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12. Key morphological features of human pyramidal neurons.

Author

Benavides-Piccione R, Blazquez-Llorca L, Kastanauskaite A, Fernaud-Espinosa I, Tapia-González S, and DeFelipe J

Subjects
Humans, Animals, Male, Female, Mice, Adult, Dendritic Spines physiology, Dendritic Spines ultrastructure, Temporal Lobe cytology, Dendrites physiology, Middle Aged, Axons physiology, Species Specificity, Pyramidal Cells physiology
Abstract

The basic building block of the cerebral cortex, the pyramidal cell, has been shown to be characterized by a markedly different dendritic structure among layers, cortical areas, and species. Functionally, differences in the structure of their dendrites and axons are critical in determining how neurons integrate information. However, within the human cortex, these neurons have not been quantified in detail. In the present work, we performed intracellular injections of Lucifer Yellow and 3D reconstructed over 200 pyramidal neurons, including apical and basal dendritic and local axonal arbors and dendritic spines, from human occipital primary visual area and associative temporal cortex. We found that human pyramidal neurons from temporal cortex were larger, displayed more complex apical and basal structural organization, and had more spines compared to those in primary sensory cortex. Moreover, these human neocortical neurons displayed specific shared and distinct characteristics in comparison to previously published human hippocampal pyramidal neurons. Additionally, we identified distinct morphological features in human neurons that set them apart from mouse neurons. Lastly, we observed certain consistent organizational patterns shared across species. This study emphasizes the existing diversity within pyramidal cell structures across different cortical areas and species, suggesting substantial species-specific variations in their computational properties., (© The Author(s) 2024. Published by Oxford University Press.)

Published
2024
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13. Three-dimensional analysis of synaptic organization in the hippocampal CA1 field in Alzheimer's disease.

Author

Montero-Crespo M, Domínguez-Álvaro M, Alonso-Nanclares L, DeFelipe J, and Blazquez-Llorca L

Subjects
Female, Humans, Imaging, Three-Dimensional, Male, Microscopy, Electron, Scanning, Alzheimer Disease pathology, CA1 Region, Hippocampal ultrastructure, Neurons ultrastructure, Synapses ultrastructure
Abstract

Alzheimer's disease is the most common form of dementia, characterized by a persistent and progressive impairment of cognitive functions. Alzheimer's disease is typically associated with extracellular deposits of amyloid-β peptide and accumulation of abnormally phosphorylated tau protein inside neurons (amyloid-β and neurofibrillary pathologies). It has been proposed that these pathologies cause neuronal degeneration and synaptic alterations, which are thought to constitute the major neurobiological basis of cognitive dysfunction in Alzheimer's disease. The hippocampal formation is especially vulnerable in the early stages of Alzheimer's disease. However, the vast majority of electron microscopy studies have been performed in animal models. In the present study, we performed an extensive 3D study of the neuropil to investigate the synaptic organization in the stratum pyramidale and radiatum in the CA1 field of Alzheimer's disease cases with different stages of the disease, using focused ion beam/scanning electron microscopy (FIB/SEM). In cases with early stages of Alzheimer's disease, the synapse morphology looks normal and we observed no significant differences between control and Alzheimer's disease cases regarding the synaptic density, the ratio of excitatory and inhibitory synapses, or the spatial distribution of synapses. However, differences in the distribution of postsynaptic targets and synaptic shapes were found. Furthermore, a lower proportion of larger excitatory synapses in both strata were found in Alzheimer's disease cases. Individuals in late stages of the disease suffered the most severe synaptic alterations, including a decrease in synaptic density and morphological alterations of the remaining synapses. Since Alzheimer's disease cases show cortical atrophy, our data indicate a reduction in the total number (but not the density) of synapses at early stages of the disease, with this reduction being much more accentuated in subjects with late stages of Alzheimer's disease. The observed synaptic alterations may represent a structural basis for the progressive learning and memory dysfunctions seen in Alzheimer's disease cases., (© The Author(s) (2021). Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2021
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14. Three-dimensional synaptic organization of the human hippocampal CA1 field.

Author

Montero-Crespo M, Dominguez-Alvaro M, Rondon-Carrillo P, Alonso-Nanclares L, DeFelipe J, and Blazquez-Llorca L

Subjects
Adult, Aged, Aged, 80 and over, Autopsy, Cadaver, Female, Humans, Male, Middle Aged, Molecular Conformation, CA1 Region, Hippocampal cytology, CA1 Region, Hippocampal ultrastructure, Microscopy, Electron, Scanning methods
Abstract

The hippocampal CA1 field integrates a wide variety of subcortical and cortical inputs, but its synaptic organization in humans is still unknown due to the difficulties involved studying the human brain via electron microscope techniques. However, we have shown that the 3D reconstruction method using Focused Ion Beam/Scanning Electron Microscopy (FIB/SEM) can be applied to study in detail the synaptic organization of the human brain obtained from autopsies, yielding excellent results. Using this technology, 24,752 synapses were fully reconstructed in CA1, revealing that most of them were excitatory, targeting dendritic spines and displaying a macular shape, regardless of the layer examined. However, remarkable differences were observed between layers. These data constitute the first extensive description of the synaptic organization of the neuropil of the human CA1 region., Competing Interests: MM, MD, PR, LA, JD, LB No competing interests declared, (© 2020, Montero-Crespo et al.)

Published
2020
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15. Volume Electron Microscopy Study of the Relationship Between Synapses and Astrocytes in the Developing Rat Somatosensory Cortex.

Author

Kikuchi T, Gonzalez-Soriano J, Kastanauskaite A, Benavides-Piccione R, Merchan-Perez A, DeFelipe J, and Blazquez-Llorca L

Subjects
Animals, Cell Size, Imaging, Three-Dimensional, Microscopy, Electron, Scanning, Rats, Somatosensory Cortex growth & development, Astrocytes ultrastructure, Neurons ultrastructure, Somatosensory Cortex ultrastructure, Synapses ultrastructure
Abstract

In recent years, numerous studies have shown that astrocytes play an important role in neuronal processing of information. One of the most interesting findings is the existence of bidirectional interactions between neurons and astrocytes at synapses, which has given rise to the concept of "tripartite synapses" from a functional point of view. We used focused ion beam milling and scanning electron microscopy (FIB/SEM) to examine in 3D the relationship of synapses with astrocytes that were previously labeled by intracellular injections in the rat somatosensory cortex. We observed that a large number of synapses (32%) had no contact with astrocytic processes. The remaining synapses (68%) were in contact with astrocytic processes, either at the level of the synaptic cleft (44%) or with the pre- and/or post-synaptic elements (24%). Regarding synaptic morphology, larger synapses with more complex shapes were most frequently found within the population that had the synaptic cleft in contact with astrocytic processes. Furthermore, we observed that although synapses were randomly distributed in space, synapses that were free of astrocytic processes tended to form clusters. Overall, at least in the developing rat neocortex, the concept of tripartite synapse only seems to be applicable to a subset of synapses., (© The Author(s) 2020. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2020
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17. Ambient Glutamate Promotes Paroxysmal Hyperactivity in Cortical Pyramidal Neurons at Amyloid Plaques via Presynaptic mGluR1 Receptors.

Author

Ovsepian SV, Blazquez-Llorca L, Freitag SV, Rodrigues EF, and Herms J

Subjects
Animals, Benzoates pharmacology, Excitatory Amino Acid Antagonists pharmacology, Excitatory Postsynaptic Potentials physiology, Glycine analogs & derivatives, Glycine pharmacology, Mice, Inbred C57BL, Neurons drug effects, Neurons physiology, Plaque, Amyloid metabolism, Pyramidal Cells drug effects, Receptors, Presynaptic drug effects, Synaptic Transmission physiology, Excitatory Postsynaptic Potentials drug effects, Glutamic Acid metabolism, Receptors, Metabotropic Glutamate metabolism
Abstract

Synaptic dysfunctions and altered neuronal activity play major role in the pathophysiology of Alzheimer's disease (AD), with underlying mechanisms largely unknown. We report that in the prefrontal cortex of amyloid precursor protein-presenilin 1 and APP23 AD mice, baseline activity of pyramidal cells is disrupted by episodes of paroxysmal hyperactivity. Induced by spontaneous EPSC bursts, these incidents are prevalent in neurons proximal to amyloid plaques and involve enhanced activity of glutamate with metabotropic effects. Abolition of EPSC bursts by tetrodotoxin and SERCA ATPase blockers thapsigargin or cyclopiasonic acid suggests their presynaptic origin and sensitized store-released calcium. Accordingly, the rate of EPSC bursts activated by single axon stimulation is enhanced. Aggravation of the hyperactivity by blockers of excitatory amino acid transporter (±)-HIP-A and DL-TBOA together with histochemical and ultrastructural evidence for enrichment of plaque-related dystrophies with synaptic vesicles and SNARE protein SNAP-25 infer the later as hot-spots for ectopic release of glutamate. Inhibition of EPSC bursts by I/II mGluR1 blocker MCPG or selective mGluR1 antagonist LY367385 implicate metabotropic glutamatergic effects in generation of paroxysmal bursts. These findings demonstrate for the first time that at amyloid plaques, enhanced activity of nonsynaptic glutamate can promote irregular EPSC bursts with hyperactivity of pyramidal cells via mGluR1 receptors., (© The Author 2016. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published
2017
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18. Seeding and transgenic overexpression of alpha-synuclein triggers dendritic spine pathology in the neocortex.

Author

Blumenstock S, Rodrigues EF, Peters F, Blazquez-Llorca L, Schmidt F, Giese A, and Herms J

Subjects
Aging, Animals, Dendritic Spines genetics, Female, Humans, Male, Mice, Inbred C57BL, Mice, Transgenic, Neocortex metabolism, Protein Aggregation, Pathological genetics, Pyramidal Cells metabolism, Pyramidal Cells pathology, Dendritic Spines pathology, Neocortex pathology, Protein Aggregation, Pathological pathology, Up-Regulation, alpha-Synuclein genetics
Abstract

Although misfolded and aggregated α-synuclein (α-syn) is recognized in the disease progression of synucleinopathies, its role in the impairment of cortical circuitries and synaptic plasticity remains incompletely understood. We investigated how α-synuclein accumulation affects synaptic plasticity in the mouse somatosensory cortex using two distinct approaches. Long-term in vivo imaging of apical dendrites was performed in mice overexpressing wild-type human α-synuclein. Additionally, intracranial injection of preformed α-synuclein fibrils was performed to induce cortical α-syn pathology. We find that α-synuclein overexpressing mice show decreased spine density and abnormalities in spine dynamics in an age-dependent manner. We also provide evidence for the detrimental effects of seeded α-synuclein aggregates on dendritic architecture. We observed spine loss as well as dystrophic deformation of dendritic shafts in layer V pyramidal neurons. Our results provide a link to the pathophysiology underlying dementia associated with synucleinopathies and may enable the evaluation of potential drug candidates on dendritic spine pathology in vivo ., (© 2017 The Authors. Published under the terms of the CC BY 4.0 license.)

Published
2017
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19. High plasticity of axonal pathology in Alzheimer's disease mouse models.

Author

Blazquez-Llorca L, Valero-Freitag S, Rodrigues EF, Merchán-Pérez Á, Rodríguez JR, Dorostkar MM, DeFelipe J, and Herms J

Subjects
Alzheimer Disease metabolism, Amyloid beta-Protein Precursor genetics, Amyloid beta-Protein Precursor metabolism, Animals, Axons metabolism, Cell Size, Disease Models, Animal, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Humans, Imaging, Three-Dimensional, Mice, Transgenic, Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Microscopy, Fluorescence, Neuronal Plasticity, Plaque, Amyloid metabolism, Plaque, Amyloid pathology, Presenilin-1 genetics, Presenilin-1 metabolism, Somatosensory Cortex metabolism, Alzheimer Disease pathology, Axons pathology, Somatosensory Cortex pathology
Abstract

Axonal dystrophies (AxDs) are swollen and tortuous neuronal processes that are associated with extracellular depositions of amyloid β (Aβ) and have been observed to contribute to synaptic alterations occurring in Alzheimer's disease. Understanding the temporal course of this axonal pathology is of high relevance to comprehend the progression of the disease over time. We performed a long-term in vivo study (up to 210 days of two-photon imaging) with two transgenic mouse models (dE9xGFP-M and APP-PS1xGFP-M). Interestingly, AxDs were formed only in a quarter of GFP-expressing axons near Aβ-plaques, which indicates a selective vulnerability. AxDs, especially those reaching larger sizes, had long lifetimes and appeared as highly plastic structures with large variations in size and shape and axonal sprouting over time. In the case of the APP-PS1 mouse only, the formation of new long axonal segments in dystrophic axons (re-growth phenomenon) was observed. Moreover, new AxDs could appear at the same point of the axon where a previous AxD had been located before disappearance (re-formation phenomenon). In addition, we observed that most AxDs were formed and developed during the imaging period, and numerous AxDs had already disappeared by the end of this time. This work is the first in vivo study analyzing quantitatively the high plasticity of the axonal pathology around Aβ plaques. We hypothesized that a therapeutically early prevention of Aβ plaque formation or their growth might halt disease progression and promote functional axon regeneration and the recovery of neural circuits.

Published
2017
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20. Spatial distribution of neurons innervated by chandelier cells.

Author

Blazquez-Llorca L, Woodruff A, Inan M, Anderson SA, Yuste R, DeFelipe J, and Merchan-Perez A

Subjects
Animals, Hippocampus cytology, Mice, Axons physiology, Dendrites physiology, Neocortex cytology, Neurons cytology, Pyramidal Cells cytology, Synapses physiology
Abstract

Chandelier (or axo-axonic) cells are a distinct group of GABAergic interneurons that innervate the axon initial segments of pyramidal cells and are thus thought to have an important role in controlling the activity of cortical circuits. To examine the circuit connectivity of chandelier cells (ChCs), we made use of a genetic targeting strategy to label neocortical ChCs in upper layers of juvenile mouse neocortex. We filled individual ChCs with biocytin in living brain slices and reconstructed their axonal arbors from serial semi-thin sections. We also reconstructed the cell somata of pyramidal neurons that were located inside the ChC axonal trees and determined the percentage of pyramidal neurons whose axon initial segments were innervated by ChC terminals. We found that the total percentage of pyramidal neurons that were innervated by a single labeled ChC was 18-22 %. Sholl analysis showed that this percentage peaked at 22-35 % for distances between 30 and 60 µm from the ChC soma, decreasing to lower percentages with increasing distances. We also studied the three-dimensional spatial distribution of the innervated neurons inside the ChC axonal arbor using spatial statistical analysis tools. We found that innervated pyramidal neurons are not distributed at random, but show a clustered distribution, with pockets where almost all cells are innervated and other regions within the ChC axonal tree that receive little or no innervation. Thus, individual ChCs may exert a strong, widespread influence on their local pyramidal neighbors in a spatially heterogeneous fashion.

Published
2015
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21. Analyzing dendritic spine pathology in Alzheimer's disease: problems and opportunities.

Author

Dorostkar MM, Zou C, Blazquez-Llorca L, and Herms J

Subjects
Alzheimer Disease physiopathology, Amyloid metabolism, Animals, Brain pathology, Brain physiopathology, Dendritic Spines physiology, Humans, Alzheimer Disease pathology, Dendritic Spines pathology
Abstract

Synaptic failure is an immediate cause of cognitive decline and memory dysfunction in Alzheimer's disease. Dendritic spines are specialized structures on neuronal processes, on which excitatory synaptic contacts take place and the loss of dendritic spines directly correlates with the loss of synaptic function. Dendritic spines are readily accessible for both in vitro and in vivo experiments and have, therefore, been studied in great detail in Alzheimer's disease mouse models. To date, a large number of different mechanisms have been proposed to cause dendritic spine dysfunction and loss in Alzheimer's disease. For instance, amyloid beta fibrils, diffusible oligomers or the intracellular accumulation of amyloid beta have been found to alter the function and structure of dendritic spines by distinct mechanisms. Furthermore, tau hyperphosphorylation and microglia activation, which are thought to be consequences of amyloidosis in Alzheimer's disease, may also contribute to spine loss. Lastly, genetic and therapeutic interventions employed to model the disease and elucidate its pathogenetic mechanisms in experimental animals may cause alterations of dendritic spines on their own. However, to date none of these mechanisms have been translated into successful therapeutic approaches for the human disease. Here, we critically review the most intensely studied mechanisms of spine loss in Alzheimer's disease as well as the possible pitfalls inherent in the animal models of such a complex neurodegenerative disorder.

Published
2015
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22. Intraneuronal APP and extracellular Aβ independently cause dendritic spine pathology in transgenic mouse models of Alzheimer's disease.

Author

Zou C, Montagna E, Shi Y, Peters F, Blazquez-Llorca L, Shi S, Filser S, Dorostkar MM, and Herms J

Subjects
Alzheimer Disease genetics, Amyloid beta-Protein Precursor genetics, Animals, Dendritic Spines metabolism, Disease Models, Animal, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Humans, Mice, Mice, Inbred C57BL, Mice, Transgenic, Presenilin-1 genetics, Statistics, Nonparametric, Alzheimer Disease pathology, Amyloid beta-Protein Precursor metabolism, Dendritic Spines pathology, Mutation genetics, Neurons pathology, Presenilin-1 metabolism
Abstract

Alzheimer's disease (AD) is thought to be caused by accumulation of amyloid-β protein (Aβ), which is a cleavage product of amyloid precursor protein (APP). Transgenic mice overexpressing APP have been used to recapitulate amyloid-β pathology. Among them, APP23 and APPswe/PS1deltaE9 (deltaE9) mice are extensively studied. APP23 mice express APP with Swedish mutation and develop amyloid plaques late in their life, while cognitive deficits are observed in young age. In contrast, deltaE9 mice with mutant APP and mutant presenilin-1 develop amyloid plaques early but show typical cognitive deficits in old age. To unveil the reasons for different progressions of cognitive decline in these commonly used mouse models, we analyzed the number and turnover of dendritic spines as important structural correlates for learning and memory. Chronic in vivo two-photon imaging in apical tufts of layer V pyramidal neurons revealed a decreased spine density in 4-5-month-old APP23 mice. In age-matched deltaE9 mice, in contrast, spine loss was only observed on cortical dendrites that were in close proximity to amyloid plaques. In both cases, the reduced spine density was caused by decreased spine formation. Interestingly, the patterns of alterations in spine morphology differed between these two transgenic mouse models. Moreover, in APP23 mice, APP was found to accumulate intracellularly and its content was inversely correlated with the absolute spine density and the relative number of mushroom spines. Collectively, our results suggest that different pathological mechanisms, namely an intracellular accumulation of APP or extracellular amyloid plaques, may lead to spine abnormalities in young adult APP23 and deltaE9 mice, respectively. These distinct features, which may represent very different mechanisms of synaptic failure in AD, have to be taken into consideration when translating results from animal studies to the human disease.

Published
2015
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23. Pharmacological inhibition of BACE1 impairs synaptic plasticity and cognitive functions.

Author

Filser S, Ovsepian SV, Masana M, Blazquez-Llorca L, Brandt Elvang A, Volbracht C, Müller MB, Jung CK, and Herms J

Subjects
Amyloid Precursor Protein Secretases genetics, Amyloid beta-Peptides metabolism, Animals, Aspartic Acid Endopeptidases genetics, Brain anatomy & histology, Brain drug effects, Cognitive Dysfunction chemically induced, Dendritic Spines drug effects, Dose-Response Relationship, Drug, Enzyme Inhibitors chemistry, Enzyme Inhibitors pharmacology, Exploratory Behavior drug effects, Humans, Maze Learning drug effects, Mice, Mice, Inbred C57BL, Mice, Transgenic, Peptide Fragments metabolism, Pyramidal Cells drug effects, Pyramidal Cells physiology, Pyrimidines chemistry, Pyrimidines pharmacology, Pyrimidinones pharmacology, Synaptic Potentials drug effects, Thiazines chemistry, Thiazines pharmacology, Thiophenes pharmacology, Time Factors, Amyloid Precursor Protein Secretases deficiency, Aspartic Acid Endopeptidases deficiency, Brain metabolism, Cognition physiology, Cognitive Dysfunction metabolism, Dendritic Spines metabolism, Synaptic Potentials physiology
Abstract

Background: BACE1 (beta site amyloid precursor protein cleaving enzyme 1) is the rate limiting protease in amyloid β production, hence a promising drug target for the treatment of Alzheimer's disease. Inhibition of BACE1, as the major β-secretase in vivo with multiple substrates, however is likely to have mechanism-based adverse effects. We explored the impact of long-term pharmacological inhibition of BACE1 on dendritic spine dynamics, synaptic functions, and cognitive performance of adult mice., Methods: Sandwich enzyme-linked immunosorbent assay was used to assess Aβ40 levels in brain and plasma after oral administration of BACE1 inhibitors SCH1682496 or LY2811376. In vivo two-photon microscopy of the somatosensory cortex was performed to monitor structural dynamics of dendritic spines while synaptic functions and plasticity were measured via electrophysiological recordings of excitatory postsynaptic currents and hippocampal long-term potentiation in brain slices. Finally, behavioral tests were performed to analyze the impact of pharmacological inhibition of BACE1 on cognitive performance., Results: Dose-dependent decrease of Aβ40 levels in vivo confirmed suppression of BACE1 activity by both inhibitors. Prolonged treatment caused a reduction in spine formation of layer V pyramidal neurons, which recovered after withdrawal of inhibitors. Congruently, the rate of spontaneous and miniature excitatory postsynaptic currents in pyramidal neurons and hippocampal long-term potentiation were reduced in animals treated with BACE1 inhibitors. These effects were not detected in Bace1(-/-) mice treated with SCH1682496, confirming BACE1 as the pharmacological target. Described structural and functional changes were associated with cognitive deficits as revealed in behavioral tests., Conclusions: Our findings indicate important functions to BACE1 in structural and functional synaptic plasticity in the mature brain, with implications for cognition., (Copyright © 2015 Society of Biological Psychiatry. Published by Elsevier Inc. All rights reserved.)

Published
2015
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24. Fibrillar amyloid plaque formation precedes microglial activation.

Author

Jung CK, Keppler K, Steinbach S, Blazquez-Llorca L, and Herms J

Subjects
Animals, Brain metabolism, Brain pathology, CX3C Chemokine Receptor 1, Cells, Cultured, Female, Humans, Immunoenzyme Techniques, Male, Mice, Mice, Transgenic, Microglia metabolism, Plaque, Amyloid etiology, Alzheimer Disease complications, Amyloid beta-Protein Precursor physiology, Disease Models, Animal, Microglia pathology, Plaque, Amyloid pathology, Presenilin-1 physiology, Receptors, Chemokine physiology
Abstract

In Alzheimer's disease (AD), hallmark β-amyloid deposits are characterized by the presence of activated microglia around them. Despite an extensive characterization of the relation of amyloid plaques with microglia, little is known about the initiation of this interaction. In this study, the detailed investigation of very small plaques in brain slices in AD transgenic mice of the line APP-PS1(dE9) revealed different levels of microglia recruitment. Analysing plaques with a diameter of up to 10 μm we find that only the half are associated with clear morphologically activated microglia. Utilizing in vivo imaging of new appearing amyloid plaques in double-transgenic APP-PS1(dE9)xCX3CR1+/- mice further characterized the dynamic of morphological microglia activation. We observed no correlation of morphological microglia activation and plaque volume or plaque lifetime. Taken together, our results demonstrate a very prominent variation in size as well as in lifetime of new plaques relative to the state of microglia reaction. These observations might question the existing view that amyloid deposits by themselves are sufficient to attract and activate microglia in vivo.

Published
2015
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