Amyotrophic lateral sclerosis (ALS) associated with superoxide dismutase 1 (SOD1) mutations in British Columbia, Canada : clinical, neurophysiological and neuropathological features

Stewart, Heather G.

January 2005

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disorder characterized by loss of motor neurons and their supporting cells in the brain, brainstem and spinal cord, resulting in muscle paresis and paralysis including the bulbar (speech, chewing, swallowing) and respiratory muscles. The average age at onset is 55 years, and death due to respiratory failure occurs 2-5 years after symptom onset in ~ 85% of cases. Five to 10% of ALS is familial, and about 20% of familial cases are associated with mutations in the superoxide dismutase 1 (SOD1) gene. To date, 118 SOD1 mutations have been reported worldwide (www alsod.org). All are dominantly inherited, except for the D90A mutation, which is typically recessively inherited. D90A homozygous ALS is associated with long (~14 years) survival, and some atypical symptoms and signs. The reason for this is not known. In contrast, most other SOD1 mutations are associated with average survival, while some are associated with aggressive disease having lower motor neuron predominance and survival less than 12 months. The A4V mutation, which is the most frequently occurring SOD1 mutation in the United States, is an example of the latter. Understanding the pathogenic mechanisms of SOD1 mutants causing widely different disease forms like D90A and A4V is of paramount importance. Overwhelming scientific evidence indicates that mutations in the SOD1 gene are cytotoxic by a “gain of noxious” function, which although not fully understood results in protein aggregation and loss of cell function. This thesis explores different ALS-SOD1 gene mutations in British Columbia (BC), Canada. Two hundred and fifty-three ALS patients were screened for SOD1 mutations, and 12 (4.7%) unrelated patients were found to carry one of 5 different SOD1 mutations: A4V (n=2); G72C (n=1); D76Y (n=1); D90A (n=2); and 113T (n=6). Incomplete penetrance was observed in 3/12 families. Bulbar onset disease was not observed in the SOD1 mutation carriers in this study, but gender distribution was similar to previously reported studies. Age at symptom onset for all patients enrolled, with or without SOD1 mutations, was older than reported in previous studies. On average, patients with SOD1 mutations experience a longer diagnostic delay (22.6 months) compared to patients without mutations (12 months). Two SOD1 patients were originally misdiagnosed including the G72C patient who’s presenting features resembled a proximal myopathy. Neuropathological examination of this patient failed to reveal upper motor neuron disease. The I113T mutation was associated with variable age of onset and survival time, and was found in 2 apparently sporadic cases. The D76Y mutation was also found in an apparently sporadic case. I113T and D76Y are likely influenced by other genetic or environmental factors in some individuals. Two patients were homozygous for the D90A mutation, with clinical features comparable to patients originally described in Scandinavia. Clinical and electrophysiological motor neuron abnormalities were observed in heterozygous relatives of one D90A homozygous patient. The A4V patients were similar to those described in previous studies, although one had significant upper motor neuron disease both clinically and neuropathologically. Clinical neurophysiology is essential in the diagnosis of ALS, and helpful in monitoring disease progression. A number of transcranial magnetic stimulation (TMS) studies may detect early dysfunction of upper motor neurons when imaging techniques lack sensitivity. Peristimulus time histograms (PSTHs), which assess corticospinal function via recording of voluntarily activated single motor units during low intensity TMS of the motor cortex, were used to study 19 ALS patients having 5 different SOD1 mutations (including 8 of the 12 patients identified with SOD1 mutations from BC). Results were compared with idiopathic ALS cases, patients with multiple sclerosis (MS), and healthy controls. Significant differences were found in corticospinal pathophysiology between ALS patients with SOD1 mutations, idiopathic ALS, and MS patients. In addition, different SOD1 mutants were associated with significantly different neurophysiologic abnormalities. D90A homozygous patients show preserved if not exaggerated cortical inhibition and slow central conduction, which may reflect the more benign disease course associated with this mutant. In contrast, A4V patients show cortical hyper-excitability and only slightly delayed central conduction. I113T patients display a spectrum of abnormalities. This suggests mutant specific SOD1 pathology(s) of the corticospinal pathways in ALS.

ALS

SOD1

complete penetrance

incomplete penetrance

mis-diagnosis

upper motor neuron

clinical neurophysiology

transcranial magnetic stimulation

peristimulus time histogram

corticospinal pathway

cortical inhibition

cortical hyper-excitability

Neural circuits engaged in mastication and orofacial nociception

Athanassiadis, Tuija

January 2009

A deeper understanding of both movement control and the effects of nociceptor inputs on our motor systems is critical for proper clinical diagnosis of musculo-skeletal dysfunctions and for development of novel rehabilitation schemes. In the jaw system, masticatory movements are produced by a central pattern generator (CPG) located in the brainstem. Considerable efforts have been made in deciphering this neuronal network. The present thesis contributes towards an increasingly detailed understanding of its essential elements, and presents a hypothesis of how deep somatic pain (i.e. muscle pain) may be evoked and interferes with the masticatory CPG circuitry. In Paper I, the expression of c-Fos-like protein was used as a molecular marker to visualize brainstem neurons that were active during induced fictive mastication in the anesthetized and paralyzed rabbit. Our findings provide a previously lacking detailed record of the neuronal populations that form the masticatory motor pattern. Certain cells were located in brainstem areas previously suggested to be involved in the masticatory CPG. However, it was a new finding that neurons in the dorsal part of the trigeminal main sensory nucleus (NVsnpr-d) may belong to this circuitry. Paper II focused on the discovered neurons in NVsnpr in an in vitro slice preparation from young rats.  Intracellular recordings allowed us to define two cell types based on their response to depolarizing current. Microstimulation applied to the trigeminal motor nucleus, its reticular border, the parvocellular reticular formation and the nucleus reticularis pontis caudalis, elicited postsynaptic potentials in 81% of the neurons tested. Responses obtained were predominately excitatory and sensitive to gluta-matergic antagonists DNQX or/and APV. Some inhibitory and biphasic responses were also evoked. Bicuculline methiodide or strychnine blocked the IPSPs indicating that they were mediated by GABAA or glycinergic receptors. About one third of the stimulations activated both types of neurons antidromically. Neurons in NVsnpr-d seem to gather all the conditions that can theoretically account for a role in masticatory rhythm generation. In Paper III, the masticatory model system was used to investigate the possible role of muscle spindle primary afferents in development of persistent musculoskeletal pain. Following intramuscular acidic (pH 4.0) saline injections of rat masseter muscles, in vitro whole cell recordings were done from jaw closing muscle spindle somata located in the trigeminal mesencephalic nucleus (NVmes). Compared to control neurons, the somata of afferents exposed to acid had more hyperpolarized membrane potentials, more hyperpolarized thresholds for firing, high frequency membrane oscillations and ectopic bursting of action potentials. These changes in membrane properties lasted for up to 35 days. Within the same time frame experi-mental animals showed hypersensitivity to touch on the skin covering the injected muscle. Similar saline injections also resulted in a significant increase of activity dependent c-Fos expression in NVmes neurons compared to controls. Immuno-fluorescence and lectin binding studies indicated that small-caliber muscle afferents containing known nociceptor markers (CGRP, SP, P2X3, TRPV1 and IB4) and expressing glutamate receptors are found close to the annulo-spiral endings of the NVmes afferents. Combined, our new observations support the hypothesis that excessive release of glutamate, within muscle spindles due to ectopically evoked antidromic action potentials, could lead to development of persistent musculoskeletal pain by activation and/ or sensitization of adjacent muscle afferent nociceptors.

Neurophysiology

Neurofysiologi

Epileptiform Activity Induced Alterations In Ca2+ Dynamics And Network Physiology Of Hippocampal Neurons - In Vitro Studies

Srinivas, V Kalyana

12 1900

Epilepsy is characterized by the hyperexcitability of individual neurons and hyper synchronization of groups of neurons (networks). The acquired changes that take place at molecular, cellular and network levels are important for the induction and maintenance of epileptic activity in the brain. Epileptic activity is known to alter the intrinsic properties and signaling of neurons. Understanding acquired changes that cause epilepsy may lead to innovative strategies to prevent or cure this neurological disorder. Advances in in vitro electrophysiological techniques together with experimental models of epilepsy are indispensible tools to understand molecular, cellular and network mechanisms that underlie epileptiform activity. The aim of the study was to investigate the epileptiform activity induced alterations in Ca2+ dynamics in apical dendrites of hippocampal subicular pyramidal neurons in slices and changes in network properties of cultured hippocampal neurons. We have also made attempts to develop an in vitro model of epilepsy using organotypic hippocampal slice cultures. In the first part of the present study, investigations on the basic properties of dendritic Ca2+ signaling in subicular pyramidal neurons during epileptiform activity are described. Subiculum, a part of the hippocampal formation is present, adjacent to the CA1 subfield. It acts as a transition zone between the hippocampus and entorhinal cortex. It receives inputs directly from the CA1 region, the entorhinal cortex, subcortical and other cortical areas. Several forms of evidences support the role of subiculum in temporal lobe epilepsy. Pronounced neuronal loss has been reported in various regions of the hippocampal formation (CA1 and CA3) leaving the subiculum generally intact in human epileptic tissue. It has been observed that epileptic activity is generated in subiculum in cases where the CA3 and CA1 regions are damaged or even absent. However, it is not clear how subicular neurons protect themselves from epileptic activity induced neuronal death. It is widely accepted that epileptiform activity induced neuronal damage is a result of an abnormally large influx of Ca2+ into neuronal compartments. In the present study, combined hippocampus / entorhinal cortical brain slices were exposed to zero Mg2+ + 4-amino pyridine artificial cerebrospinal fluid (ACSF) to generate spontaneous epileptiform discharges. Whole cell current-clamp recordings combined with Ca2+ imaging experiments (by incorporating Oregon green BAPTA-1 in the recording pipette) were performed on subicular pyramidal neurons to understand the changes in [Ca2+]i transients elicited in apical dendrites, in response to spontaneous epileptic discharges. To understand the changes occurring with respect to control, experiments were performed (in both control and in vitro epileptic conditions) where [Ca2+]i transients in dendrites were elicited by back propagating action potentials following somatic current injections. The results show clear distance-dependent changes in decay kinetics of [Ca2+]i transients (τdecay), without change in the amplitude of the [Ca2+]i transients, in distal parts (95–110 µm) compared to proximal segments (30–45 µm) of apical dendrites of subicular pyramidal neurons under in vitro epileptic condition, but not in control conditions. Pharmacological agents that block Ca2+ transporters viz. Na+/Ca2+ exchangers (Benzamil), plasma membrane Ca2+-ATPase pumps (Calmidazolium) and smooth endoplasmic reticulum Ca2+-ATPase pumps (Thapsigargin) were applied locally to the proximal and distal part of the apical dendrites in both experimental conditions to understand the molecular aspects of the Ca2+ extrusion mechanisms. The relative contribution of Na+/Ca2+ exchangers in Ca2+ extrusion was higher in the distal apical dendrite in in vitro epileptic condition. Using computer simulations with NEURON, biophysically realistic models were built to understand how faster decay of [Ca2+]i transients in the distal part of apical dendrite associated with [Ca2+]i extrusion mechanisms affect excitability of the neurons. With a linear increase in the density of Na+/Ca2+ exchangers along the apical dendrite, the decrease in τ decay values of [Ca2+]i transients in distal regions seen in experimental epileptic condition was reproduced in simulation. This linear increase in Na+/Ca2+ exchangers lowered the threshold for firing in response to consecutive synaptic inputs to the distal apical dendrite. Our results thus, show the existence of a novel neuroprotective mechanism in distal parts of the apical dendrite of subicular pyramidal neurons under in vitro epileptic condition with the Na+/Ca2+ exchangers being the major contributors to this mechanism. Although the enhanced contribution of Na+/Ca2+ exchangers helps the neuron in removing excess [Ca2+]i loads, it paradoxically makes the neuron hyperexcitable to synaptic inputs in the distal parts of the apical dendrites. Thus, the Na+/Ca2+ exchangers may actually protect subicular pyramidal neurons and at the same time contribute to the maintenance of epileptiform activity. In the second part of the study, neuronal network topologies and connectivity patterns were explored in control and glutamate injury induced epileptogenic hippocampal neuronal networks, cultured on planar multielectrode array (8×8) probes. Hyper synchronization of neuronal networks is the hallmark of epilepsy. To understand hyper synchronization and connectivity patterns of neuronal networks, electrical activity from multiple neurons were monitored simultaneously. The electrical activity recorded from a single electrode mainly consisted of randomly fired single spikes and bursts of spikes. Simultaneous measurement of electrical activity from all the 64 electrodes revealed network bursts. A network burst represents the period (lasting for 0.1–0.2 s) of synchronized activity in the network and, during this transient period, maximum numbers of neurons interact with each other. The network bursts were observed in both control and in vitro epileptic networks, but the frequency of network bursts was more in the latter, compared to former condition. Time stamps of individual spikes (from all 64 electrodes) during such time-aligned network burst were collected and stored in a matrix and used to construct the network topology. Connectivity maps were obtained by analyzing the spike trains using cross-covariance analysis and graph theory methods. Analysis of degree distribution, which is a measure of direct connections between electrodes in a neuronal network, showed exponential and Gaussian distributions in control and in vitro epileptic networks, respectively. Quantification of number of direct connections per electrode revealed that the in vitro epileptic networks showed much higher number of direct connections per electrode compared to control networks. Our results suggest that functional two-dimensional neuronal networks in vitro are not scale-free (not a power law degree distribution). After brief exposure to glutamate, normal hippocampal neuronal networks became hyperexcitable and fired a larger number of network bursts with altered network topology. Quantification of clustering coefficient and path length in these two types of networks revealed that the small-world network property was lost once the networks become epileptic and this was accompanied by a change from an exponential to a Gaussian network. In the last part of the study, we have explored if an excitotoxic glutamate injury (20 µM for 10 min) that produces spontaneous, recurrent, epileptiform discharges in cultured hippocampal neurons can induce epileptogenesis in hippocampal neurons of organotypic brain slice cultures. In vitro models of epilepsy are necessary to understand the mechanisms underlying seizures, the changes in brain structure and function that underlie epilepsy and are the best methods for developing new antiseizure and antiepileptogenic strategies. Glutamate receptor over-activation has been strongly associated with epileptogenesis. Recent studies have shown that brief exposure of dissociated hippocampal neurons in culture to glutamate (20 µM for 10 min) induces epileptogenesis in surviving neurons. Our aim was to extend the in vitro model of glutamate injury induced epilepsy to the slice preparations with intact brain circuits. Patch clamp technique in current-clamp mode was employed to monitor the expression of spontaneous epileptiform discharges from CA1 and CA3 neurons using several combinations of glutamate injury protocols. The results presented here represent preliminary efforts to standardize the glutamate injury protocol for inducing epileptogenesis in organotypic slice preparations. Our results indicate that glutamate injury protocols that induced epileptogenesis in dissociated hippocampal neurons in culture failed to turn CA1 and CA3 neurons of organotypic brain slice cultures epileptic. We also found that the CA1 and CA3 neurons of organotypic brain slice cultures are resilient to induction of epileptogenesis by glutamate injury protocols with 10 times higher concentrations of glutamate (200µM) than that used for neuronal cultures and long exposure periods (upto 30 min). These results clearly show that the factors involved in induction of epileptiform activity after glutamate injury in neuronal cultures and those involved in making the neurons in organotypic slices resilient to such insults are different, and understanding them could give vital clues about epileptogenesis and its control. The resilience of CA1 and CA3 neurons seen could be due to differences in homeostatic plasticity that operate in both these experimental systems. However, further studies are required to corroborate this hypothesis.

Calcium - Biophysics

Neurons - Physiology

Epilepsy

Hippocampus

Brain Slices

Hippocampal Neurons

Epileptic Seizure

Epileptogenesis

Epileptiform Activity

Hippocampal Neuronal Network

Apical Dendrites

Pyramidal Neurons

Neurophysiology

Σχεδιασμός και ανάπτυξη γραφικού περιβάλλοντος για επεξεργασία εγκεφαλογραφικού σήματος μέσω MATLAB / Design and implementation of a graphical user interface for the processing of EEG signal through MATLAB

Κουππάρης, Ανδρέας

27 April 2009

Η επεξεργασία του εγκεφαλογραφικού σήματος με τη χρήση νέων υπολογιστικών τεχνικών δίνει τεράστια ώθηση στη μελέτη νευροφυσιολογικών ερωτημάτων. Η χρήση αυτών των μεθόδων από ερευνητές με ελάχιστες γνώσεις προγραμματισμού απαιτεί την ανάπτυξη ενός εύχρηστου γραφικού περιβάλλοντος που να περιλαμβάνει εργαλεία για την αυτοματοποιημένη εφαρμογή των υπολογιστικών τεχνικών. Στην παρούσα εργασία παρουσιάζεται το γραφικό περιβάλλον που αναπτύχθηκε στη Μονάδα Νευροφυσιολογίας στο Εργαστήριο Φυσιολογίας της Ιατρικής Σχολής του Πανεπιστημίου Πατρών για την υποστήριξη των εγκεφαλογραφικών μελετών. Επεξηγούνται οι δυσκολίες της επεξεργασίας εγκεφαλογραφικού σήματος, οι λόγοι που καθιστούν τη χρήση ήδη υπαρχόντων εργαλείων αδύνατη ή ασύμφορη και δικαιολογείται η επιλογή της πλατφόρμας του MATLAB για την ανάπτυξη του περιβάλλοντος. Δίνεται αναλυτικά η πορεία υλοποίησης του προγράμματος και οι οδηγίες χρήσης του. Το περιβάλλον περιλαμβάνει μεθόδους για εισαγωγή δεδομένων από το πρόγραμμα καταγραφής Neuroscan, επιλογή τμημάτων για επεξεργασία, απεικονίσεις στα πεδία του χρόνου, του χώρου και της συχνότητας, εφαρμογή φίλτρων, ανάλυση προκλητών δυναμικών με παρουσίαση μέσης κυματομορφής και μέσου φασματογραφήματος, δημιουργία εικονικών καναλιών και συνεργασία με άλλα προγράμματα όπως τη χρήση της μεθόδου ανάλυσης ανεξαρτήτων συνιστωσών του EEGLAB. Παρουσιάζονται τα αποτελέσματα από τη χρήση του προγράμματος σε δυο μελέτες του εργαστηρίου. Καταρχάς, σε φυσιολογικό ύπνο για τη μελέτη της σχέσης δυο κυματομορφών του δεύτερου σταδίου του ύπνου, των συμπλεγμάτων Κ και των ατράκτων του ύπνου, όπου διαπιστώθηκε ότι η εμφάνιση του συμπλέγματος Κ επηρεάζει τη συχνότητα των ατράκτων όταν συμπίπτουν χρονικά. Έπειτα, σε παθολογικό ύπνο για τη διερεύνηση μεταβολών του θαλαμοφλοιικού κυκλώματος και των ατράκτων του ύπνου σε ένα παιδί με ιστορικό επιληψίας αφαιρέσεων παιδικής ηλικίας. Σε αυτή την περίπτωση διαπιστώθηκε η ύπαρξη ενός ρυθμού με χαρακτηριστικά παρόμοια των ατράκτων του ύπνου, αλλά σε διαφορετική συχνότητα, ενώ παράλληλα, σημαντικά μειωμένη ήταν η εμφάνιση φυσιολογικών ατράκτων. Τέλος, αναδεικνύονται τα πλεονεκτήματα της χρήσης του περιβάλλοντος και συζητείται η εκπλήρωση των στόχων και αναγκών του εργαστηρίου μέσα από το πρόγραμμα καθώς και οι πιθανές μελλοντικές επεκτάσεις. / The use of novel computational techniques in the analysis of encephalographic signals has given a huge boost to the study of neurophysiological questions. The use of such methods by researchers who have little knowledge of computer programming requires the development of a user-friendly graphical interface that includes tools for the automated application of these computational techniques. The present work presents the graphical interface developed at the Neurophysiology Unit of the University of Patras' Medical School for the support of EEG studies. The difficulties of the processing of EEG signals and the reasons that render the use of existing tools impossible or unfit are explained and I justify the choice of the MATLAB platform for the development of the environment. The course of the realization of the program and directions for its use are given in detail. The environment includes methods that import data from the Neuroscan recording system, select portions for processing, plot data over time, space and frequency, apply filters, analyze event-related potentials using average waveform and average spectrogram views, create virtual channels and cooperate with other programs, like using EEGLAB's technique of independent component analysis. The results of using the program in two laboratory studies are presented. First, it helped analyze normal sleep data, for the study of the relationship between two graphoelements of the second NREM sleep stage, the K complex and the sleep spindle. It was shown that the occurrence of a K complex affects the frequency of a spindle when they coincide. Next, in abnormal sleep data, for the study of possible changes of the thalamocortical pathway and sleep spindles on a child with medical history of childhood absence. In this case, the appearance of a rhythmic wave with attributes similar of a sleep spindle but different frequency of oscillation was shown, while at the same time, the incidence of normal spindles was significantly lower. Finally, the advantages of using this environment are shown and the fulfillment of the lab's goals and needs by the program, as well as possible future expansions, are discussed.

Εγκεφαλογράφημα

Ανάλυση σήματος

Γραφικό περιβάλλον

Νευροφυσιολογία

616.804 754 7

Electroencephalography

Signal analysis

GUI

Time-frequency analysis

MATLAB

Neurophysiology

Neurotrophin expression in sympathetic neurons influences of exogenous NGF and afferent input /

Jones, Elizabeth Ellen.

January 2004

Thesis (M.S.)--Miami University, Dept. of Zoology, 2004. / Title from first page of PDF document. Includes bibliographical references (p. 36-47).

Etude fonctionnelle de la neurotransmission glutamatergique cortico-striatale et GABAergique striatale dans la physiologie normale et pathologique

Lambot, Laurie

19 August 2015

Apprendre de nouvelles séquences d'actions est l'une des fonctions cruciales du système nerveux central. Cet apprentissage est notamment assuré par les ganglions de la base ;ceux-ci jouent un rôle critique dans la sélection d'actions ou la prise de décisions en permettant l'apprentissage et la sélection des programmes moteurs les plus appropriés. Comprendre la physiologie de cette circuiterie neuronale hautement complexe et particulièrement celle du striatum - structure d'entrée des ganglions de la base - est donc d'une importance capitale dans l'amélioration de notre compréhension de ce système neuronal. Dans ce travail, nous nous sommes intéressés au rôle fonctionnel du récepteur NMDA (NMDA-R) dans une sous-population des neurones de projection, les neurones striatopallidaux. Ces récepteurs sont impliqués dans les modifications de l'efficacité synaptique à long terme et jouent donc un rôle central dans le mécanisme d'apprentissage. Notre travail démontre que le NMDA-R des neurones striatopallidaux est un élément essentiel de l'apprentissage au niveau des ganglions de la base. En effet, nous observons que des souris transgéniques, déficientes en NMDA-R spécifiquement dans les neurones striatopallidaux, disposent d'une capacité d'adaptation réduite aux modifications de leur environnement. De plus, nous démontrons que ces souris transgéniques présentent des connexions neuronales affaiblies susceptibles d'expliquer les altérations comportementales observées. Dans ce travail de thèse, nous avons également développé une stratégie expérimentale reposant sur l'utilisation d'outils optogénétiques afin de déterminer le rôle d'une population d'interneurones inhibiteurs du striatum, les "fast spiking interneurons" (FSI). Cette technique a été mise en oeuvre avec succès et nous avons validé son efficacité in vitro. Nous démontrons que cette approche permet un contrôle l'activité électrique des FSI à l'échelle de la milliseconde. Son application in vivo, combinée avec des paradigmes comportementaux, nous permettra d'élucider le rôle spécifique de cette sous-population neuronale, tant au niveau du contrôle moteur que de la prise de décisions, dans des situations physiologiques ou pathologiques. Dans son ensemble, le présent travail ouvre les portes vers une meilleure compréhension de l'orchestration de la microcircuiterie striatale. / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished

Médecine pathologie humaine

Neurophysiology

Neural transmission

Neurons -- Physiology

Amino acid neurotransmitters

GABA

Neurophysiologie

Transmission nerveuse

Neurones -- Physiologie

Acides aminés neurotransmetteurs

GABA

striatumn récepteur NMDA

neuroscience

A influência do voo na resposta do H1 e o registro do comportamento motor em Chrysomya megacephala / The influence of flight in the H1s response and the record of motor behavior in Chrysomya megacephala

Carolina Menezes Silverio

19 August 2013

Desenvolvemos um protocolo experimental para estudar a codificação do movimento horizontal pelo neurônio H1 de moscas varejeiras Chrysomya megacephala durante o voo. Tradicionalmente, o neurônio H1 é considerado puramente sensorial, e a maioria dos trabalhos tem utilizado o trem de potenciais de ação deste neurônio para explorar o código neural visual da mosca enquanto esta se encontra imobilizada (cabeça, asas, patas) e observa passivamente uma imagem que se move de maneira controlada. Nosso laboratório já dispunha de um aparato para registrar de maneira adequada a atividade do H1, enquanto a mosca imobilizada observava um padrão de barras verticais se movendo de acordo com uma sequência de velocidades previamente escolhidas pelo experimentador. Por meio de um novo suporte, especialmente desenvolvido neste trabalho, pudemos obter as medidas eletrofisiológicas quando apenas parte do corpo do inseto se encontra fixo. Além disso, conseguimos encontrar uma maneira de estimular a mosca para que esta apresentasse períodos de atividade, com batimentos de asa, similares ao voo. Utilizamos estes períodos de atividade de voo para registrar a atividade dos músculos que controlam a direção do voo. Também utilizamos microfones que captam pequenas diferenças de pressão do batimento das asas para inferir quando a mosca quer mudar a direção do voo e validamos estas medidas com o auxílio de um pequeno acelerômetro adaptado à haste de fixação da mosca. Mostramos que a taxa média de disparo do H1 é mais alta quando a mosca está voando do que quando está com as asas paradas. Além disso, a resposta ao estímulo visual é mais rápida e mais intensa quando a mosca está voando. Estes resultados são evidências de que a codificação da informação visual é diferente nos dois casos. Nossos experimentos com registro da atividade de controle motor do voo através de microfones permitiram encontrar padrões que podem ser usados para inferir a tentativa do inseto de mudar a direção do voo, em um intervalo de poucas batidas de asas e de maneira não invasiva. Esta informação poderá ser utilizada no futuro para produzir um equipamento em que a própria mosca controle o movimento da imagem em tempo real. / We developed a protocol do address the movement information coding in flying Chrysomya Megacephala by the horizontal sensitive H1neuron. H1 is traditionally considered a purely sensory neuron and his sequence of action potentials is used to explore the visual neural code while an immobilized fly passively watch a movie generated by the experimenter. We improved an apparatus to perform such experiments, that was already working in our laboratory, by developing a new holder for the fly and electrode that allowed to record from H1 while only part of the fly was fixed, keeping wings and legs free to move. Moreover we found a protocol to stimulate the fly to present long periods of wing beating activity, very similar to the insect flying. During these flying periods of activity, we also recorded from the steering muscles that control fly direction as well as from small microphones sensitive to subtle pressure variations of the beating wings when the fly try to change direction. These recordings were validated by using an accelerometer adapted to the fly fixation rod. According to our results, the firing rate of H1 increases during the flying periods. Moreover, the response to visual stimuli is faster and more intense during the flying than the response when the wings are not beating. These are evidences that the information coding is different in both cases. We could also find some patterns in the time series of the microphones recordings that allowed us to infer, in a small number of wing beatings, when the insect tries to turn and what is the turning direction. This information can be useful to perform new experiments in the future, were the fly controls in real-time the image movement.

Comportamento motor

Influência do voo na resposta visual

Neurobiofísica

Neurônio H1

Sistema visual de moscas

H1 neuron

Motor behavior

Neurophysiology

Visual system of flies

A união do corpo e da alma n\'A estrutura do comportamento / The union of body and soul in The Structure of Behavior

Natália Giosa Fujita

29 August 2014

Procuramos mostrar como a primeira das teses doutorais de Merleau-Ponty, A Estrutura do Comportamento, torna possível o retorno ao problema clássico da união do corpo e da alma, uma vez que, ao mesmo tempo em que faz a crítica do empirismo mecanicista que embasa as tentativas científicas (da neurofisiologia e da psicologia) de dar conta da vida orgânica e do comportamento, descobre nas descrições destes fenômenos um meio original em relação ao para-si suposto pelo criticismo como explicação e fundamentação última do conhecimento e limite para o que se pode dizer sobre o ser. Procuramos ademais sugerir as limitações do quadro conceitual em que o corpo e suas realizações, dentre as quais especialmente a percepção, podem voltar a desempenhar um papel decisivo na interrogação filosófica, em especial pela ênfase, a nosso ver excessiva, que o autor faz recair sobre a articulação entre símbolo e verdade e pela falta de descrição positiva da articulação entre as formas chamadas inferiores do comportamento ligadas ao instinto, à vida orgânica e a uma temporalidade circular - e o nível simbólico remetido à verdade, à liberdade e à História / We try to show how Merleau-Ponty\'s first doctoral thesis, The Structure of Behavior, allows for a comeback of the classical problem of the union of body and soul, once it criticizes the mechanicist empirism founding the scientific attempts (from neurophysiology and psychology) to explain the organic life and behavior, while unearthing in those fenomena a milieu that differs from the transcendental self embedded in criticism as a final explanation and foundation of knowledge, and as the limit to what one can say about being. We also try to point out to the limits of such conceptual framework, in which body and its performances, specially perception, may again play a crucial role in philosophical investigation, in particular because of excessive emphasis placed upon the connection between symbol and truth, and for a lack of positive description of the articulation between the so-called inferior forms of behavior connected to instincts, organic life and circular time and the symbolic level related to truth, freedom and History

Behaviorismo

Comportamento

Corpo

Corpo e alma

Gestalt

Lacan

Merleau-Ponty

Neurofisiologia

Psicanálise

Psicologia da Gestalt

Behavior

Behaviorism

Body

Body and soul

Gestalt

Gestalt psychology

Lacan

Merleau-Ponty

Neurophysiology

Psychoanalysis

Caracterização das vias de sinalização desencadeadas pelas interações PrPc-p66 e PrPc-laminina e sua relevância nos processos de morte celular programada e consolidação da memória / Characterization of the signaling pathways triggered by the PrPc-p66 and PrPc-laminin interactions and their relevance in the processes of programmed cell death and memory consolidation

Adriana Regina de Oliveira Freitas

06 June 2002

PrPc é uma glicoproteína de 35 KDa, bastante conservada entre as espécies e essencial no processo de transmissão e patogênese de várias doenças neurodegenerativas como a encefalopatia espongiforme bovina e a doença de Creutzfeldt-Jacob (PRUSINER, 1991). Embora sua função fisiológica ainda seja desconhecida, sabe-se que a patogênese das doenças priônicas requer a sua expressão e é freqüentemente acompanhada do acúmulo no cérebro de uma isoforma anormal de PrPc, designada PrPsc (GABIZON e cols., 1997). Interessado nos possíveis papéis fisiológicos da proteína PrPc, nosso grupo tem se dedicado a estudar as interações que PrPc realiza com outras moléculas. Identificamos e caracterizamos duas interações nas quais PrPc está envolvido: com uma proteína ligante de 66 KDa, recém-identificada como sendo a proteína STI1 (ZANATA e cols., 2002) e com a principal proteína não colagênica da matriz extracelular, a laminina (GRANER e cols., 2000). No presente trabalho, procuramos investigar as vias de sinalização deflagradas por cada uma dessas interações, como também o seu papel nos mecanismos de morte celular programada e memória. Os resultados apresentados nesse trabalho demonstram que a interação PrPc-p66 desencadeia uma resposta neuroprotetora na camada neuroblástica da retina de roedores em desenvolvimento via cAMP/PKA. Além disso, verificamos que a interação PrPc-laminina desempenha um importante papel na formação da memória de curta duração através da ativação da via cAMP-PKA-MAPK, e na memória de longa duração ativando somente a via cAMP/PKA. / PrPc is an extremely conserved 35 KDa glycoprotein which seems to be essential during the transmission and pathogenesis of several neurodegenerative diseases like bovine spongiform encephalopathy or Creutzfeldt-Jacob disease (PRUSINER, 1991). Although the physiological function of this protein remains unclear, it is well established that prion diseases require PrPc expression and are often characterized by deposition of an abnormal PrPc isoform, named PrPsc (GABIZON et. al., 1997). Interested in the normal fuction of PrPc, our group has been dedicated to study the interations that PrPc could entertain with other molecules. We have identified and characterized two interactions in which PrPc is involved: with a 66 KDa ligand protein, recently identified as the STI1 protein (ZANATA et. al., 2002) and with laminin (GRANER et. al., 2000). In this work, we have investigated the signaling pathways triggered by these interactions, as well as their relevance in programmed cell death and memory formation mechanisms. We show in this work that PrPc-p66 interaction transduces neuroprotective signals through a cAMP/PKA-dependent pathway in the neuroblastic layer of rodents\' retina. Moreover, we demonstrated that PrPc-laminin interaction has an important role for short-term memory formation through the activation of cAMP-PKA-MAPK pathways and for long-term memory with the activation of the cAMP/PKA pathway only.

Apoptose (Patologia)

Células mortas (Fisiologia)

Memória

Morte celular

Neurofisiologia

PrPc

Transdução de sinal

Apoptosis (Pathology)

Cell death

Dead cells (Physiology)

Memory

Neurophysiology

PrPc

Signal transduction

"Estudo sobre a parestesia do nervo alveolar inferior pós cirurgias de terceiros molares inferiores" / Study of alveolar Inferior Nerve Paresthesia after inferior third molar surgery.

Marta Maria Becker Prado

04 November 2004

A parestesia é um distúrbio neurosensitivo causado por uma lesão no tecido nervoso. Ela tem uma incidência pouco freqüente após as cirurgias de terceiros molares inferiores; no entanto para o cirurgião dentista é de grande relevância. A literatura comenta sobre os tipos de lesão nervosa, causas e alternativas de tratamento não conservadores ligados à neuromicrocirurgia que são relacionados nesses casos. Nesse trabalho procurou-se estabelecer a classificação da lesão ao nervo alveolar inferior que ocorre nas exodontias de terceiros molares inferiores, entender os mecanismos fisiológicos, as causas principais que levam à ocorrência desse distúrbio e estudar as técnicas de neuromicrocirurgia, com suas indicações e contra-indicações para os tipos de lesão nervosa. / Paresthesia consists of a neurosentitive disturb resulting from nerve tissue injury. It is less likely to occur following lower third molar surgeries, despite being highly relevant for dentists. The literature comments on the types of nerve injuries, its causes and related non-conservative treatment procedures involving neuromicrosurgery in such cases. This essay is an attempt to establish the types of nerve injury classification that occur following lower third molar surgery involving the inferior alveolar nerve, understand the physiological mechanisms, the main causes that result in such disturbance, and study the neuromicrosurgery procedures, their indications and non-indications concerning types of nerve injury.

exodontia de terceiro molar inferior

lesão de nervo

nervo alveolar inferior

neurofisiologia

neuromicrocirurgia

parestesia

neurophysiology

inferior alveolar nerve

lower third molar surgery

nerve injury

neuromicrosurgery

paresthesia