Local Hemodynamics Dictate Long-Term Dendritic Plasticity in Peri-Infarct Cortex

Mostany, Ricardo; Chowdhury, Tara G.; Johnston, David G.; Portonovo, Shiva A; Carmichael, S. Thomas; Portera‐Cailliau, Carlos

doi:10.1523/jneurosci.3908-10.2010

Cited by 114 publications

(123 citation statements)

References 49 publications

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“…These are mostly stable in the adult cortex [60,61], although they remodel in response to loss of afferent inputs or learning [62][63][64]. After stroke, there is initially a net loss of dendritic spines in peri-infarct cortex in the first week after stroke [52,65]. This occurs in regions with normal blood flow [65], indicating that this loss is due to neuronal network damage from loss of axonal connections and not due to partial ischemia in peri-infarct regions.…”

Section: Radial Stroke: Tissue Reorganizationmentioning

confidence: 99%

“…After stroke, there is initially a net loss of dendritic spines in peri-infarct cortex in the first week after stroke [52,65]. This occurs in regions with normal blood flow [65], indicating that this loss is due to neuronal network damage from loss of axonal connections and not due to partial ischemia in peri-infarct regions. After this loss of connections, peri-infarct cortex within 1 mm of the infarct in the mouse recovers synaptic connections back to baseline [65], whereas neurons in regions 1-2 mm away from the infarct gain synaptic connections compared with control [65], indicating these neurons form new connections after stroke.…”

Section: Radial Stroke: Tissue Reorganizationmentioning

confidence: 99%

“…It is important to note that animal models of stroke differ in their initiation of angiogenesis. The photothrombotic stroke model, which is used in many optogenetic studies of stroke neural repair, does not produce substantial angiogenesis [65,109]. However, other stroke models with reperfusion and the production of a periinfarct region of partial damage do induce angiogenesis [29,107,110].…”

Section: Tissue Regeneration After Strokementioning

confidence: 99%

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The 3 Rs of Stroke Biology: Radial, Relayed, and Regenerative

Carmichael

2016

Neurotherapeutics

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Stroke not only causes initial cell death, but also a limited process of repair and recovery. As an overall biological process, stroke has been most often considered from the perspective of early phases of ischemia, how these inter-relate and lead to expansion of the infarct. However, just as the biology of later stages of stroke becomes better understood, the clinical realities of stroke indicate that it is now more a chronic disease than an acute killer. As an overall biological process, it is now more important to understand how early cell death leads to the later, limited recovery so as develop an integrative view of acute to chronic stroke. This progression from death to repair involves sequential stages of primary cell death, secondary injury events, reactive tissue progenitor responses, and formation of new neuronal circuits. This progression is radial: from the tissue that suffers the infarct secondary injury signals, including free radicals and inflammatory cytokines, radiate out from the stroke core to trigger later regenerative events. Injury and repair processes occur not just in the local stroke site, but are also triggered in the connected networks of neurons that had existed in the stroke center: damage signals are relayed throughout a brain network. From these relayed, distributed damage signals, reactive astrocytosis, inflammatory processes, and the formation of new connections occur in distant brain areas. In short, emerging data in stroke cell death studies and the development of the field of stroke neural repair now indicate a continuum in time and in space of progressive events that can be considered as the 3 Rs of stroke biology: radial, relayed, and regenerative.

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Section: Radial Stroke: Tissue Reorganizationmentioning

confidence: 99%

Section: Radial Stroke: Tissue Reorganizationmentioning

confidence: 99%

Section: Tissue Regeneration After Strokementioning

confidence: 99%

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The 3 Rs of Stroke Biology: Radial, Relayed, and Regenerative

Carmichael

2016

Neurotherapeutics

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“…Intrinsic optical signal (IOS) imaging was performed to map the barrel field using contralateral stimulation of a bundle of whiskers and custom-written MATLAB routines, as described previously (Johnston et al, 2013).…”

Section: Methodsmentioning

confidence: 99%

“…Imaging was done under light isoflurane anesthesia (1-1.5%) with a custom-built two-photon microscope, using a Ti:Sapph laser (910 nm, Chameleon Ultra II, Coherent), as previously described , using ScanImage software (Pologruto et al, 2003). A preliminary imaging session at low-magnification was performed to identify potential candidates for dendritic imaging.…”

Section: Methodsmentioning

confidence: 99%

Layer 4 Pyramidal Neurons Exhibit Robust Dendritic Spine PlasticityIn Vivoafter Input Deprivation

Miquelajáuregui¹,

Sahana²,

Mostany³

et al. 2015

J. Neurosci.

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Pyramidal neurons in layers 2/3 and 5 of primary somatosensory cortex (S1) exhibit somewhat modest synaptic plasticity after whisker input deprivation. Whether neurons involved at earlier steps of sensory processing show more or less plasticity has not yet been examined. Here, we used longitudinal in vivo two-photon microscopy to investigate dendritic spine dynamics in apical tufts of GFP-expressing layer 4 (L4) pyramidal neurons of the vibrissal (barrel) S1 after unilateral whisker trimming. First, we characterize the molecular, anatomical, and electrophysiological properties of identified L4 neurons in Ebf2-Cre transgenic mice. Next, we show that input deprivation results in a substantial (ϳ50%) increase in the rate of dendritic spine loss, acutely (4-8 d) after whisker trimming. This robust synaptic plasticity in L4 suggests that primary thalamic recipient pyramidal neurons in S1 may be particularly sensitive to changes in sensory experience. Ebf2-Cre mice thus provide a useful tool for future assessment of initial steps of sensory processing in S1.

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Longitudinal in vivo two‐photon fluorescence imaging

Crowe

Ellis‐Davies

2014

J of Comparative Neurology

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Fluorescence microscopy is an essential technique for the basic sciences, especially biomedical research. Since the invention of laser scanning confocal microscopy in 1980s, that enabled imaging both fixed and living biological tissue with three-dimensional precision, high-resolution fluorescence imaging has revolutionized biological research. Confocal microscopy, by its very nature, has one fundamental limitation. Due to the confocal pinhole, deep tissue fluorescence imaging is not practical. In contrast (no pun intended), two-photon fluorescence microscopy allows, in principle, the collection of all emitted photons from fluorophores in the imaged voxel, dramatically extending our ability to see deep into living tissue. Since the development of transgenic mice with genetically encoded fluorescent protein in neocortical cells in 2000, two-photon imaging has enabled the dynamics of individual synapses to be followed for up to two years. Since the initial landmark contributions to this field in 2002, the technique has been used to understand how neuronal structure are changed by experience, learning and memory and various diseases. Here we provide a basic summary of the crucial elements that are required for such studies, and discuss many applications of longitudinal two-photon fluorescence microscopy that have appeared since 2002.

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Local Hemodynamics Dictate Long-Term Dendritic Plasticity in Peri-Infarct Cortex

Cited by 114 publications

References 49 publications

The 3 Rs of Stroke Biology: Radial, Relayed, and Regenerative

The 3 Rs of Stroke Biology: Radial, Relayed, and Regenerative

Layer 4 Pyramidal Neurons Exhibit Robust Dendritic Spine PlasticityIn Vivoafter Input Deprivation

Longitudinal in vivo two‐photon fluorescence imaging

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