Anatomie fonctionnelle des voies corticothalamiques du chat

Huppé-Gourgues, Frédéric

January 2006

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

Chat

Corticothalamique

Terminaux

Thalamus

Cortex

Microscopie photonique

Microscopie électronique

Reconstruction d'axone

DEVELOPMENTAL REMODELING OF RELAY CELLS IN THE DORSAL LATERAL GENICULATE NUCLEUS (dLGN) OF THE MOUSE AND THE ROLE OF RETINAL INNERVATION

El-Danaf, Rana

07 September 2011

The dorsal lateral geniculate nucleus (dLGN) has become an important model for studying many aspects of visual system development. To date, studies have focused on the development of retinal projections and the role of activity in shaping the pattern of synaptic connections made with thalamocortical relay cells. By contrast, little is known about relay cells and the factors that regulate the growth and establishment of their dendritic architecture. In many systems, such growth seems consistent with the synaptotrophic hypothesis which states that synapse formation and dendritic growth work in a concerted fashion such that afferent input and the establishment of functional synapses are needed to shape the maturation of dendritic arbors. To address this, we characterized the development of relay cells in the dLGN of wild-type (WT) mouse. By adopting a loss of function approach, we assessed the manner in which growth and maturation of relay cells were affected by retinal innervation. For this, we made use of the math-null (math5-/-) mouse in which progenitors fail to differentiate into retinal ganglion cells (RGCs), and exhibit a >95% cell loss. Anterograde labeling of RGC axons with cholera toxin subunit B (CTB), immunolabeling of RGC-specific presynaptic machinery in dLGN (e.g. vesicular glutamate transporter 2), and ultrastructural analysis at the electron microscopy level demonstrated that the dLGN is devoid of retinal innervation. We examined the functional and morphological characteristics of relay cells in WT and math5-nulls during early postnatal life by conducting in vitro whole cell recordings in slices containing dLGN. Individual relay cells were labeled by intracellular injection of biocytin, and imaged by confocal microscopy to obtain the 3-D reconstructions of their dendritic trees. Morphometric analysis revealed that relay cells in WT undergo two growth spurts: an early one where cell class specification and dendritic complexity are established and a later one marked by an increase in dendritic field and length. Following the third week, relay cells growth was stabilized. In math5-nulls, relay cells maintained their morphological identity whereby cells could be classified in three groups (Y: spherical, X: bi-conical, W: hemi-spherical). However, the dLGN was highly reduced in size, and relay cells showed disrupted growth spurts. Relay cells had smaller somata and exhibited fluctuations in dendritic complexity and field extent compared to age-matched WTs. Exuberance in dendritic branching was noted in week 2, and by week 5, relay cells had significantly smaller surface area resulting from a loss of dendritic segments and a reduction in dendritic field extent. Control experiments using RT-PCR revealed that these changes were not due to the loss of math5 in the dLGN. Whole cell recordings and voltage responses to square wave current pulses showed that math5-nulls possess the full compliment of intrinsic membrane properties, such as relay cells displayed both burst and tonic firing modes. A cross of the math5-null with a transgenic mouse that expresses GFP in layer VI cortical neurons revealed a dense plexus of corticogeniculate terminals throughout the mature dLGN. However, the rate of corticogeniculate innervation was highly accelerated and was complete a week earlier than WT. Electric stimulation of cortical axons revealed that synapses are functional and responses were indistinguishable from WT. Taken altogether, these observations suggest that retinal innervation plays an important trophic role in the maturation of dLGN and is necessary for the continued maintenance of relay cells’ structural integrity. However, the general form and function of relay cells seem largely unaffected by the loss of retinal innervation.

dLGN

thalamus

retinogeniculate

relay cells

Medical Sciences

Medicine and Health Sciences

Neurosciences

Behavioural examination of the role of the thalamic reticular nucleus in attention

Stanislaus-Carter, Rudi

January 2017

The ability to selectively attend to aspects of the environment which signal opportunity or danger, while marginalising irrelevant stimuli is critical to an animal's survival. With finite cognitive resources, the brain must dedicate resources to only those stimuli that are biologically significant. Incoming thalamic information must therefore be filtered. The thalamic reticular nucleus has long been considered critically involved in modulating thalamic sensory processing. Sharing connections with both the thalamus and cortex, it is ideally located to modulate the transfer of pertinent incoming sensory information. This thesis sought to determine the functional role of the thalamic reticular nucleus in attentional processes by combining lesion techniques and well established behavioural paradigms. Chapter 3 examined the role of visual thalamic reticular nucleus lesions on performance in a two-alternative forced choice reaction time task when auditory distractors were presented. No effect of the lesion was found. Chapter 4 examined excitotoxic lesions of thalamic retlcular nucleus on performance in the 7-stage attentional set shifting task. No effect of lesion on performance was found. Chapter 5 examined mediodorsal thalamus and rostral thalamic reticular nucleus lesions on performance in the attentional set shifting task. Despite strong connectivity with prefrontal regions known to be involved in this task, there was no effect of either lesion. Finally, chapter 6 examined the effects of reducing dopamine input into the thalamic reticular nucleus on a two alternative forced choice reaction time task. Following bilateral lesions the animals were impaired in the re-orientation of attention – suggesting a critical role for both the thalamic reticular nucleus and dopamine in attentional processes. Taken together, these results suggest that while the thalamic reticular nucleus is involved in attention, it is not involved in every aspect.

Stimulations du cervelet pour le traitement des dyskinésies induites par la lévodopa dans la maladie de Parkinson / Stimulations of the cerebellum for the treatment of levodopa-induced dyskinesias in Parkinson's disease

Bousquet Combes, Adèle

07 June 2017

La lévodopa est actuellement la thérapie de référence pour les patients atteints de la maladie de Parkinson et permet le rétablissement artificiel des niveaux de dopamine. Cependant, ce traitement s'accompagne de mouvements involontaires anormaux invalidants, ou dyskinésies. Au cours de ma thèse, j'ai étudié l'implication des cellules de Purkinje de la région cérébelleuses crus II, via les voies cérébello-thalamo-cortico-striatale et cérébello-thalamo-striatale, dans l'émergence et le traitement des mouvements involontaires anormaux oro-linguaux induits par la lévodopa dans un modèle murin de la maladie de Parkinson. Mes résultats suggèrent que la stimulation chronique et spécifique des cellules de Purkinje par une technique d'optogénétique semble à même de corriger et de prévenir le phénotype dyskinétique et ce en association avec une modulation de l'activité du noyau thalamique intralaminaire parafasciculaire, du cortex moteur primaire oral et du striatum dorsal. Les voies cérébello-thalamo-cortico-striatale et cérébello-thalamo-striatale semblent ainsi impliquées dans le traitement correctif et préventif des dyskinésies induites par la lévodopa dans la maladie de Parkinson. / Levodopa is currently the gold standard treatment for Parkinson’s disease patients and artificially restores dopamine levels. However, it induces debilitating abnormal involuntary movements, or dyskinesia. During my thesis, I assessed the involvement of the cerebellar crus II region Purkinje cells, via the cerebello-thalamo-cortico-striatal and cerebello-thalamo-striatal pathways, in the onset and the treatment of levodopa induced oro-lingual abnormal involuntary movements, in a mouse model of Parkinson’s disease. My results suggest that the chronic and specific stimulation of Purkinje cells, using optogenetics, seems able to correct and prevent the dyskinetic phenotype, together with modulations of the activity of the parafascicular intralaminar thalamic nucleus, primary oral motor cortex and dorsal striatum, thus arguing for the involvement of the cerebello-thalamo-cortico-striatal and the cerebello-thalamo-striatal pathways in the corrective and preventive treatment for levodopa induced dyskinesia in Parkinson’s disease.

Dyskinésies

Parkinson

Cervelet

Optogénétique

Thalamus

Cortex moteur

Dyskinesia

Parkinson

Motor cortex

620.5

616.83

Mean-field analysis of basal ganglia and thalamocortical dynamics

van Albada, Sacha Jennifer

January 2009

PhD / When modeling a system as complex as the brain, considerable simplifications are inevitable. The nature of these simplifications depends on the available experimental evidence, and the desired form of model predictions. A focus on the former often inspires models of networks of individual neurons, since properties of single cells are more easily measured than those of entire populations. However, if the goal is to describe the processes responsible for the electroencephalogram (EEG), such models can become unmanageable due to the large numbers of neurons involved. Mean-field models in which assemblies of neurons are represented by their average properties allow activity underlying the EEG to be captured in a tractable manner. The starting point of the results presented here is a recent physiologically-based mean-field model of the corticothalamic system, which includes populations of excitatory and inhibitory cortical neurons, and an excitatory population representing the thalamic relay nuclei, reciprocally connected with the cortex and the inhibitory thalamic reticular nucleus. The average firing rates of these populations depend nonlinearly on their membrane potentials, which are determined by afferent inputs after axonal propagation and dendritic and synaptic delays. It has been found that neuronal activity spreads in an approximately wavelike fashion across the cortex, which is modeled as a two-dimensional surface. On the basis of the literature, the EEG signal is assumed to be roughly proportional to the activity of cortical excitatory neurons, allowing physiological parameters to be extracted by inverse modeling of empirical EEG spectra. One objective of the present work is to characterize the statistical distributions of fitted model parameters in the healthy population. Variability of model parameters within and between individuals is assessed over time scales of minutes to more than a year, and compared with the variability of classical quantitative EEG (qEEG) parameters. These parameters are generally not normally distributed, and transformations toward the normal distribution are often used to facilitate statistical analysis. However, no single optimal transformation exists to render data distributions approximately normal. A uniformly applicable solution that not only yields data following the normal distribution as closely as possible, but also increases test-retest reliability, is described in Chapter 2. Specialized versions of this transformation have been known for some time in the statistical literature, but it has not previously found its way to the empirical sciences. Chapter 3 contains the study of intra-individual and inter-individual variability in model parameters, also providing a comparison of test-retest reliability with that of commonly used EEG spectral measures such as band powers and the frequency of the alpha peak. It is found that the combined model parameters provide a reliable characterization of an individual's EEG spectrum, where some parameters are more informative than others. Classical quantitative EEG measures are found to be somewhat more reproducible than model parameters. However, the latter have the advantage of providing direct connections with the underlying physiology. In addition, model parameters are complementary to classical measures in that they capture more information about spectral structure. Another conclusion from this work was that a few minutes of alert eyes-closed EEG already contain most of the individual variability likely to occur in this state on the scale of years. In Chapter 4, age trends in model parameters are investigated for a large sample of healthy subjects aged 6-86 years. Sex differences in parameter distributions and trends are considered in three age ranges, and related to the relevant literature. We also look at changes in inter-individual variance across age, and find that subjects are in many respects maximally different around adolescence. This study forms the basis for prospective comparisons with age trends in evoked response potentials (ERPs) and alpha peak morphology, besides providing a standard for the assessment of clinical data. It is the first study to report physiologically-based parameters for such a large sample of EEG data. The second main thrust of this work is toward incorporating the thalamocortical system and the basal ganglia in a unified framework. The basal ganglia are a group of gray matter structures reciprocally connected with the thalamus and cortex, both significantly influencing, and influenced by, their activity. Abnormalities in the basal ganglia are associated with various disorders, including schizophrenia, Huntington's disease, and Parkinson's disease. A model of the basal ganglia-thalamocortical system is presented in Chapter 5, and used to investigate changes in average firing rates often measured in parkinsonian patients and animal models of Parkinson's disease. Modeling results support the hypothesis that two pathways through the basal ganglia (the so-called direct and indirect pathways) are differentially affected by the dopamine depletion that is the hallmark of Parkinson's disease. However, alterations in other components of the system are also suggested by matching model predictions to experimental data. The dynamics of the model are explored in detail in Chapter 6. Electrophysiological aspects of Parkinson's disease include frequency reduction of the alpha peak, increased relative power at lower frequencies, and abnormal synchronized fluctuations in firing rates. It is shown that the same parameter variations that reproduce realistic changes in mean firing rates can also account for EEG frequency reduction by increasing the strength of the indirect pathway, which exerts an inhibitory effect on the cortex. Furthermore, even more strongly connected subcircuits in the indirect pathway can sustain limit cycle oscillations around 5 Hz, in accord with oscillations at this frequency often observed in tremulous patients. Additionally, oscillations around 20 Hz that are normally present in corticothalamic circuits can spread to the basal ganglia when both corticothalamic and indirect circuits have large gains. The model also accounts for changes in the responsiveness of the components of the basal ganglia-thalamocortical system, and increased synchronization upon dopamine depletion, which plausibly reflect the loss of specificity of neuronal signaling pathways in the parkinsonian basal ganglia. Thus, a parsimonious explanation is provided for many electrophysiological correlates of Parkinson's disease using a single set of parameter changes with respect to the healthy state. Overall, we conclude that mean-field models of brain electrophysiology possess a versatility that allows them to be usefully applied in a variety of scenarios. Such models allow information about underlying physiology to be extracted from the experimental EEG, complementing traditional measures that may be more statistically robust but do not provide a direct link with physiology. Furthermore, there is ample opportunity for future developments, extending the basic model to encompass different neuronal systems, connections, and mechanisms. The basal ganglia are an important addition, not only leading to unified explanations for many hitherto disparate phenomena, but also contributing to the validation of this form of modeling.

mean-field modeling

basal ganglia

Parkinson's disease

aging

EEG

thalamus

cortex

transformation

normal distribution

REPRESENTATIONS DE SCENES TACTILES COMPLEXES DANS LA BOUCLE THALAMO-CORTICALE DU SYSTEME VIBRISSAL

Le Cam, Julie

23 September 2010

Lors de l'exploration tactile chez les rongeurs, les mouvements oscillatoires des vibrisses faciales permettent à l'animal d'explorer les objets afin de déterminer leur position, leur forme et leur texture. Dans ces situations naturelles, l'animal est donc confronté à des patterns spatio-temporels complexes des mouvements des vibrisses. Notre hypothèse est que la réponse neuronale corticale étant contextuelle, elle différera selon que les stimuli font partie d'une séquence complexe dans le temps et l'espace ou qu'ils soient présentés isolément. Mon travail de thèse, réalisé à l'UNIC (CNRS, Gif sur Yvette) sous la direction de Daniel Shulz, propose de caractériser les réponses neuronales du système vibrissal à différents niveau de la voie afférente, et leur modulation par le contexte spatio-temporel du stimulus. Afin de générer des stimuli complexes, nous avons développé un nouvel outil de stimulation tactile basé sur une technologie piezo-électrique permettant de générer des stimulations contrôlées et indépendantes de 24 macro-vibrisses sur la face du rat. Cet outil nous a permis d'étudier les propriétés fonctionnelles des champs récepteurs dans le cortex à tonneaux. En plus de la mise en évidence de champs récepteurs multi-vibrissaux dans les différentes couches corticales, une modulation de la structure spatiale du champ récepteur par la direction de déflexion des vibrisses a été observée. Par la suite, nous avons montré que les réponses corticales sont modulées par le contexte sensoriel. En effet, les neurones corticaux présentent une sélectivité à la direction pour un mouvement global impliquant l'ensemble des vibrisses qui est indépendante de la sélectivité locale. Cette sélectivité ne peut être expliquée par des interactions linéaires simples ou par des interactions suppressives non-linéaires d'ordre deux. Des interactions non-linéaires d'ordre supérieur impliquant une intégration de l'ensemble des inputs sous- et supraliminaires de la cellule sous-tendraient la sélectivité au mouvement global du stimulus. Le noyau Ventro-Postéro-Médian thalamique (VPM), principale source des afférences au cortex, intègre déjà une information multi-vibrissale. Nous avons donc émis l'hypothèse d'une contribution des mécanismes sous-corticaux dans l'intégration multi-vibrissale corticale. En effet, notre étude a révélé que les neurones du VPM sont sélectifs au mouvement global des vibrisses cependant en plus faible proportion que dans le cortex. Ce résultat suggère que la sélectivité puisse émerger au niveau de la boucle thalamo-corticale et soit amplifiée dans le cortex par des connexions intra-corticales. Afin de tester cette hypothèse, nous avons étudié l'impact de l'inactivation de la couche VI corticale, sources de la voie cortico-thalamique, sur la sélectivité globale du VPM. Dans ces conditions d'inactivation corticale, nous avons observé une diminution de la sélectivité thalamique. Malgré la description canonique de ce système, associant une vibrisse à un tonneau cortical, et une structure très discrétisée, nous avons montré des réponses du système à des propriétés émergeantes du stimulus nécessitant une intégration multi-vibrissale. Cette intégration est réalisée de manière dynamique par l'action conjointe de la boucle thalamocortico-thalamique et de la connectivité cortico-corticale.

cortex à tonneaux

vibrisses

thalamus

boucle thalamo-cortical

Distribution of FABP7 in Neural Tissue of Socially Defeated Adult Anolis Carolinensis

Cañete, Carmenada L.

06 May 2012

Due to its significance in many cellular functions, fatty acid binding protein 7 (FABP7) has become a rising topic of interest for many scientists. Immunocytochemistry was used to map the distribution of FABP7 and test whether the amount of FABP7 immunoreactivity (FABP7-IR) differed in animals that were defeated in a fight, as compared to control animals that did not engage in any social interaction. The male green anole was used as the subject because its natural tendency to establish social classes within its species provides an ideal model to observe for variation in FABP7-IR. The results showed FABP7-IR in cells and fibers of the cortex, hypothalamus, thalamus, medial preoptic area, dorsoventricular ridge, amygdala, suprachiasmatic nucleus, nucleus accumbens, nucleus rotundus, habenular area, tectum, dorsal noradrenergic and lateral forebrain bundles, and lining the third and lateral ventricles. Qualitative observation suggested higher FABP7 levels in socially defeated males than controls in all areas.

Fatty acid binding protein 7

Anolis carolinensis

Subordinate

Immunocytochemistry

Dorsomedial thalamus

Medial cortex

Region-selective effects of thiamine deficiency on cerebral metabolism in pyrithiamine-treated rats

Navarro, Darren.

January 2008

Pyrithiamine-induced thiamine deficiency in rats is a well-established animal model of Wernicke's Encephalopathy (WE). This thesis project, submitted as four articles, presents an examination of metabolic events that contribute to the selective neuronal lesions observed in the medial thalamus (MT) of thiamine-deficient (TD) rat. In addition, the phenomenon of glucose-precipitated worsening of neurological status in WE patients (Wallis et al., 1978; Watson et al., 1981) is explored. / Lactate accumulation is known to occur selectively in regions of the TD brain, which ultimately express neuronal cell death (McCandless, 1982; Munujos et al., 1996). In Article 1, the metabolic origin and cellular localization of region-selective lactate accumulation in the MT of TD rats was studied using combined 1H and 13C nuclear magnetic resonance (NMR) spectroscopy. Parallel studies were performed to examine the effects of glucose loading on regional brain lactate synthesis in TD animals. Thiamine deficiency caused focal increases in the de novo synthesis of lactate via elevated glycolytic flux in the MT, while contribution via pyruvate recycling and the periphery remained nominal. Lactate levels remained unaltered in the frontal cortex (FC), a brain region that is spared in thiamine deficiency. Administration of a glucose load intensified the selective increases in lactate de novo synthesis and accumulation in the MT of TD rats, positing a role for lactic acidosis in the glucose-precipitated worsening of neurological status in TD patients. Accordingly, Article 2 addresses the effect of glucose loading on local cerebral pH in the vulnerable MT, compared to the FC, of TD rats. Administration of a glucose load resulted in detrimental decreases in regional pH selectively in the MT, implying that alterations of brain pH contribute to the pathogenesis of thalamic neuronal damage and consequent cerebral dysfunction in WE. / Region-specific alterations in the steady state levels of cerebral amino acid neurotransmitters have been well-documented in experimental animal models of thiamine deficiency (Butterworth et al., 1979; Butterworth & Heroux, 1989; Gaitonde et al., 1975; Plaitakis et al., 1979); however, the dynamics of these changes have never been systematically explored. In Article 3, we examined the metabolic fluxes through thiamine-dependent pyruvate dehydrogenase (PDH) and alpha-ketoglutarate dehydrogenase (alpha-KGDH) using multinuclear NMR spectroscopy. Furthermore the cellular localization of the metabolic changes in relation to regional vulnerability to thiamine deficiency was addressed. Our studies clearly demonstrate that early decreases m metabolic flux through alpha-KGDH result in commensurate declines in aspartate concentrations in the MT of TD rats. Impairments to PDH flux manifest secondarily to the metabolic block at alpha-KGDH, likely due to depleted oxaloacetate pools. As a result of impaired pyruvate oxidation, declines in the de novo synthesis of glutamate and GABA ensue. The present findings also suggest that inhibition of flux through alpha-KGDH in TD brain occurs primarily in the neurons, while astrocytes possess compensatory mechanisms, i.e. the anaplerotic pathway, to replenish oxaloacetate concentrations via metabolic pathways that do not involve thiamine-dependent enzymes. / In Article 4, we investigated the regional effects of thiamine deficiency on the activity of thiamine-dependent branched-chain alpha-ketoacid dehydrogenase (BCKDH) and the resultant effects on regional cerebral branched-chain amino acid (BCAA) oxidation. Thiamine deficiency resulted in significant impairments in BCKDH activity; while parallel studies on enzyme distribution confirmed a lower oxidative capacity for BCAAs in the MT compared with the Fe. / The data presented in these four articles confirm and extend findings for the region-selective impairments in thiamine-dependent metabolic processes as the foundation of vulnerability of the MT to thiamine deficiency. In addition, glucose loading of TD rats exacerbates both lactic acidosis and impaired pyruvate oxidation in this vulnerable brain region, positing a role for these processes in the glucose-precipitated worsening of neurological status in TD patients. Impaired oxidative metabolism of glucose and BCAAs in the MT leads to the accumulation of potentially harmful metabolic intermediates, contributing to the mitochondrial dysfunction, cellular energy failure and ultimately neuronal cell death observed in thiamine deficiency.

Thalamus -- metabolism.

Frontal Lobe -- metabolism.

Thiamine Deficiency -- metabolism.

Ketone Oxidoreductases -- metabolism.

Rats.

Rats, Sprague-Dawley.

Retrograde signalling within fear neurocircuitry: Nitric oxide signalling from the lateral nucleus of the amygdala regulates thalamic EGR-1 mediated alterations of presynaptic protein levels during auditory fear conditioning

Overeem, Kathie

January 2009

Previous research has shown that nitric oxide signalling in the lateral nucleus of the amygdala is required for the consolidation of Pavlovian conditioned fear. Given the evidence that nitric oxide can act as a retrograde signalling molecule in in vitro models of memory consolidation the question arises whether this is also occurring within behavioural memory models? Using auditory fear conditioning this research shows that nitric oxide does indeed act as retrograde signalling molecule in the fear system. Its synthesis in the lateral nucleus of the amygdala regulates conditioning induced expression of the immediate early gene early growth response gene 1 (EGR-1) in cells of the auditory thalamus that project to the lateral nucleus of the amygdala. The regulation of EGR-1 expression by the lateral nucleus of the amygdala was proven to be dependent on amygdala-based cellular excitation, nitric oxide synthesis and NR2B-NMDA receptor activation but not ERK/MAPK activity. Using an EGR-1 antisense oligonucleotide to prevent training induced EGR-1 expressions in the auditory thalamus it was shown that this gene upregulation is necessary for the consolidation of conditioned fear. Finally, inhibition of EGR-1 upregulation in the auditory thalamus was proven to impair conditioning induced increases in the presynaptic proteins synaptophysin, and synapsin II and II back in the lateral nucleus of the amygdala. Overall, the results of this dissertation have shown that nitric oxide acts as a retrograde messenger in a mammalian memory system by modulating gene expression in presynaptic cells. This modulation of gene expression serves to increase levels of presynaptic proteins back at the origin of nitric oxide synthesis. This supports the long standing doctrine that nitric oxide acts as a retrograde signalling molecule to coordinate presynaptic changes associated with memory formation.

Nitric Oxide

Amygdala

Retrograde Signalling

Auditory Thalamus

Fear

Memory

EGR-1

Anterior and lateral thalamic lesions in object-odour paired associate learning

Bell, Rati

January 2007

Diencephalic amnesia is thought to be the result of damage to a single thalamic structure that is responsible for the memory impairment. However, an alternative view is that different thalamic structures contribute to the memory impairment in subtly different ways. Paired-associate learning is one important measure of learning and memory that is highly sensitive to disruption in people with amnesia or dementia. The current study will investigate the influence of lesions to two thalamic subregions, the anterior thalamic nuclei (AT) and the lateral thalamic nuclei (LT) in an object-odour paired associate learning task. Each of these subregions has been suggested by the literature as critical for amnesia after thalamus injury. The current study does not involve a place/ space component. Both AT and LT lesions caused impairments in the object-odour paired associate task, but not in the simple discrimination tasks. The results of this study provide new evidence to suggest that the anterior thalamic region may be responsible for more than spatial memory processing. This result is inconsistent with those of Aggleton & Brown (1999) that consider the AT to be part of an 'extended hippocampal system'. The deficits observed from LT lesions in this study provide new insight into the lateral thalamic region's role in pattern processing.

Diencephalic amnesia

memory

thalamus

anterior thalamic nuclei

lateral thalamic nuclei

paired-associate learning