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Granular retrosplenial cortex layer 2/3 generates high frequency oscillation events coupled with hippocampal sharp wave-ripples and Str. LM high gammaArndt, Kaiser C. 11 June 2024 (has links)
Encoding and consolidation of memories are two processes within the hippocampus, and connected cortical networks, that recruit different circuit level dynamics to effectively process and pass information from brain region to brain region. In the hippocampal CA1 pyramidal layer local field potential (LFP), these processes take the form of theta and sharp wave ripples (SPW-Rs) for encoding and consolidation, respectively. As an animal runs through an environment, neurons become active at specific locations in the environment (place cells) increasing their firing rate, functionally representing these specific locations. These firing rate increases are organized within the local theta oscillations and sequential activation of many place cells creates a map of the environment. Once the animal stops moving and begins consummatory behaviors, such as eating, drinking, or grooming, theta activity diminishes, and large irregular activity (LIA) begins to dominate the LFP. Spontaneously, with the LIA, the place cells active during the experience are replayed during SPW-Rs in the same spatial order they were encountered in the environment. Both theta and SPW-R oscillations and their associated neuronal firing are necessary for effective place recognition as well as learning and memory. As such, interruption or termination of SPW-R events results in decreased learning performance over days. During exploration, the associated theta and sequential place cell activity is thought to encode the experience. During quiet restfulness or slow wave sleep (SWS), SPW-R events, that replay experience specific place sequences, are thought to be the signal by which systems consolidation progresses and the hippocampus guides cortical synaptic reorganization.
The granular retrosplenial cortex (gRSC) is an associational area that exhibits high frequency oscillations (HFOs) during both hippocampal theta and SPW-Rs, and is potentially a period when the gRSC interprets incoming content from the hippocampus during encoding and systems consolidation. However, the precise laminar organization of synaptic currents supporting HFOs, whether the local gRSC circuitry can support HFOs without patterned input, and the precise coupling of hippocmapla oscillations to gRSC HFOs across brain states remains unknown. We aimed to answer these questions using in vivo, awake electrophysiological recordings in head-fixed mice that were trained to run for water rewards in a 1D virtual environment. We show that gRSC synaptic currents supporting HFOs, across all awake brain states, are exclusively localized to layer 2/3 (L2/3), even when events are detected within layer 5 (L5). Using focal optogenetics, both L2/3 and L5 can generate induced HFOs given a strong enough broad stimulation. Spontaneous gRSC HFOs occurring outside of SPW-Rs are highly comodulated with medial entorhinal cortex (MEC) generated high gamma in hippocampal stratum lacunosum moleculare. gRSC HFOs may serve a necessary role in communication between the hippocampus during SPW-Rs states and between the hippocampus, gRSC, and MEC during theta states to support memory consolidation and memory encoding, respectively. / Doctor of Philosophy / As an animal moves through an environment, individual neurons in the hippocampus, known as place cells, increase and decrease their firing rate as the animal enters and exits specific locations in the environment. Within an environment, multiple neurons become active in different locations, this cooperation of spiking in various locations creates a place map of the environment. Now let's say when the animal moved from one corner of the environment to another, place cells 'A', 'C', 'B', 'E', and 'D' became active in that order. This means, at any given point in the environment, the animal is standing in a venn-diagram-esque overlap of place fields, or locations individual place cells represent. A key question that entranced researchers for many years was how do these neurons know when to be active to not impinge on their neighbor's locations? The answer to this question rested with population electrical activity, known as the local field potential (LFP), that place cell activity is paced to. During active navigation through an environment, place cells activity is coupled to the phase of a slow ~8 hertz (Hz) theta oscillation. Within one theta cycle, or peak to peak, multiple place cells are active, representing the venn diagram of location the animal is in. Importantly, this theta activity and encoding of place cell activity is largely seen during active running or rapid eye movement (REM) sleep.
During slow wave sleep (SWS), after an animal has experienced a specific environment and has created a place map, place cells are reactivated in the same order the animal experienced them in. From our previous example, the content of this reactivation would be the place cells 'A', 'C', 'B', 'E', and 'D' which all would be reactivated in that same order. These reactivations or replays occur during highly synchronous and fast LFP oscillations known as sharp wave-ripples (SPW-Rs). SPW-Rs are thought to be a key LFP event that drives memory consolidation and the eventual conversion of short-term memory into long-term memory. However, for consolidation to occur, connected cortical regions need to be able to receive and interpret the information within SPW-Rs. The granular retrosplenial cortex (gRSC) is one proposed region that serves this role. During SPW-Rs the superficial gRSC has been shown to exhibit high frequency oscillations (HFOs), which potentially serve the purpose for interpreting SPW-R content. However, HFOs have been reported during hippocampal theta, suggesting HFOs serve multiple purposes in interregional communication across different states. In this study, we found that naturally occurring gRSC HFOs occur exclusively in layer 2/3 across all awake brain states. Using focal optogenetic excitation we were able to evoke HFOs in both layer 2/3 and 5. Spontaneous gRSC HFOs occurring without SPW-Rs were highly comodulated with medial entorhinal cortex (MEC) generated high gamma in hippocampal stratum lacunosum moleculare. gRSC HFOs may serve a general role in supporting hippocampo-cortical dialogue during SPW-R and theta brain states to support memory consolidation and encoding, respectively.
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Interferindo com oscila??es de alta frequ?ncia no hipocampo epil?ptico: consequ?ncias para as crises espont?neasFarias, Kelly Soares 21 September 2012 (has links)
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Previous issue date: 2012-09-21 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / Crises epil?pticas s?o eventos parox?sticos do sistema nervoso central (SNC) caracterizadas por uma descarga el?trica neuronal anormal, com ou sem perda de consci?ncia e com sintomas cl?nicos variados. Nas epilepsias do lobo temporal as crises tem in?cio focal, em estruturas do sistema l?mbico. Dados cl?nicos e experimentais mostram que essas regi?es apresentam morte neuronal (esclerose hipocampal), reorganiza??o sin?ptica (brotamento aberrante das fibras musgosas) e gliose reativa, sendo esses marcadores biol?gicos da zona epileptog?nica. Registros extracelulares mostram que al?m das altera??es anat?micas mencionadas acima, a zona epileptog?nica tamb?m apresenta oscila??es de alta frequ?ncia patol?gicas (pOAF). As pOAF s?o oscila??es transientes (50 100 ms de dura??o), de baixa amplitude (200 μV - 1.5 mV) e de frequ?ncias vari?veis (80 800 Hz). A rela??o entre essas oscila??es e a g?nese das crises espont?neas ainda ? desconhecida. O objetivo do presente trabalho foi avaliar os efeitos da estimula??o el?trica intracerebral (EIC) nas pOAF e frequ?ncia de crises espont?neas de animais cronicamente epil?pticos (modelo da epilepsia do lobo temporal). Atualmente, a EIC ? utilizada no tratamento de dist?rbios do movimento (e.g., doen?a de Parkinson) e em alguns casos de dor cr?nica, e experimentalmente, no tratamento das epilepsias de dif?cil controle. A hip?tese de trabalho dessa disserta??o ? de que a indu??o de depress?o de longa dura??o por EIC, ao reduzir a excitabilidade neuronal local, modular? as pOAF, bem como a frequ?ncia de crises espont?neas. Para isso, comparamos as caracter?sticas espectrais das pOAF e a frequ?ncia de crises espont?neas antes e depois de um protocolo de 12 horas de estimula??o el?trica de baixa frequ?ncia (0,2 Hz) aplicado na via perforante. De fato, esse protocolo reduziu a amplitude do potencial de a??o coletivo registrado no giro denteado (GD) do hipocampo dorsal em 45% (amplitude m?dia da primeira e da ?ltima hora de estimula??o: 7,3 ? 3,0 mV e 4,1 ? 1,5 mV, respectivamente; p<0,05; teste t). O monitoramento cont?nuo do potencial de campo local, realizado no GD e em CA3 simultaneamente, mostrou que o protocolo de estimula??o empregado foi eficaz em (i) aumentar a dura??o (64,6 ? 9,3 ms vs. 70,5 ? 11,5 ms) e reduzir (ii) a entropia (3,72 ? 0,28 vs. 3,58 ? 0,30), (iii) o ?ndice pOAF (0,20 ? 0,08 vs. 0,15 ? 0,07) e (iv) o modo espectral (237,5 ? 15,8 Hz vs. 228,7 ? 15,2 Hz) das pOAF (valores do GD, expressos como m?dia ? desvio-padr?o, para os per?odos pr? e p?s estimula??o respectivamente; p<0,05; teste t). Ainda, este protocolo reduziu significativamente a frequ?ncia de crises espont?neas (1,8 ? 0,4 vs. 1,0 ? 0,3 crises/hora; pr? e p?s estimula??o, respectivamente; p<0,05; teste t). Curiosamente, observamos um aumento na dura??o m?dia das crises espont?neas ap?s o t?rmino do protocolo (39,7 ? 6,0 vs. 51,6 ? 12,5 s; pr? e p?s estimula??o respectivamente; p<0,05; teste t). Estes resultados sugerem que a redu??o da excitabilidade neuronal, por meio de protocolos de estimula??o el?trica, altera o perfil espectral das pOAF. Esse efeito foi acompanhado de redu??o na frequ?ncia de crises espont?neas. Apesar de preliminar, o presente trabalho contribui para o refinamento de terapias baseadas em EIC para indiv?duos com epilepsia
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Revisitando o eletrocorticograma intra-operat?rio na epilepsia mesial do lobo temporal: relev?ncia das oscila??es de alta frequ?nciaSilva, Anderson Brito da 13 December 2013 (has links)
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Previous issue date: 2013-12-13 / Epilepsies are neurological disorders characterized by recurrent and spontaneous seizures
due to an abnormal electric activity in a brain network. The mesial temporal lobe epilepsy
(MTLE) is the most prevalent type of epilepsy in adulthood, and it occurs frequently
in association with hippocampal sclerosis. Unfortunately, not all patients benefit from
pharmacological treatment (drug-resistant patients), and therefore become candidates for
surgery, a procedure of high complexity and cost. Nowadays, the most common surgery is
the anterior temporal lobectomy with selective amygdalohippocampectomy, a procedure
standardized by anatomical markers. However, part of patients still present seizure after the
procedure. Then, to increase the efficiency of this kind of procedure, it is fundamental to
know the epileptic human brain in order to create new tools for auxiliary an individualized
surgery procedure.
The aim of this work was to identify and quantify the occurrence of epilepticform activity -such as interictal spikes (IS) and high frequency oscillations (HFO) - in electrocorticographic
(ECoG) signals acutely recorded during the surgery procedure in drug-resistant patients
with MTLE.
The ECoG recording (32 channels at sample rate of 1 kHz) was performed in the surface
of temporal lobe in three moments: without any cortical resection, after anterior temporal
lobectomy and after amygdalohippocampectomy (mean duration of each record: 10 min; N
= 17 patients; ethic approval #1038/03 in Research Ethic Committee of Federal University
of S?o Paulo). The occurrence of IS and HFO was quantified automatically by MATLAB
routines and validated manually. The events rate (number of events/channels) in each
recording time was correlated with seizure control outcome.
In 8 hours and 40 minutes of record, we identified 36,858 IS and 1.756 HFO. We observed
that seizure-free outcome patients had more HFO rate before the resection than non-seizure
free, however do not differentiate in relation of frequency, morphology and distribution of
IS. The HFO rate in the first record was better than IS rate on prediction of seizure-free
patients (IS: AUC = 57%, Sens = 70%, Spec = 71% vs HFO: AUC = 77%, Sens = 100%,
Spec = 70%). We observed the same for the difference of the rate of pre and post-resection
(IS: AUC = 54%, Sens = 60%, Spec = 71%; vs HFO: AUC = 84%, Sens = 100%, Spec =
80%). In this case, the algorithm identifies all seizure-free patients (N = 7) with two false
positives.
To conclude, we observed that the IS and HFO can be found in intra-operative ECoG
record, despite the anesthesia and the short time of record. The possibility to classify the
patients before any cortical resection suggest that ECoG can be important to decide the
use of adjuvant pharmacological treatment or to change for tailored resection procedure.
The mechanism responsible for this effect is still unknown, thus more studies are necessary
to clarify the processes related to it / As epilepsias s?o dist?rbios neurol?gicos caracterizados por crises espont?neas e recorrentes,
resultantes de uma atividade el?trica anormal de uma rede neural. Dentre os diferentes
tipos de epilepsia, a epilepsia mesial do lobo temporal (EMLT) ? a mais observada em
adultos, sendo frequentemente associada ? esclerose hipocampal. Infelizmente, nem todos
os pacientes s?o beneficiados pelo tratamento farmacol?gico (pacientes f?rmaco-resistentes).
Para estes sujeitos, uma alternativa ? a realiza??o de cirurgia, um procedimento de alta
complexidade e elevado custo. Atualmente, o procedimento mais realizado ? a lobectomia
temporal anterior com amigdalo-hipocampectomia seletiva, uma cirurgia padronizada por
marcos anat?micos. Entretanto, uma parcela dos pacientes continua a apresentar crises
incapacitantes ap?s o tratamento cir?rgico. Desta forma, para aumentar a efici?ncia deste
tipo de tratamento, ? fundamental a compreens?o do enc?falo humano epil?ptico com
vistas a se criar ferramentas que auxiliem na realiza??o de procedimentos individualizados.
O objetivo do presente trabalho foi identificar e quantificar a ocorr?ncia de atividade
epileptiforme - esp?culas interictais (EI) e oscila??es de alta frequ?ncia (OAF) - em registros
eletrocorticogr?ficos (ECoG) realizados durante procedimento cir?rgico em pacientes com
EMLT refrat?ria ao tratamento farmacol?gico.
Registros ECoG (32 canais a uma taxa de amostragem de 1 kHz) foram realizados na
superf?cie do lobo temporal em 3 momentos cir?rgicos: no c?rtex intacto, ap?s lobectomia
temporal anterior e ap?s amigdalo-hipocampectomia (dura??o m?dia de cada um desses
registros: 10 min; N=17 pacientes). A ocorr?ncia de EI e OAF foi quantificada automatica-mente, por meio de rotinas em MATLAB, e validadas manualmente. A taxa de ocorr?ncia
em cada um dos tempos cir?rgicos foi correlacionada com o resultado cir?rgico quanto ao
controle das crises, num seguimento de 2 anos.
De um total de 8 h e 40 min de registro, identificamos 36.858 EI e 1.756 OAF. Observamos
que os pacientes que ficaram livres de crises no p?s-operat?rio apresentaram maior quanti-dade de OAF antes da cirurgia do que aqueles que continuaram a ter crises; por?m, n?o
diferiram quanto a frequ?ncia, morfologia e distribui??o de EI. A ocorr?ncia de OAF no
registro basal apresentou melhor desempenho que as EI na previs?o do controle total das
crises no p?s-operat?rio (EI: AUC = 57%, S = 71% , E = 70% vs OAF: AUC = 77%, S =
100%, E=70%). O mesmo foi observado com a varia??o da ocorr?ncia entre os momentos
pr?- e p?s-ressec??o (EI: AUC = 54%, S = 71%, E = 60% vs OAF: AUC = 84%, S =
100%, E = 80%). Nesse caso, o classificador foi capaz de identificar todos os pacientes
livres de crises (N = 7) , apresentando apenas dois falsos positivos.
Desta forma, podemos concluir que as OAF, juntamente com as EI, podem ser encontradas
no registro ECoG intra-operat?rio, mesmo na presen?a de anest?sicos e em uma curta
sess?o de registro. Al?m disso, a observa??o de que a ocorr?ncia desses eventos no in?cio
da cirurgia permite classificar o paciente quanto ao progn?stico cir?rgico abre caminho
para aplicar o ECoG intra-operat?rio, por exemplo, na decis?o sobre o uso de tratamento
farmacol?gico adjuvante ou da convers?o para ressec??es individualizadas. No entanto,
o mecanismo respons?vel por esse efeito ainda ? desconhecido, logo novos estudos s?o
necess?rios para melhor esclarec?-lo
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