Psychopharmacology

, Volume 116, Issue 2, pp 226–236 | Cite as

Investigations of fetal development models for prenatal drug exposure and schizophrenia. Prenatald-amphetamine effects upon early and late juvenile behavior in the rat

  • Melvin Lyon
  • William O. McClure
Article
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Abstract

Recent evidence suggests that mid-pregnancy is a critical period for production of fetal abnormalities that cause behavioral and neuropathological changes in adult offspring. The present experiments provide an animal model of these effects by treating pregnant Sprague-Dawley rats during gestational days 11–14 withd-amphetamine (AM). Offspring were tested for neurological signs, foraging activity, reversal learning, and sensitivity to amphetamine challenge. In the Early Juvenile period, postnatal days (PND) 20–30, female AM offspring initially showed reductions in rearing, holepoking, and midfield activity. On later trials, and as young adults, AM females showed signs of locomotor hyperactivity despite continued poor foraging efficiency, and were also more sensitive to a 1.0 mg/kgd-amphetamine challenge. AM males showed initially slower and more perseverative responding than controls, but then developed excessive response switching. These changes continued during tests for Retention, Reversal, and Extinction in the Late Juvenile/Early Adult stage (PND 50–90), when both AM-exposed sexes showed increased eating time, significantly more perseverative lateral turning preference (right or left), and slower reversal learning than controls. Behavioral data were consistent with aberrations in thalamo-frontal and mesolimbic/nigrostriatal projection systems that have been reported in AM animals and which are also affected by maternal drug abuse and schizophrenia.

Key words

Fetus Prenatal drug exposure Schizophreniad-Amphetamine Rat 
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Copyright information

© Springer-Verlag 1994

Authors and Affiliations

  • Melvin Lyon
    • 1
  • William O. McClure
    • 2
  1. 1.Center for Brain and Behavior Study University of Arkansas for Medical SciencesLittle RockUSA
  2. 2.Departments of Biological Science and NeurologyUniversity of Southern CaliforniaLos AngelesUSA

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