79 research outputs found
La maturation fonctionnelle de l’hippocampe postnatal chez le rongeur : approche électrophysiologique
Les réseaux neuronaux, pendant leur période de développement, génèrent des patrons d’activité immatures qui sont supposés participer à la formation des circuits neuronaux. Ces activités synchronisées créent des conditions favorables pour la plasticité hebbienne qui soutient la formation des circuits locaux. Les travaux menés notamment sur les systèmes sensoriels ont montré que les circuits pauci-neuronaux locaux sont capables de présenter une activité synchrone tout en étant isolés du reste des structures cérébrales. La moelle épinière isolée produit des bursts qui sont à l’origine des secousses musculaires, la rétine insensible à la lumière génère des ondes d’activité, d’autres régions cérébrales génèrent des activités synchrones avant de remplir la fonction à laquelle ils sont destinés. De manière similaire, l’hippocampe du rat nouveau-né ou primate prématuré in vitro, ainsi que les néocortex immature in vitro, génèrent une activité neuronale synchronisée, appelée giant depolarising potentials (GDPs). En se basant uniquement sur ces études et en prenant en compte la maturation tardive de certaines projections neuronales à distance, il serait tentant de conclure que le cerveau immature fonctionne comme un ensemble de petits modules fonctionnels qui auto-entretiennent leur activité intrinsèque avant de se connecter entre eux pour créer un cerveau fonctionnel adulte. Cependant, certaines connexions à longue distance sont formées très tôt pendant le développement et permettent la propagation des oscillations immatures entre les structures connectées. En effet, les ondes rétinales se propagent au noyau géniculé latéral et ensuite jusqu’au cortex visuel ; les GDPs hippocampiques se propagent à l’hippocampe controlatéral, septum et cortex entorhinal et finalement, les secousses musculaires, en créant un feed-back sensoriel, déclenchent des oscillations gamma immatures ainsi que les spindle bursts dans le réseau thalamo-cortical. Un fonctionnement similaire est décrit chez le nouveau-né prématuré. Il paraît donc plus probable, que le cerveau soit, dès les stades précoces du développement, organisé en sous-systèmes fonctionnels reliés entre eux anatomiquement et fonctionnellement. Au sein des unités fonctionnelles sont générés des patrons d’activité immatures synchrones afin de créer des connexions organisées topographiquement qui serviront de base anatomique de la fonction finale. Si ces étapes développementales sont perturbées pendant les périodes critiques, le système ne pourra pas assurer sa fonction de manière adéquate au stade mature. L’hippocampe mature, ou plus exactement les circuits cortico-hippocampiques, jouant un rôle primordial dans la mémoire déclarative, l’orientation spatiale et l’inhibition du comportement. L’établissement de ces fonctions est progressif au cours du développement. Par exemple les adultes humains n’ont que rarement des souvenirs personnels datant avant l’âge de trois ans. Or, nous savons aujourd'hui que le bébé humain est capable de garder des souvenirs dans la mémoire déclarative (dépendante de l’hippocampe) au cours de la première année de vie avec une efficacité croissante, mais il ne se rappellera pas ces souvenirs à l’âge adulte (Bauer, 2006). Nous ne savons pas s’il s’agit d’un encodage différent d’emblée ou d’un processus secondaire supprimant l’accès à ces souvenirs précoces. Nous pouvons présumer qu’il existe des modifications des activités électrophysiologiques pendant le développement qui soutiennent la modification de ces fonctions. Au cours de ce travail de thèse, nous voulions savoir comment et à partir de quand l’hippocampe, qui reçoit des informations convergentes de nombreuses régions néocorticales, acquiert son mode de fonctionnement adulte. Afin de répondre à cette question nous avons étudié le système cortex entorhinal – hippocampe, le cortex entorhinal étant la principale entrée excitatrice de l’hippocampe et recevant des afférences de nombreuses régions du néocortex. (...)Neuronal networks spontaneously generate “immature” patterns of activity during development, which are thought to participate on the formation of neural circuits. Local neocortical as well as hippocampal circuits generate synchronised neuronal discharges providing support for Hebbian plasticity. Studies of sensory systems showed that local pauci-neuronal circuits were able to generate synchronous activity while isolated from other brain structures. Isolated spinal cord produces bursts evoking muscle twitching, light insensitive retina generates waves of activity, as well as other brain regions generate synchronous activities before fulfilling the function for which they are intended. Similarly, the hippocampus of newborn rat or premature primate in vitro, as well as immature neocortex in vitro, generates synchronised neuronal activity called giant depolarising potentials (GDPs). Based solely on these studies and taking into account the delayed maturation of certain long-distance neuronal projections, it would be tempting to conclude that the immature brain functions as a set of small functional modules that self-maintain their intrinsic activity before connecting together to create a functional adult brain. However, some long-distance connections are formed very early during development and allow the propagation of oscillations between immature connected structures. Indeed, retinal waves propagate to the lateral geniculate nucleus and then to the visual cortex, hippocampal GDPs propagate to the contralateral hippocampus, septum and entorhinal cortex, and finally, twitching, creating a sensory feedback, triggers immature gamma oscillations and spindle bursts in the thalamo-cortical network. A similar functioning is described in the premature newborn. It therefore seems more likely that the brain is, during the early stages of development, organised into functional subsystems interconnected anatomically and functionally. Within functional units are generated immature patterns of synchronous activity to create topographically organised connections that serve as anatomical basis of the final function. If these developmental stages are disturbed during critical periods, the system cannot perform its function adequately in mature stage. The mature hippocampus, or more precisely the cortico-hippocampal circuits, plays a key role in declarative memory, spatial organisation and behavioural inhibition. The establishment of these functions is progressive during development. For example, human adults rarely have personal memories dating before the age of three years. However, we now know that the human baby is able to keep memories in declarative memory (hippocampus-dependent) during the first year of life with increasing efficiency, but will not remember them in the adulthood. We do not know if the encoding of the memories is different or a secondary process inhibits the access to the early memories. We can assume that changes in electrophysiological activity during development support modification of these functions. In this thesis, we wanted to know how and from when the hippocampus, which receives convergent information from many cortical areas, acquires his adult mode of functioning. To answer this question we studied the entorhinal cortex-hippocampus system, entorhinal cortex being the main excitatory input to the hippocampus and receiving afferents from many parts of the neocortex. We were able to distinguish several periods in the development of the immature hippocampus: Period from P1 till P12 characterised by the sole presence of immature sharp waves triggered by the entorhinal cortex. Period from P13, when two types of sharp waves coexisted: the immature sharp waves and sharp waves as described in the adult animals newly emerged. The mature sharp waves, unlike the immature, can be accompanied by ripples. (...
Neuronal Activity Patterns in the Developing Barrel Cortex
International audienceThe developing barrel cortex reveals a rich repertoire of neuronal activity patterns, which have been also found in other sensory neocortical areas and in other species including the somatosensory cortex of preterm human infants. The earliest stage is characterized by asyn-chronous, sparse single-cell firing at low frequencies. During the second stage neurons show correlated firing, which is initially mediated by electrical synapses and subsequently transforms into network bursts depending on chemical synapses. Activity patterns during this second stage are synchronous plateau assemblies, delta waves, spindle bursts and early gamma oscillations (EGOs). In newborn rodents spindle bursts and EGOs occur spontaneously or can be elicited by sensory stimulation and synchronize the activity in a barrel-related columnar network with topo-graphic organization at the day of birth. Interfering with this early activity causes a disturbance in the development of the cortical architecture, indicating that spindle bursts and EGOs influence the formation of cortical columns. Early neuronal activity also controls the rate of programed cell death in the developing barrel cortex, suggesting that spindle bursts and EGOs are physiological activity patterns particularly suited to suppress apoptosis. It remains to be studied in more detail how these different neocortical activity patterns control early developmental processes such as formation of synapses, microcircuits, topographic maps and large-scale networks. This article is part of a Special Issue entitled: Barrel Cortex.
Activités électrophysiologiques précoces du cortex sensorimoteur (aspects physiologiques et pathologiques)
AIX-MARSEILLE2-BU Méd/Odontol. (130552103) / SudocSudocFranceF
How development sculpts hippocampal circuits and function
International audienceIn mammals, the selective transformation of transient experience into stored memory occurs in the hippocampus, which develops representations of specific events in the context in which they occur. In this review, we focus on the development of hippocampal circuits and the self-organized dynamics embedded within them since the latter critically support the role of the hippocampus in learning and memory. We first discuss evidence that adult hippocampal cells and circuits are sculpted by development as early as during embryonic neurogenesis. We argue that these primary developmental programs provide a scaffold onto which later experience of the external world can be grafted. Next, we review the different sequences in the development of hippocampal cells and circuits at anatomical and functional levels. We cover a period extending from neurogenesis and migration to the appearance of phenotypic diversity within hippocampal cells, and their wiring into functional networks. We describe the progressive emergence of network dynamics in the hippocampus, from sensorimotor-driven early sharp waves to sequences of place cells tracking relational information. We outline the critical turn points and discontinuities in that developmental journey, and close by formulating open questions. We propose that rewinding the process of hippocampal development helps understand the main organization principles of memory circuits
Early patterns of electrical activity in the developing cerebral cortex of humans and rodents.
International audienceDuring prenatal and early postnatal development, the cerebral cortex exhibits synchronized oscillatory network activity that is believed to be essential for the generation of neuronal cortical circuits. The nature and functional role of these early activity patterns are of central interest in neuroscience. Much of the research is performed in rodents and in vitro, but how closely do these model systems relate to the human fetal brain? In this review, we compare observations in humans with in vivo and in vitro rodent data, focusing on particular oscillatory activity patterns that share many common features: delta brushes, spindle bursts and spindle-like oscillations. There is considerable evidence that the basic functional properties of immature cortical networks are conserved through mammalian evolution, making the neonatal rodent an excellent model for studying early cortical activity and associated plasticity during the developmental period corresponding to the human fetal stage. This review is part of the INMED/TINS special issue "Nature and nurture in brain development and neurological disorders", based on presentations at the annual INMED/TINS symposium (http://inmednet.com/)
Network mechanisms of spindle-burst oscillations in the neonatal rat barrel cortex in vivo.
International audienceEarly in development, cortical networks generate particular patterns of activity that participate in cortical development. The dominant pattern of electrical activity in the neonatal rat neocortex in vivo is a spatially confined spindle-burst. Here, we studied network mechanisms of generation of spindle-bursts in the barrel cortex of neonatal rats using a superfused cortex preparation in vivo. Both spontaneous and sensory-evoked spindle-bursts were present in the superfused barrel cortex. Pharmacological analysis revealed that spindle-bursts are driven by glutamatergic synapses with a major contribution of AMPA/kainate receptors, but slight participation of NMDA receptors and gap junctions. Although GABAergic synapses contributed minimally to the pacing the rhythm of spindle-burst oscillations, surround GABAergic inhibition appeared to be crucial for their compartmentalization. We propose that local spindle-burst oscillations, driven by glutamatergic synapses and spatially confined by GABAergic synapses, contribute to the development of barrel cortex during the critical period of developmental plasticity
Blocking GABA(A) inhibition reveals AMPA- and NMDA-receptor-mediated polysynaptic responses in the CA1 region of the rat hippocampus.
International audienceWe have investigated the conditions required to evoke polysynaptic responses in the isolated CA1 region of hippocampal slices from Wistar adult rats. Experiments were performed with extracellular and whole cell recording techniques. In the presence of bicuculline (10 microM), 6-cyano-7-nitroquinoxaline-2-3-dione (10 microM), glycine (10 microM), and a low external concentration of Mg2+ (0.3 mM), electrical stimulation of the Schaffer collaterals/commissural pathway evoked graded N-methyl-D-aspartate (NMDA)-receptor-mediated late field potentials in the stratum radiatum of the CA1 region. These responses were generated via polysynaptic connections because their latency varied strongly and inversely with the stimulation intensity and they were abolished by a high concentration of divalent cations (7 mM Ca2+). These responses likely were driven by local collateral branches of CA1 pyramidal cell axons because focal application of tetrodotoxin (30 microM) in the stratum oriens strongly reduced the late synaptic component and antidromic stimulation of CA1 pyramidal cells could evoke the polysynaptic response. Current-source density analysis suggested that the polysynaptic response was generated along the proximal part of the apical dendrites of CA1 pyramidal cells (50-150 microm below the pyramidal cell layer in the stratum radiatum). In physiological concentration of Mg2+ (1.3 mM), the pharmacologically isolated NMDA-receptor-mediated polysynaptic response was abolished. In control artificial cerebrospinal fluid (with physiological concentration of Mg2+), bicuculline ( 10 microM) generated a graded polysynaptic response. Under these conditions, this response was mediated both by alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/NMDA receptors. In the presence of D-2-amino-5-phosphonovalerate (50 microM), the polysynaptic response could be mediated by AMPA receptors, although less efficiently. In conclusion, suppression of gamma-aminobutyric acid-A inhibition reveals glutamate receptor-mediated network-driven events in the isolated CA1 region. These polysynaptic responses are mediated by AMPA and/or NMDA receptors depending on the pharmacological conditions and the external concentration of Mg2+ used. We suggest that these responses are driven by local recurrent collaterals of CA1 pyramidal cells
Spontaneous activity in developing sensory circuits: Implications for resting state fMRI
The immature brain spontaneously expresses unique patterns of electrical activity that are believed to contribute to the development of neuronal networks. Certain electrographic features of this activity, particularly modulation on an infraslow time scale, resemble activity patterns observed in the mature brain at 'rest', loosely defined as the absence of an investigator imposed task. However, it is not clear whether the immature activity patterns observed at rest are precursors of the spontaneous neuronal activity that forms resting state networks in the adult. Here, we review recent studies that have explored the generative mechanisms of resting state activity during development in the primary sensory systems of premature human neonates and neonatal rodents. The remarkable hypothesis suggested by this work is that while resting state activity during the pre- and possibly near-term period can bear superficial resemblance to adult activity it is fundamentally different in terms of function and origin. During early development spontaneous thalamocortical activity in primary sensory regions is determined largely by transitory generators in the sensory periphery. This is in contrast to the adult, where spontaneous activity generated within thalamocortex, particularly by cortico-cortical connections, dominates. We therefore suggest a conservative interpretation of developmental mapping studies which are based on indirect measurement of activity (e.g. fMRI), or on the partitioning of EEG frequency using bands derived from adult studies. The generative mechanisms for brain activity at early ages are likely different from those of adults, and may play very different roles; for example in circuit formation as opposed to attention. © 2012 Elsevier Inc
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