Your search keyword '"Network dysfunction"' showing total 5 results

1. Early altered directionality of resting brain network state transitions in the TgF344-AD rat model of Alzheimer's disease.

Author

De Waegenaere, Sam, van den Berg, Monica, Keliris, Georgios A., Adhikari, Mohit H., and Verhoye, Marleen

Subjects

ALZHEIMER'S disease, LARGE-scale brain networks, ANIMAL disease models, NEURODEGENERATION, DISEASE progression, RATS

Abstract

Introduction: Alzheimer's disease (AD) is a progressive neurodegenerative disease resulting in memory loss and cognitive decline. Synaptic dysfunction is an early hallmark of the disease whose effects on whole-brain functional architecture can be identified using resting-state functionalMRI (rsfMRI). Insights into mechanisms of early, whole-brain network alterations can help our understanding of the functional impact of AD's pathophysiology. Methods: Here, we obtained rsfMRI data in the TgF344-AD rat model at the pre- and early-plaque stages. This model recapitulates the major pathological and behavioral hallmarks of AD. We used co-activation pattern (CAP) analysis to investigate if and how the dynamic organization of intrinsic brain functional networks states, undetectable by earliermethods, is altered at these early stages. Results: We identified and characterized six intrinsic brain states as CAPs, their spatial and temporal features, and the transitions between the different states. At the pre-plaque stage, the TgF344-AD rats showed reduced co-activation of hub regions in the CAPs corresponding to the default mode-like and lateral cortical network. Default mode-like network activity segregated into two distinct brain states, with one state characterized by high co-activation of the basal forebrain. This basal forebrain co-activation was reduced in TgF344-AD animals mainly at the pre-plaque stage. Brain state transition probabilities were altered at the pre-plaque stage between states involving the defaultmode-like network, lateral cortical network, and basal forebrain regions. Additionally, while the directionality preference in the network-state transitions observed in the wild-type animals at the pre-plaque stage had diminished at the early-plaque stage, TgF344-AD animals continued to show directionality preference at both stages. Discussion: Our study enhances the understanding of intrinsic brain state dynamics and how they are impacted at the early stages of AD, providing a nuanced characterization of the early, functional impact of the disease's neurodegenerative process. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cortical Circuit Dysfunction as a Potential Driver of Amyotrophic Lateral Sclerosis.

Author

Brunet, Aurore, Stuart-Lopez, Geoffrey, Burg, Thibaut, Scekic-Zahirovic, Jelena, and Rouaux, Caroline

Subjects

AMYOTROPHIC lateral sclerosis, TRANSCRANIAL magnetic stimulation, DELAYED onset of disease, CEREBRAL cortex, ANIMAL disease models, NEURODEGENERATION

Abstract

Amyotrophic lateral sclerosis (ALS) is a devastating neurodegenerative disease that affects selected cortical and spinal neuronal populations, leading to progressive paralysis and death. A growing body of evidences suggests that the disease may originate in the cerebral cortex and propagate in a corticofugal manner. In particular, transcranial magnetic stimulation studies revealed that ALS patients present with early cortical hyperexcitability arising from a combination of increased excitability and decreased inhibition. Here, we discuss the possibility that initial cortical circuit dysfunction might act as the main driver of ALS onset and progression, and review recent functional, imaging and transcriptomic studies conducted on ALS patients, along with electrophysiological, pathological and transcriptomic studies on animal and cellular models of the disease, in order to evaluate the potential cellular and molecular origins of cortical hyperexcitability in ALS. [ABSTRACT FROM AUTHOR]

Published

2020

3. Neuronal levels and sequence of tau modulate the power of brain rhythms.

Author

Das, Melanie, Maeda, Sumihiro, Hu, Bozhong, Yu, Gui-Qiu, Guo, Weikun, Lopez, Isabel, Yu, Xinxing, Tai, Chao, Wang, Xin, and Mucke, Lennart

Subjects

*BRAIN waves, *TAU proteins, *AMINO acid sequence, *BIOLOGICAL neural networks, *NEURODEGENERATION

Abstract

Neural network dysfunction may contribute to functional decline and disease progression in neurodegenerative disorders. Diverse lines of evidence suggest that neuronal accumulation of tau promotes network dysfunction and cognitive decline. The A152T-variant of human tau (hTau-A152T) increases the risk of Alzheimer's disease (AD) and several other tauopathies. When overexpressed in neurons of transgenic mice, it causes age-dependent neuronal loss and cognitive decline, as well as non-convulsive epileptic activity, which is also seen in patients with AD. Using intracranial EEG recordings with electrodes implanted over the parietal cortex, we demonstrate that hTau-A152T increases the power of brain oscillations in the 0.5–6 Hz range more than wildtype human tau in transgenic lines with comparable levels of human tau protein in brain, and that genetic ablation of endogenous tau in Mapt −/− mice decreases the power of these oscillations as compared to wildtype controls. Suppression of hTau-A152T production in doxycycline-regulatable transgenic mice reversed their abnormal network activity. Treatment of hTau-A152T mice with the antiepileptic drug levetiracetam also rapidly and persistently reversed their brain dysrhythmia and network hypersynchrony. These findings suggest that both the level and the sequence of tau modulate the power of specific brain oscillations. The potential of EEG spectral changes as a biomarker deserves to be explored in clinical trials of tau-lowering therapeutics. Our results also suggest that levetiracetam treatment is able to counteract tau-dependent neural network dysfunction. Tau reduction and levetiracetam treatment may be of benefit in AD and other conditions associated with brain dysrhythmias and network hypersynchrony. [ABSTRACT FROM AUTHOR]

Published

2018

4. An unbalanced synaptic transmission: Cause or consequence of the amyloid oligomers neurotoxicity?

Author

Giovanni Bellomo, Gabriele Ruffolo, Cinzia Costa, Alfredo Megaro, Eleonora Palma, Miriam Sciaccaluga, and Michele Romoli

Subjects

Amyloid, Aβ oligomers, QH301-705.5, Amyloidogenic Proteins, Hyperexcitability, Review, Neurotransmission, Inhibitory postsynaptic potential, Synaptic Transmission, Catalysis, Synaptic plasticity, Inorganic Chemistry, Calcium homeostasis, Excitatory/inhibitory unbalance, Alzheimer Disease, neurotoxicity, medicine, Animals, Humans, network dysfunction, Biology (General), Physical and Theoretical Chemistry, QD1-999, Molecular Biology, Spectroscopy, Amyloid beta-Peptides, Chemistry, Organic Chemistry, Neurodegeneration, Neurotoxicity, General Medicine, medicine.disease, Peptide Fragments, Computer Science Applications, Synapses, Excitatory postsynaptic potential, Alzheimer's disease, Protein Multimerization, Neuroscience

Abstract

Amyloid-β (Aβ) 1-40 and 1-42 peptides are key mediators of synaptic and cognitive dysfunction in Alzheimer’s disease (AD). Whereas in AD, Aβ is found to act as a pro-epileptogenic factor even before plaque formation, amyloid pathology has been detected among patients with epilepsy with increased risk of developing AD. Among Aβ aggregated species, soluble oligomers are suggested to be responsible for most of Aβ’s toxic effects. Aβ oligomers exert extracellular and intracellular toxicity through different mechanisms, including interaction with membrane receptors and the formation of ion-permeable channels in cellular membranes. These damages, linked to an unbalance between excitatory and inhibitory neurotransmission, often result in neuronal hyperexcitability and neural circuit dysfunction, which in turn increase Aβ deposition and facilitate neurodegeneration, resulting in an Aβ-driven vicious loop. In this review, we summarize the most representative literature on the effects that oligomeric Aβ induces on synaptic dysfunction and network disorganization.

Published

2021

5. Astrocytes in Alzheimer's Disease: Emerging Roles in Calcium Dysregulation and Synaptic Plasticity.

Author

Vincent, Adele J., Gasperini, Robert, Foa, Lisa, and Small, David H.

Subjects

*ASTROCYTES, *ALZHEIMER'S disease, *CALCIUM, *NEUROPLASTICITY, *BIOLOGICAL neural networks

Abstract

Alzheimer's disease (AD) is caused by the accumulation of amyloid-β (Aβ), which induces progressive decline in learning, memory, and other cognitive functions. Aβ is a neurotoxic protein that disrupts calcium signaling in neurons and alters synaptic plasticity. These effects lead to loss of synapses, neural network dysfunction, and inactivation of neuronal signaling. However, the precise mechanism by which Aβ causes neurodegeneration is still not clear, despite decades of intensive research. The role of astrocytes in early cognitive decline is a major component of disease pathology that has been poorly understood. Recent research suggests that astrocytes are not simply passive support cells for neurons, but are active participants in neural information processing in the brain. Aβ can disrupt astrocytic calcium signaling and gliotransmitter release, processes that are vital for astrocyte-neuron communication. Therefore, astrocyte dysfunction may contribute to the earliest neuronal deficits in AD. Here we discuss emerging concepts in glial biology and the implications of astrocyte dysfunction on neurodegeneration in AD. [ABSTRACT FROM AUTHOR]

Published

2010