina

Discinesia Tardia

Doença de Parkinson

Estresse Oxidativo

Movimentos de Mascar no Vazio

Discinesia Orofacial

Ácido Gálico

Ácido Valerico

Valeriana officinalis

Reserpine

Tardive Dyskinesia

Parkinson s disease

Oxidative stress

Vacuous chewing movements

Oral Dyskinesia

Gallic Acid

Valeric Acid

CNPQ::CIENCIAS BIOLOGICAS::BIOQUIMICA

Anti-Psychotic Drug Induced Tardive Dyskinesia: A Role for the Anti-Apoptotic Molecule Curcumin

Sookram, Christal D.

10 1900

<p>Anti-psychotic drug (APD) administration can induce movement disorders including tardive dyskinesia (TD), characterized by abnormal movements of the oro-facial region and occasionally the trunk and limbs. The most widely accepted model of TD is the APD-induced vacuous chewing movement (VCM). While the mechanism of induction of TD remains unclear, there are two prevailing hypothesis: oxidative stress and dopamine supersensitivity. Currently available APDs antagonize dopamine D2 receptors (D2R) which can result in excessive dopamine accumulation and oxidation which was demonstrated to induce striatal neurodegeneration and increased oxidative stress. The dopamine supersensitivity hypothesis proposes that APD treatment causes an up-regulation of high affinity D2Rs to compensate for D2R antagonism. Curcumin, a derivative of turmeric, has been demonstrated to affect dopamine levels and hold significant anti-apoptotic potential. Thus, the goal of this study was to investigate curcumin’s potential to prevent haloperidol-induced behavioural and biochemical abnormalities. Four groups of rats were treated daily: control; haloperidol (at 2mg/kg intra-peritoneally); curcumin (at 200mg/kg orally in jello) and curcumin plus haloperidol. VCMs, catalepsy and locomotor activity were assessed. Animals were sacrificed and tissues removed for qPCR, immunoblot, receptor binding, and UPLC assessments. At day14 there was a significant increase in VCMs and catalepsy following haloperidol treatment, which was prevented by curcumin treatment. However, curcumin did not alter locomotor activity. Curcumin was demonstrated to increase the expression of the anti-apoptotic molecule BclXL and to increase striatal D2Rs. These investigations support the potential of curcumin in the prevention of TD and provide insight into the complex pathophysiology of this disorder.</p> / Doctor of Philosophy (Medical Science)

TARDIVE DYSKINESIA

ANTI-PSYCHOTIC DRUGS

VACUOUS CHEWING MOVEMENT

CATALEPSY

LOCOMOTOR ACTIVITY

CURCUMIN

BclXL

Behavior and Behavior Mechanisms

Medical Neurobiology

Medical Pharmacology

Medicinal and Pharmaceutical Chemistry

Medicine and Health Sciences

Neurosciences

Pharmaceutical Preparations

Psychiatric and Mental Health

Behavior and Behavior Mechanisms