Longitudinal MRI monitoring of brain damage in the neonatal ventral hippocampal lesion rat model of schizophrenia

Rat with excitotoxic neonatal ventral hippocampal lesions (NVHL rats) is considered as a heuristic neurodevelopmental model for studying schizophrenia. Extensive study of this model is limited by the lack of clear validity criteria of such lesions and because ascertaining of the lesions is realized postmortem with histological examination after completing experiments. Here, in a first experiment, by assessing the locomotor response to amphetamine in adult NVHL rats, we further specify that the lesions must be bilateral and confined to the ventral hippocampus to obtain the validated behavioral phenotype. We then show a longitudinal magnetic resonance imaging (MRI) protocol suitable for the detection of brain structural changes in NVHL rats. The T₂‐weighted images acquired in adult NVHL rats reveal the same structural changes as those appraised with histological protocol. Moreover, we demonstrate that the lesion status in adulthood can be accurately predicted from the T₂‐weighted images acquired in the juvenile period. As technical advantages, our MRI protocol makes possible to select animals according to lesion criteria as soon as in the juvenile period before long‐lasting experiments and gives access in vivo to a quantitative parameter indicative of the lesion extent. Finally, we show that the lesion size increases only slightly between juvenile and adult periods. These latter results are discussed in the context of the specific postpubertal emergence of the behavioral deficits in NVHL rats. © 2009 Wiley‐Liss, Inc.     

Neonatal ventral hippocampal lesions potentiate amphetamine-induced increments in dopamine efflux in the core, but not the shell, of the nucleus accumbens.

BACKGROUND: In rats, neonatal ventral hippocampal lesions (NVHLs) result in the postpubertal emergence of alterations reminiscent of several features of schizophrenia, including increased responsivity to the behavioral effects of amphetamine (AMPH). The precise nature of presynaptic aspects of accumbal dopamine (DA) function in these alterations is however uncertain: previous studies have found that the exacerbated responses to AMPH of NVHL rats are associated with either decreased or unchanged DA efflux in the nucleus accumbens (NAc) as compared with shams. Because these studies investigated DA output in the whole NAc, it was considered of interest to examine the impact of NVHLs on DA transmission in NAc subregions involved in distinct aspects of goal-directed behavior. METHODS: The effects of AMPH (.25 mg/kg, subcutaneous) on the accumbal DA efflux of adult rats were evaluated using brain microdialysis, and motor activity was recorded alongside dialysate sample collection. RESULTS: The enhanced behavioral responsivity to AMPH of NVHL rats is associated with potentiation of AMPH-induced DA output in the NAc core and a concomitant attenuation of DA overflow in the NAc shell. CONCLUSIONS: The functional alterations in the NAc core induced by NVHLs provide a link between the hippocampal damage and striatal DA hyperactivity in schizophrenia.     

Animal modeling dual diagnosis schizophrenia: sensitization to cocaine in rats with neonatal ventral hippocampal lesions.

BACKGROUND: Increased substance disorder comorbidity in schizophrenia may reflect greater vulnerability to addictive processes because of inherent neurocircuit dysfunction in the schizophrenic brain. METHODS: To further explore this hypothesis, we used neonatal ventral hippocampal lesions (NVHL) as a rat model of schizophrenia and assessed locomotor sensitization to cocaine (15 mg/kg) in adulthood. RESULTS: The NVHL animals showed greater activity in response to an initial cocaine injection compared with sham and saline-treated groups. With daily cocaine injections over 7 days, NVHL rats showed elevated locomotor sensitization curves with greater fluctuations in the intersession changes in activity between days 4 and 7. In a single session 4 weeks later, NVHL compared with SHAM rats showed maintenance of cocaine-associated hyperactivity, as if superimposed on long-term sensitization effects present in both groups. CONCLUSIONS: In a neurodevelopmental model of schizophrenia, the locomotor effects of cocaine were augmented on initial and repeated doses, with emergence of irregularity in sensitization-related changes in activity in the short term and perseverance of augmented effects in the long term. Altered patterns of behavioral sensitization, as a possible correlate of greater addiction vulnerability, can occur as a by-product of neural systems dysfunction responsible for major psychiatric syndromes.     

Prefrontal dopamine release and sensory-specific satiety altered in rats with neonatal ventral hippocampal lesions

Rats with a neonatal ventral hippocampal lesion (NVHL) have been used to model certain features of schizophrenia because they display dopaminergic activity and behavioral alterations consistent with a dysfunctional prefrontal cortex after puberty. Microdialysis studies in normal rats demonstrated increased prefrontal dopamine release during the incentive phase of behavior in an experimental situation specifically designed to evidence this behavioral aspect: the so called "sensory-specific satiety" procedure. Our hypothesis is that if dopaminergic activity in the prefrontal cortex of NVHL rats differs from sham lesioned rats, the responsiveness to the aforementioned experimental situation should also be different. Extracellular medial prefrontal dopamine outflow increased in hungry control rats when they had access to food and decreased across satiety. It increased again when a new food was presented, even when the rats were satiated. NVHL rats also had increased dopamine prefrontal outflow in these conditions, but it remained high after the end of the consumption period. The food consumption behavior declined less rapidly and the reinstatement of food consumption, usually produced by new food, did not occur in NVHL rats, provided the lesions were large. These data were discussed in relation to several theoretical backgrounds developed about the incentive aspect of behavior and for understanding the pathophysiology of schizophrenia.     

Neonatal ventral hippocampal damage modifies serum corticosterone and dopamine release responses to acute footshock in adult Sprague-Dawley rats

Rats with excitotoxic neonatal ventral hippocampal lesions (NVHL) manifest in early adulthood a variety of behavioral and neurochemical abnormalities mimicking those seen in patients with schizophrenia. Some of these aberrations implicate malfunction of the midbrain dopamine systems. We studied NVHL effects on dopamine release in the rat frontal cortex, nucleus accumbens, and striatum during acute stress caused by inescapable continuous footshock (0.45 mA). Serum total corticosterone and prolactin levels were used as peripheral indices of stress. As an indirect index of dopamine release, tissue 3-methoxytyramine levels attained in vivo 10 min after monoamine oxidase inhibition was assayed in rats sacrificed by instantaneous microwave fixation of the brain tissue. Nonshocked NVHL rats showed significantly less nucleus accumbens' 3-methoxytyramine accumulation than their sham counterparts. Frontal cortical 3-methoxytyramine levels rose similarly after 20-min footshock in both groups of rats, but while it normalized after 60-min footshock in the sham rats, it did not decrease in the NVHL rats. Nucleus accumbens' 3-methoxytyramine was significantly elevated after either 20-min or 60-min footshock in both groups, whereas striatal 3-methoxytyramine was significantly elevated in the NVHL rats only. Serum corticosterone showed similar elevations in the sham and NVHL rats, but the patterns differed in that there was no attenuation after 60-min footshock in the latter. The lesion did not affect serum prolactin response. These data indicate that neonatal ventral hippocampal damage enhances and prolongs certain neural and neuroendocrine responses to acute physical stressor(s), and thus may affect adaptation and enhance detrimental effects of stress.     

Alterations in GABA(A) receptor expression in neonatal ventral hippocampal lesioned rats: comparison of prepubertal and postpubertal periods

Rats with neonatal ventral hippocampal lesions (NVHL) have been studied as a neurodevelopmental animal model of schizophrenia. NVHL rats exhibit postpubertal emergence of hyperresponsiveness to stress, suggesting increased mesolimbic dopamine (DA) activity. However, previous studies have not yielded clear evidence of this. Disturbances in the gamma-amino-butyric acid (GABA)-ergic system as well as the dopaminergic system are thought to be present in schizophrenia. To determine whether GABA(A) receptors play a role in the abnormal postpubertal behavior in NVHL rats, we compared changes in expression of mRNA of GABA(A) receptor subunits and in [(35)S] t-butylbicyclophosphorothionate ([(35)S] TBPS) binding in the prepubertal and postpubertal periods. Male pups were lesioned with ibotenic acid at postnatal day 7 (PD 7), and in situ hybridization and quantitative autoradiography were then performed. In NVHL rats, alpha1 subunit mRNA expression in prefrontal cortex was decreased at PD 35 (prepubertal period; by 21.7%), but increased at PD 56 (postpubertal period; by 21.4%) when compared with sham controls. beta2 subunit mRNA expression was increased in PFC in the postpubertal period (by 24.3%). beta3 subunit mRNA expression was increased in the caudate-putamen in the postpubertal period (by 37.2%). [(35)S] TBPS binding was increased in PFC only in the postpubertal period (by 17.7%). These findings suggest that dysfunction of the GABAergic system exists in NVHL rats. Furthermore, developmental and regional changes in GABA(A) receptor expression appear to occur in compensation for the attenuation of GABAergic system activity in NVHL rats.     

Post-pubertal disruption of medial prefrontal cortical dopamine-glutamate interactions in a developmental animal model of schizophrenia.

BACKGROUND: A neonatal ventral hippocampal lesion (NVHL) induces behavioral and physiological anomalies mimicking pathophysiological changes of schizophrenia. Because prefrontal cortical (PFC) pyramidal neurons recorded from adult NVHL rats exhibit abnormal responses to activation of the mesocortical dopaminergic (DA) system, we explored whether these changes are due to an altered DA modulation of pyramidal neurons. METHODS: Whole-cell recordings were used to examine the effects of DA and glutamate agonists on cell excitability in brain slices obtained from pre- (postnatal day [PD] 28-35) and post-pubertal (PD > 61) sham and NVHL animals. RESULTS: N-methyl d-aspartate (NMDA), alpha-amino-3-hydroxy-5-methylisoxazole propionate (AMPA), and the D(1) agonist SKF38393 increased excitability of deep layer pyramidal neurons in a concentration-dependent manner. The opposite effect was observed with the D(2) agonist quinpirole. The effects of NMDA (but not AMPA) and SKF38393 on cell excitability were significantly higher in slices from NVHL animals, whereas quinpirole decrease of cell excitability was reduced. These differences were not observed in slices from pre-pubertal rats, suggesting that PFC DA and glutamatergic systems become altered after puberty in NVHL rats. CONCLUSIONS: A disruption of PFC dopamine-glutamate interactions might emerge after puberty in brains with an early postnatal deficit in hippocampal inputs, and this disruption could contribute to the manifestation of schizophrenia-like symptoms.     

Increased cell proliferation in the rat anterior cingulate cortex following neonatal hypoxia: relevance to schizophrenia

As a consequence of obstetric complications, neonatal hypoxia has been discussed as an environmental factor in the pathophysiology of schizophrenia. However, the biological consequences of hypoxia are unclear. The neurodevelopmental hypothesis of schizophrenia suggests that the onset of abnormal brain development and neuropathology occurs perinatally, whereas symptoms of the disease appear in early adulthood. In our animal model of chronic neonatal hypoxia, we have detected behavioral alterations resembling those known from schizophrenia. Disturbances in cell proliferation possibly contribute to the pathophysiology of this disease. In the present study, we used postnatal rats to investigate cell proliferation in several brain areas following neonatal hypoxia. Rats were repeatedly exposed to hypoxia (89 % N₂, 11 % O₂) from postnatal day (PD) 4–8. We then evaluated cell proliferation on PD 13 and 39, respectively. These investigations were performed in the anterior cingulate cortex (ACC), caudate-putamen (CPU), dentate gyrus, and subventricular zone. Rats exposed to hypoxia exhibited increased cell proliferation in the ACC at PD 13, normalizing at PD 39. In other brain regions, no alterations have been detected. Additionally, hypoxia-treated rats showed decreased CPU volume at PD 13. The results of the present study on the one hand support the assumption of chronic hypoxia influencing transient cell proliferation in the ACC, and on the other hand reveal normalization during ageing.     

Neonatal intrahippocampal injection of lipopolysaccharide induces deficits in social behavior and prepulse inhibition and microglial activation in rats: Implication for a new schizophrenia animal model

Several lines of evidence have suggested that the dysregulation of immune system is involved in the pathogenesis of schizophrenia. Microglia are the resident macrophage of the brain and the major player in innate immunity in the brain. We hypothesized that microglia activation may be closely associated with the neuropathology of schizophrenia. Neonatal intrahippocampal injection of lipopolysaccharide (LPS), an activator of microglia, was performed in rats at postnatal day 7 (PD7), and they were separately treated with saline or minocycline for consecutive 3 days. Behavioral changes (locomotor activity, social interaction and prepulse inhibition) were examined in adulthood, and the number of microglia was assessed using immunohistochemistry at PD9, PD21 and PD67. The adult rats in LPS-injected group showed obvious behavioral alterations (deficits in social behavior and prepulse inhibition) and a persistently dramatic increase of number of activated microglial cells in the hippocampus, cerebral cortex and thalamus compared to those in saline-injected group. Interestingly, pretreatment with minocycline could significantly rescue the behavioral deficits and prevent microglia activation. Our results suggest that neonatal intrahippocampal LPS injection may serve as a potential schizophrenia animal model, and inhibition of microglia activation may be a potential treatment strategy for schizophrenia.     

A neurodevelopmental model of schizophrenia: neonatal disconnection of the hippocampus

In the context of our current knowledge about schizophrenia, heuristic models of psychiatric disorders may be used to test the plausibility of theories developed on the basis of new emerging biological findings, explore mechanisms of schizophrenia-like phenomena, and develop potential new treatments. In a series of studies, we have shown that neonatal excitotoxic lesions of the rat ventral hippocampus (VH) may serve as a heuristic model. The model appears to mimic a spectrum of neurobiological and behavioral features of schizophrenia, including functional pathology in presumably critical brain regions interconnected with the hippocampal formation and targeted by antipsychotic drugs - the striatum/nucleus accumbens and the prefrontal cortex, and leads in adolescence or early adulthood to the emergence of abnormalities in a number of dopamine related behaviors. Moreover, our data show that even transient inactivation of the ventral hippocampus during a critical period of development, that produces subtle, if any, anatomical changes in the hippocampus, may be sufficient to disrupt normal maturation of the prefrontal cortex (and perhaps, other interconnected late maturing regions) and trigger behavioral changes similar to those observed in animals with the permanent excitotoxic lesion. These results represent a potential new model of aspects of schizophrenia without a gross anatomical lesion.     

Enduring increases in anxiety‐like behavior and rapid nucleus accumbens dopamine signaling in socially isolated rats

Social isolation (SI) rearing, a model of early life stress, results in profound behavioral alterations, including increased anxiety‐like behavior, impaired sensorimotor gating and increased self‐administration of addictive substances. These changes are accompanied by alterations in mesolimbic dopamine function, such as increased dopamine and metabolite tissue content, increased dopamine responses to cues and psychostimulants, and increased dopamine neuron burst firing. Using voltammetric techniques, we examined the effects of SI rearing on dopamine transporter activity, vesicular release and dopamine D2‐type autoreceptor activity in the nucleus accumbens core. Long–Evans rats were housed in group (GH; 4/cage) or SI (1/cage) conditions from weaning into early adulthood [postnatal day (PD) 28–77]. After this initial housing period, rats were assessed on the elevated plus‐maze for an anxiety‐like phenotype, and then slice voltammetry experiments were performed. To study the enduring effects of SI rearing on anxiety‐like behavior and dopamine terminal function, another cohort of similarly reared rats was isolated for an additional 4 months (until PD 174) and then tested. Our findings demonstrate that SI rearing results in lasting increases in anxiety‐like behavior, dopamine release and dopamine transporter activity, but not D2 activity. Interestingly, GH‐reared rats that were isolated as adults did not develop the anxiety‐like behavior or dopamine changes seen in SI‐reared rats. Together, our data suggest that early life stress results in an anxiety‐like phenotype, with lasting increases in dopamine terminal function.     

Altered prefrontal cortical metabolic response to mesocortical activation in adult animals with a neonatal ventral hippocampal lesion.

BACKGROUND: Adult animals with a neonatal ventral hippocampal lesion (NVHL) exhibit deficits in working memory and sensorimotor gating similar to those observed in schizophrenia. As cognitive deficits in this disorder are typically associated with changes in cortical metabolic levels, we investigated here whether an NVHL affects metabolic responses to ventral tegmental area (VTA) activation, a procedure that elicits abnormal cell firing in the prefrontal cortex (PFC) of NVHL animals. METHODS: Prefrontal cortex metabolic activity was determined by measuring cytochrome oxidase I (CO-I) staining. Cytochrome oxidase I levels were quantified by densitometry in pre- and postpubertal sham-operated and lesioned rats that received one or three series of fifteen 20-Hz trains of VTA stimuli every 20 seconds. RESULTS: Ventral tegmental area stimulation yielded higher levels of PFC CO-I in NVHL animals when compared with the sham-operated group, an effect that appeared only after puberty. Increasing the series of burst stimulations further elevated CO-I in sham-operated, but not in NVHL animals. CONCLUSIONS: Increased PFC CO-I activity after VTA burst stimulation in NVHL rats highlights the enhanced energy demand that could be linked to the exaggerated response to stress observed in these animals. The inability to further increase the response with higher mesocortical activity, as observed in sham-operated animals, could be expression of a reduced PFC functional capacity in lesioned animals. Thus, a hyperexcitable PFC with a reduced ability to further increase activity could be a plausible pathophysiological scenario for schizophrenia. Human functional studies could be interpreted in the light of this conceptual framework.     

A neural plasticity hypothesis of schizophrenia

An extensive research effort has failed, thus far, to conclusively identify a specific disease process (or processes) underlying the behavioral symptoms of schizophrenia. The present paper will entertain the hypothesis that the structural and functional plasticity of the brain can constitute a "nonspecific" biological etiology of schizophrenia. This plasticity need not be accompanied by infectious processes or gross alterations in neurotransmitter levels, enzyme activities, etc. that are specific to schizophrenia. The monkey isolation syndrome provides a precedent for a causal relationship between brain plasticity and pathological behavior. In a speculative manner, it will be demonstrated that neural plasticity concepts can be invoked to potentially explain several aspects of schizophrenia: the various types of behavioral symptoms exhibited by schizophrenics, the regional alterations in brain structure and function seen in chronic schizophrenics, the involvement of genetic and environmental etiological factors, the pharmacological support for the dopamine hypothesis, and the delayed onset of neuroleptic antipsychotic action. Considering the explanatory potential of neural plasticity concepts, a research program which focuses on these concepts seems warranted.     

Review: Parkinson's disease: from synaptic loss to connectome dysfunction

Parkinson's disease (PD) is a common neurodegenerative disorder with prominent loss of nigro‐striatal dopaminergic neurons. The resultant dopamine (DA) deficiency underlies the onset of typical motor symptoms (MS). Nonetheless, individuals affected by PD usually show a plethora of nonmotor symptoms (NMS), part of which may precede the onset of motor signs. Besides DA neuron degeneration, a key neuropathological alteration in the PD brain is Lewy pathology. This is characterized by abnormal intraneuronal (Lewy bodies) and intraneuritic (Lewy neurites) deposits of fibrillary aggregates mainly composed of α‐synuclein. Lewy pathology has been hypothesized to progress in a stereotypical pattern over the course of PD and α‐synuclein mutations and multiplications have been found to cause monogenic forms of the disease, thus raising the question as to whether this protein is pathogenic in this disorder. Findings showing that the majority of α‐synuclein aggregates in PD are located at presynapses and this underlies the onset of synaptic and axonal degeneration, coupled to the fact that functional connectivity changes correlate with disease progression, strengthen this idea. Indeed, by altering the proper action of key molecules involved in the control of neurotransmitter release and re‐cycling as well as synaptic and structural plasticity, α‐synuclein deposition may crucially impair axonal trafficking, resulting in a series of noxious events, whose pressure may inevitably degenerate into neuronal damage and death. Here, we provide a timely overview of the molecular features of synaptic loss in PD and disclose their possible translation into clinical symptoms through functional disconnection.     

Sensory and sensorimotor gating deficits after neonatal ventral hippocampal lesions in rats

Neonatal ventral hippocampal lesions (NVHLs) in rats lead to reduced prepulse inhibition (PPI) of startle and other behavioral deficits in adulthood that model abnormalities in schizophrenia patients. A neurophysiological deficit in schizophrenia patients and their first-degree relatives is reduced gating of the P50 event-related potential (ERP). N40 ERP gating in rats may be a cross-species analog of P50 gating, and is disrupted in experimental manipulations related to schizophrenia. Here, we tested whether N40 gating as well as PPI is disrupted after NVHLs, using contemporaneous measures of these two conceptually related phenomena. Male rat pups received sham or ibotenic acid NVHLs on postnatal day 7. PPI was tested on days 35 and 56, after which rats were equipped with cortical surface electrodes for ERP measurements. One week later, PPI and N40 gating were measured in a single test, using paired S1-S2 clicks spaced 500 ms apart to elicit N40 gating. Compared to sham-lesioned rats, those with NVHLs exhibited PPI deficits on days 35 and 56. NVHL rats also exhibited reduced N40 gating and reduced PPI, when measured contemporaneously at day 65. Deficits in PPI and N40 gating appeared most pronounced in rats with larger lesions, focused within the ventral hippocampus. In this first report of contemporaneous measures of two important schizophrenia-related phenotypes in NVHL rats, NVHLs reproduce both sensory (N40) and sensorimotor (PPI) gating deficits exhibited in schizophrenia. In this study, lesion effects were detected prior to pubertal onset, and were sustained well into adulthood.     

Blunted brain metabolic response to ketamine in mice lacking D(1A) dopamine receptors

The interaction of glutamatergic and dopamine neurotransmission is thought to have relevance to both the pathophysiology and pharmacotherapy of schizophrenia. For example, subanesthetic doses of the N-methyl-D-aspartate receptor (NMDA-R) antagonist ketamine induce schizophrenia-like behavioral effects in humans and both behavioral and brain metabolic activation in rodents. Blockade of NMDA-R results in dopamine release, and antipsychotic drugs that block dopamine neurotransmission decrease NMDA-R antagonist-induced behavioral activation. The involvement of dopamine receptors in brain metabolic activation induced by ketamine is, however, unknown. The present study used D(1A) knockout mice to determine the role of dopamine D(1A) receptors in the effects of subanesthetic doses of ketamine on both behavioral responses and on alterations in regional [14C]2-deoxyglucose (2-DG) uptake. There was less ketamine-induced behavioral activation in D(1A) knockout mice than in wild-type mice. In wild-type mice, ketamine (30 mg/kg) induced dramatic increases in 2-DG uptake in limbic cortical regions, hippocampal formation, nucleus accumbens, basolateral amygdala, and caudal parts of the substantia nigra pars reticulata. D(1A) knockout mice exhibited blunted metabolic activation in response to ketamine in a neuroanatomically specific manner. The selective D(1) antagonist, SCH23390 (0.3 mg/kg), inhibited both ketamine-induced brain metabolic activation and behavioral responses in the wild-type mice, with a similar neuroanatomical specificity observed in the D(1A) knockout mice. Thus, the neuroanatomically selective role that D(1A) receptors play in ketamine-induced behavior and regional brain metabolic activation in mice provides a useful model for further studies of how the D(1A) receptor function may be altered in schizophrenia.     

Blunted brain metabolic response to ketamine in mice lacking D1A dopamine receptors

The interaction of glutamatergic and dopamine neurotransmission is thought to have relevance to both the pathophysiology and pharmacotherapy of schizophrenia. For example, subanesthetic doses of the N-methyl- -aspartate receptor (NMDA-R) antagonist ketamine induce schizophrenia-like behavioral effects in humans and both behavioral and brain metabolic activation in rodents. Blockade of NMDA-R results in dopamine release, and antipsychotic drugs that block dopamine neurotransmission decrease NMDA-R antagonist-induced behavioral activation. The involvement of dopamine receptors in brain metabolic activation induced by ketamine is, however, unknown. The present study used D_1A knockout mice to determine the role of dopamine D_1A receptors in the effects of subanesthetic doses of ketamine on both behavioral responses and on alterations in regional [¹⁴C]2-deoxyglucose (2-DG) uptake. There was less ketamine-induced behavioral activation in D_1A knockout mice than in wild-type mice. In wild-type mice, ketamine (30 mg/kg) induced dramatic increases in 2-DG uptake in limbic cortical regions, hippocampal formation, nucleus accumbens, basolateral amygdala, and caudal parts of the substantia nigra pars reticulata. D_1A knockout mice exhibited blunted metabolic activation in response to ketamine in a neuroanatomically specific manner. The selective D₁ antagonist, SCH23390 (0.3 mg/kg), inhibited both ketamine-induced brain metabolic activation and behavioral responses in the wild-type mice, with a similar neuroanatomical specificity observed in the D_1A knockout mice. Thus, the neuroanatomically selective role that D_1A receptors play in ketamine-induced behavior and regional brain metabolic activation in mice provides a useful model for further studies of how the D_1A receptor function may be altered in schizophrenia.     

New developments of brain imaging for Parkinson's disease and related disorders.

Parkinson's disease (PD) and related disorders are subcortical degenerations targeting the nigrostriatal dopaminergic system and basal ganglia. Traditionally, MRI has been used to detect structural and positron emission tomography and single emission computed tomography functional neurochemical and metabolic changes associated with these disorders. Recently, advances in diffusion-weighted MRI, ultrasonography, and radiotracer-based imaging have yielded greater sensitivity for revealing structural change and allowed detection of changes in brain dopamine levels after levodopa and during behavioral tasks. This review focuses on these recent advances in neuroimaging technology and their use for the diagnosis and assessment of PD and other parkinsonian disorders.     

Subthalamic nucleus stimulation and lesioning have distinct state‐dependent effects upon striatal dopamine metabolism

The mechanism by which deep brain stimulation (DBS) of the subthalamic nucleus (STN) achieves its effects in Parkinson's disease (PD) is not known. In animal models of PD, stimulation and lesioning of the STN have some effects which are the same, but others which differ, in reversing cellular and behavioral changes induced by dopamine depletion. We compared the effects of short‐term STN stimulation and lesions upon extracellular levels of dopamine and metabolites using in vivo microdialysis of the dorsal striatum of awake, intact and unilateral 6‐hydroxydopamine (6OHDA)‐lesioned rats. STN stimulation in control rats decreased striatal dopamine levels and caused a relative increase in dopamine metabolism, as expressed by HVA/dopamine and DOPAC/dopamine ratios. This suggests an increase in both vesicular dopamine release (metabolized to HVA), and release from the cytoplasmic dopamine pool (metabolized to DOPAC). STN lesions in control rats increased the HVA/dopamine ratio, also suggesting a relative increase in vesicular dopamine release. These results indicate that STN stimulation and lesioning can affect striatal dopamine metabolism in the intact system. In 6OHDA‐lesioned rats at baseline, metabolic ratios were markedly decreased as compared with controls. STN lesions of 6OHDA‐lesioned rats did not affect relative metabolic ratios as compared with baseline levels. In 6‐OHDA‐lesioned rats, STN stimulation decreased extracellular levels of dopamine, and, to a greater extent, metabolites, resulting in a decrease in metabolic ratios. This further decrease in dopamine turnover with STN stimulation would serve to maintain dopamine levels in the dopamine‐depleted striatum, and may account for the therapeutic benefit of DBS in Parkinson's disease. Synapse 63:136–146, 2009. Published 2008 Wiley‐Liss, Inc.     

Neonatal phencyclidine treatment selectively attenuates mesolimbic dopamine function in adult rats as revealed by methamphetamine-induced behavior and c-fos mRNA expression in the brain

One of the major hypotheses regarding the pathogenesis of schizophrenia is the implication of neurodevelopmental abnormality. However, the mechanism of delayed onset of schizophrenic symptoms, in which increased dopaminergic activity in mesolimbic or mesocortical dopamine systems plays a pathological role, is not known. In this study, we investigated whether the chronic blockade of N-methyl-D-aspartate (NMDA) receptor by phencyclidine (PCP), an NMDA channel blocker, during development could disrupt the dopamine system during later life. Neonatal rats were injected with PCP subcutaneously daily from postnatal day (PD) 1 to PD 14 and their dopaminergic function was evaluated on PD 42 by rating the methamphetamine (MAP)-induced behavior. To illustrate the activated brain regions, the expression of c-fos mRNA in response to a MAP challenge was also studied utilizing in situ hybridization. Chronic neonatal PCP treatment attenuated MAP-induced oral stereotypy (licking and gnawing) and reduced MAP-induced expression of c-fos mRNA in the N. accumbens shell region and VTA but not in the N. accumbens core region, medial striatum, or substantia nigra. These results suggest that neonatal blockade of NMDA receptor, which induces a number of effects in the developing nervous system, may cause long-lasting functional changes of the mesolimbic dopamine system.