Resistance to barbiturate is changed by developmental alteration of dopamine receptor sensitivity

Prenatal exposition to haloperidol: A preclinical narrative review

Pre-existing maternal mental disorders may affect the early interactions between mother and baby, impacting the child's psychoemotional development. The typical antipsychotic haloperidol can be used during pregnancy, even with some restrictions. Its prescription is not limited to psychotic disorders, but also to other psychiatric conditions of high incidence and prevalence in the woman's fertile period. The present review focused on the preclinical available data regarding the biological and behavioral implications of embryonic exposure to haloperidol. The understanding of the effects of psychotropic drugs during neurodevelopment is important for its clinical aspect since there is limited evidence regarding the risks of antipsychotic drug treatment in pregnant women and their children. Moreover, a better comprehension of the mechanistic events that can be affected by antipsychotic treatment during the critical period of neurodevelopment may offer insights into the pathophysiology of neurodevelopmental disorders. The findings presented in this review converge to the existence of several risks associated with prenatal exposure to such medication and emphasize the need for further studies regarding its dimensions.

Altered brain sensitivity to ethanol in mice after MPTP treatment

Previous studies demonstrated the role of the dopaminergic receptors in brain sensitivity to ethanol. The present study was designed to assess the relative contribution of the nigrostriatal component to this brain sensitivity. Adult male C57BL mice were given 1-Methyl-4-Phenyl-1,2,3,6-Tetrahydropyridine (MPTP) injections (30 mg/kg daily for 2 consecutive days). The treatment decreased the striatal dopamine level by 35% from the control level, and the number (Bmax) of dopaminergic receptors was increased by 67%. Ethanol-induced sleep time was reduced in the MPTP-treated mice, as compared to controls, and this gap progressively widened during the 3 weeks of testing to 29%. Brain ethanol levels upon awakening increased by 22%. The results suggest that the nigrostriatal dopaminergic pathways play a major role in determining brain sensitivity to ethanol which may represent an important component in the addictive process.

Behavioral effects of prenatal haloperidol exposure

Pregnant albino rats were exposed to vehicle (CON), 2.5 mg/kg (LOW) or 5.0 mg/kg (HIGH) haloperidol (HAL) from the sixth through the twentieth day of gestation. The effect of prenatal HAL exposure on offspring was assessed with the following five behavioral measures: 1) milk-induced behavioral activation on the sixth postnatal day (PND 6), 2) shock-precipitated wall climbing (PNDs 9, 11, 13, 15 and 17), 3) amphetamine-induced stereotypies (PND 30), 4) apomorphine-induced stereotypies (PND 30) and 5) duration of barbiturate anesthesia (PNDs 34 and 62). Measures taken very early in life indicated that prenatal HAL reduced arousal. Inactivity scores were elevated in HAL-exposed pups on PND 6 during milk-induced behavioral activation. Shock-precipitated wall climbing was reduced in the HAL animals on PNDs 9 and 11, but not thereafter. At PND 30, no prenatal treatment effect was detectable on stimulant-induced stereotypies or on duration of barbiturate anesthesia. On PND 62, barbiturate anesthesia duration was significantly reduced in both sexes of HIGH HAL animals. These findings suggest that prenatal HAL effects follow a dynamic, changing course as the exposed rat pup matures. Early reductions in arousal (milk-induced behavior and shock-precipitated wall climbing) wane with age, perhaps to be replaced by an actual increase in arousal as HAL pups approach adulthood.

Chronic treatment with haloperidol affect the response of the brain to pentobarbital

Treatment of mice with haloperidol increased the number of dopamine D2 receptors (Bmax). The animals were given 40 or 50 mg of pentobarbital. Animals treated with haloperidol had a shorter duration of narcosis induced by pentobarbital than the controls, suggesting a decreased sensitivity to pentobarbital which was functional (CNS), since the animals treated with haloperidol had higher levels of pentobarbital in the brain upon awakening than the controls. The results suggest that increased Bmax reduces the sensitivity of the brain to pentobarbital.