R. Andrew Chambers

The neonatal ventral hippocampal lesion as a heuristic neurodevelopmental model of schizophrenia.

Traditionally, animal models of schizophrenia were predominantly pharmacological constructs focused on phenomena linked to dopamine and glutamate neurotransmitter systems, and were created by direct perturbations of these systems. A number of developmental models were subsequently generated that allowed testing of hypotheses about the origin of the disease, mimicked a wider array of clinical and neurobiological features of schizophrenia, and opened new avenues for developing novel treatment strategies. The most thoroughly characterized (approximately 100 primary research articles) is the neonatal ventral hippocampal lesion (NVHL) model, which is the subject of this review. We highlight its advantages and limitations, and how it may offer clues about the extent to which positive, negative, cognitive, and other aspects of schizophrenia, including addiction vulnerability, represent inter-related pathophysiological mechanisms.

Network Modeling of Adult Neurogenesis: Shifting Rates of Neuronal Turnover Optimally Gears Network Learning according to Novelty Gradient

Apoptotic and neurogenic events in the adult hippocampus are hypothesized to play a role in cognitive responses to new contexts. Corticosteroid-mediated stress responses and other neural processes invoked by substantially novel contextual changes may regulate these processes. Using elementary three-layer neural networks that learn by incremental synaptic plasticity, we explored whether the cognitive effects of differential regimens of neuronal turnover depend on the environmental context in terms of the degree of novelty in the new information to be learned. In adult networks that had achieved mature synaptic connectivity upon prior learning of the Roman alphabet, imposition of apoptosis/neurogenesis before learning increasingly novel information (alternate Roman < Russian < Hebrew) reveals optimality of informatic cost benefits when rates of turnover are geared in proportion to the degree of novelty. These findings predict that flexible control of rates of apoptosis-neurogenesis within plastic, mature neural systems optimizes learning attributes under varying degrees of contextual change, and that failures in this regulation may define a role for adult hippocampal neurogenesis in novelty- and stress-responsive psychiatric disorders.

Adult hippocampal neurogenesis in the pathogenesis of addiction and dual diagnosis disorders

BACKGROUND As knowledge deepens about how new neurons are born, differentiate, and wire into the adult mammalian brain, growing evidence depicts hippocampal neurogenesis as a special form of neuroplasticity that may be impaired across psychiatric disorders. This review provides an integrated-evidence based framework describing a neurogenic basis for addictions and addiction vulnerability in mental illness. METHODS Basic studies conducted over the last decade examining the effects of addictive drugs on adult neurogenesis and the impact of neurogenic activity on addictive behavior were compiled and integrated with relevant neurocomputational and human studies. RESULTS While suppression of hippocampal neurogenic proliferation appears to be a universal property of addictive drugs, the pathophysiology of addictions involves neuroadaptative processes within frontal-cortical-striatal motivation circuits that the neurogenic hippocampus regulates via direct projections. States of suppressed neurogenic activity may simultaneously underlie psychiatric and cognitive symptoms, but also confer or signify hippocampal dysfunction that heightens addiction vulnerability in mental illness as a basis for dual diagnosis disorders. CONCLUSIONS Research on pharmacological, behavioral and experiential strategies that enhance adaptive regulation of hippocampal neurogenesis holds potential in advancing preventative and integrative treatment strategies for addictions and dual diagnosis disorders.

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.

A scale-free systems theory of motivation and addiction

Scale-free organizations, characterized by uneven distributions of linkages between nodal elements, describe the structure and function of many life-based complex systems developing under evolutionary pressures. We explore motivated behavior as a scale-free map toward a comprehensive translational theory of addiction. Motivational and behavioral repertoires are reframed as link and nodal element sets, respectively, comprising a scale-free structure. These sets are generated by semi-independent information-processing streams within cortical-striatal circuits that cooperatively provide decision-making and sequential processing functions necessary for traversing maps of motivational links connecting behavioral nodes. Dopamine modulation of cortical-striatal plasticity serves a central-hierarchical mechanism for survival-adaptive sculpting and development of motivational-behavioral repertoires by guiding a scale-free design. Drug-induced dopamine activity promotes drug taking as a highly connected behavioral hub at the expense of natural-adaptive motivational links and behavioral nodes. Conceptualizing addiction as pathological alteration of scale-free motivational-behavioral repertoires unifies neurobiological, neurocomputational and behavioral research while addressing addiction vulnerability in adolescence and psychiatric illness. This model may inform integrative research in defining more effective prevention and treatment strategies for addiction.

Ethanol sensitization in a neurodevelopmental lesion model of Schizophrenia in rats

Substance use disorder comorbidity in schizophrenia may reflect dysfunctional cortical-striatal-limbic circuitry commonly involved in the addiction process and the pathogenesis of schizophrenia. Rats with neonatal ventral hippocampal lesions (NVHL) demonstrate post-adolescent onset of schizophrenia-like symptoms and increased addiction vulnerability in paradigms using cocaine in adulthood. Here, we investigated response profiles of young adult NVHL vs. SHAM rats to ethanol, an addictive drug with many psychopharmacological effects divergent from those of cocaine, in a locomotor sensitization paradigm. Over 15 days of daily injections of saline, low (0.15 g/kg) or high (1.0 g/kg) doses of ethanol, NVHL rats showed stimulatory effects at the low dose compared to saline and high-dose conditions, while SHAM rats showed expected patterns of dose-dependent suppression of locomotor activity. In a challenge session 2 weeks later in which a moderate dose (0.25 g/kg) of ethanol was given to all subjects, NVHL rats with history of prior ethanol exposure showed greater locomotor activity consistent with installment of alcohol-induced sensitization not present in SHAMs. These findings provide further evidence of enhanced short- and long-term responsivity to abused drugs in a neurodevelopmental model of schizophrenia, and may reflect potentiation of common mechanisms of addiction shared between pharmacologically diverse addictive drugs.

Accentuated behavioral sensitization to nicotine in the neonatal ventral hippocampal lesion model of schizophrenia

The prevalence of smoking in schizophrenia patients far exceeds that in the general population. Increased vulnerability to nicotine and other drug addictions in schizophrenia may reflect the impact of developmental limbic abnormalities on cortical-striatal mediation of behavioral changes associated with drug use. Rats with neonatal ventral hippocampal lesions (NVHLs), a neurodevelopmental model of schizophrenia, have previously been shown to exhibit altered patterns of behavioral sensitization to both cocaine and ethanol. This study explored nicotine sensitization in NVHLs by testing locomotor activity of NVHL vs. SHAM-operated controls over 3 weeks in response to nicotine (0.5 mg/kg) or saline injections (s.c.) followed by a nicotine challenge delivered to all rats 2 weeks later. At the beginning of the initial injection series, post-injection locomotor activation was indistinguishable among all treatment groups. However, nicotine but not saline injections produced a progressive sensitization effect that was greater in NVHLs compared to SHAMs. In the challenge session, rats with previous nicotine history showed enhanced locomotor activation to nicotine when compared to drug naïve rats, with NVHL-nicotine rats showing the greatest degree of activity overall. These results demonstrate that NVHLs exhibit altered short- and long-term sensitization profiles to nicotine, similar to altered long-term sensitization profiles produced by cocaine and ethanol. Collectively, these findings suggest the neurodevelopmental underpinnings of schizophrenia produce enhanced behavioral sensitization to addictive drugs as an involuntary and progressive neurobehavioral process, independent of the acute psychoactive properties uniquely attributed to nicotine, cocaine, or alcohol.

GABAergic modulation of the 40 Hz auditory steady-state response in a rat model of schizophrenia

Auditory steady-state auditory responses (ASSRs), in which the evoked potential entrains to stimulus frequency and phase, are reduced in magnitude in patients with schizophrenia, particularly at 40 Hz. While the neural mechanisms responsible for ASSR generation and its perturbation in schizophrenia are unknown, it has been hypothesized that the GABAA receptor subtype may have an important role. Using an established rat model of schizophrenia, the neonatal ventral hippocampal lesion (NVHL) model, 40-Hz ASSRs were elicited from NVHL and sham rats to determine if NVHL rats show deficits comparable to schizophrenia, and to examine the role of GABAA receptors in ASSR generation. ASSR parameters were found to be stable across time in both NVHL and sham rats. Manipulation of the GABAA receptor by muscimol, a GABAA agonist, yielded a strong lesion x drug interaction, with ASSR magnitude and synchronization decreased in NVHL and increased in sham rats. The lesion x muscimol interaction was blocked by a GABAA receptor antagonist when given prior to muscimol administration, confirming the observed interaction was GABAA mediated. Together, these data suggest an alteration involving GABAA receptor function, and hence inhibitory transmission, in the neuronal networks responsible for ASSR generation in NVHL rats. These findings are consistent with prior evidence for alterations in GABA neurotransmitter systems in the NVHL model and suggest the utility of this animal modelling approach for exploring neurobiological mechanisms that generate or modulate ASSRs.

Cortical-striatal integration of cocaine history and prefrontal dysfunction in animal modeling of dual diagnosis.

BACKGROUND High rates of substance disorders in schizophrenia and other mental illnesses may reflect biological vulnerabilities to the addiction process. Interactions between addictive drug effects and mental illness involving circuits that generate motivated behavior may underpin this vulnerability. METHODS We examined separate and combined effects of neonatal ventral hippocampal lesions (NVHLs)-a neurodevelopmental model of schizophrenia (vs. SHAM-operated control animals)--and a behaviorally sensitizing cocaine history (15 mg/kg/day x 5 days vs. saline injections) on acute cocaine-induced neural activation signaled by c-Fos expression. Stereological assessment of activation densities spanned six ventral to dorsal cortical-striatal compartments. RESULTS Cortically, NVHLs showed hypoactivation and decreased volume of the ventral medial prefrontal cortex. In contrast, cocaine history was only expressed subcortically and as a hyperactivating effect in the dorsal striatum where significant NVHL-induced hyperactivation also emerged. Across all subjects and brain regions, only dorsal striatal activation was correlated with differences in sensitized locomotion. However, this activation was tightly correlated to a simple multiplicative function of ventral medial prefrontal hypoactivation and cocaine history-related increases in striatal activation. CONCLUSIONS These findings suggest drug history and developmental temporal limbic abnormalities associated with prefrontal dysfunction produce compounding effects within cortical-striatal circuits as mechanistic basis for dual diagnosis.

Natural reward-related learning in rats with neonatal ventral hippocampal lesions and prior cocaine exposure

RationalPsychostimulant injections in rats have been shown to alter future performance in natural reward conditioning. These effects may represent a persistent impact of drugs on neurocircuits that interface cognitive and motivational processes, which may be further altered in neuropsychiatric conditions that entail increased addiction vulnerability.ObjectiveThis study investigated whether a rat model of schizophrenia with cocaine addiction vulnerability shows altered natural reward conditioning with or without prior cocaine exposure.MethodsAdult rats with SHAM or neonatal ventral hippocampal lesions were given cocaine (15 mg/kg per day for 5 days) or saline injections, followed 7 days later by natural reward-conditioned learning. Over ten daily sessions, water-restricted rats were assessed for durations of head entries into a magazine during random water presentations, a conditioning stimulus phase predictive of the water reward, and an “inappropriate” phase when conditioning stimuli were absent and reward presentation would be delayed.ResultsOver repeated sessions, lesioned and SHAM rats showed similar reductions in total magazine entry durations, with similar increases in the allocations of entry times during the water presentation. However, lesioned rats, especially those exposed to cocaine, demonstrated reduced allocations of magazine entry times during the conditioning stimulus phase, and increased allocations during the inappropriate phase.ConclusionsIntact natural reward motivation accompanied by deficient learning of complex contingencies to guide efficient reward approach may represent a form of impulsivity as an addiction vulnerability trait marker in an animal model of schizophrenia.