Time course images of cellular injury and recovery in murine brain with high-resolution GRIN lens system

Pernici, Chelsea D.; Kemp, Benjamin S.; Murray, Teresa A.

doi:10.1038/s41598-019-44174-7

Cited by 18 publications

(22 citation statements)

References 65 publications

(94 reference statements)

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“…In the same study, we further visualized their rapid induction in an mTBI mouse model, where the usage of Thy1-YFP transgenic mice was the key to clearly visualize such axonal change (Gu et al, 2017 ). Importantly, consistent with our results, there are several recent studies showing rather rapid induction of axonal varicosities in vivo in different types of mTBI mouse models (Marion et al, 2018 ; Vascak et al, 2018 ; Ziogas and Koliatsos, 2018 ; Pernici et al, 2019 ; Weber et al, 2019 ). Therefore, rapid and reversible formation of axonal varicosities in CNS neuron mechanosensation is likely a new form of neural plasticity that is related to mechanical injury.…”

Section: Introductionsupporting

confidence: 93%

“…Collectively, this experimental result confirmed that axonal varicosities indeed rapidly form upon mechanical impact in vivo in the mouse model of repetitive mTBI, suggesting that at least some axonal varicosities were induced by the primary injury in mTBI. Since 2018, several groups independently reported that axonal varicosities were induced from a few hours to 2 days after impact in the brain of different mTBI mouse models (Marion et al, 2018;Ziogas and Koliatsos, 2018;Pernici et al, 2019;Weber et al, 2019), consistent with the findings using rcTBI.…”

Section: Axonal Varicosities Induced By Mechanical Impact In Vivosupporting

confidence: 70%

“…By combining the FPI model and in vivo imaging using highresolution gradient index lens technology, the Murray group was able to examine axonal changes in the same mouse and visualized axonal morphology from external capsule in both preinjury and post-injury stages for up to 60 days after injury. They found axonal varicosities and undulated axons 1 h post injury (Pernici et al, 2019(Pernici et al, , 2020. Administration of minocycline to reduce microglia activation for three days starting 1 or 72 h after injury inhibited axonal varicosity formation or promoted axon recovery, respectively (Pernici et al, 2020).…”

Section: Axonal Varicosities Induced By Mechanical Impact In Vivomentioning

confidence: 99%

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Rapid and Reversible Development of Axonal Varicosities: A New Form of Neural Plasticity

2021

Front. Mol. Neurosci.

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Axonal varicosities are enlarged, heterogeneous structures along axonal shafts, profoundly affecting axonal conduction and synaptic transmission. They represent a key pathological feature believed to develop via slow accumulation of axonal damage that occurs during irreversible degeneration, for example in mild traumatic brain injury (mTBI), Alzheimer's and Parkinson's diseases, and multiple sclerosis. Here this review first discusses recent in vitro results showing that axonal varicosities can be rapidly and reversibly induced by mechanical stress in cultured primary neurons from the central nervous system (CNS). This notion is further supported by in vivo studies revealing the induction of axonal varicosities across various brain regions in different mTBI mouse models, as a prominent feature of axonal pathology. Limited progress in understanding intrinsic and extrinsic regulatory mechanisms of axonal varicosity induction and development is further highlighted. Rapid and reversible formation of axonal varicosities likely plays a key role in CNS neuron mechanosensation and is a new form of neural plasticity. Future investigation in this emerging research field may reveal how to reverse axonal injury, contributing to the development of new strategies for treating brain injuries and related neurodegenerative diseases.

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Section: Introductionsupporting

confidence: 93%

Section: Axonal Varicosities Induced By Mechanical Impact In Vivosupporting

confidence: 70%

Section: Axonal Varicosities Induced By Mechanical Impact In Vivomentioning

confidence: 99%

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Rapid and Reversible Development of Axonal Varicosities: A New Form of Neural Plasticity

2021

Front. Mol. Neurosci.

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“…Images were scanned in three dimensions with x- and y-dimensions of 248 μm (1024 × 1024-pixel resolution), with z-steps of 2 μm (z stack) to produce z stacks of 36 and 46 μm to ensure that all cells were captured within the volume. Pixel dwell time was set to 2 μL with pixel averaging of 5/scan to acquire z stack images [ 17 , 18 ].…”

Section: Methodsmentioning

confidence: 99%

Cellular Analysis and Chemotherapeutic Potential of a Bi-Functionalized Halloysite Nanotube

et al. 2020

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The surface of halloysite nanotubes (HNTs) was bifunctionalized with two ligands—folic acid and a fluorochrome. In tandem, this combination should selectively target cancer cells and provide a means for imaging the nanoparticle. Modified bi-functionalized HNTs (bi-HNTs) were then doped with the anti-cancer drug methotrexate. bi-HNTs were characterized and subjected to in vitro tests to assess cellular growth and changes in cellular behavior in three cell lines—colon cancer, osteosarcoma, and a pre-osteoblast cell line (MC3T3-E1). Cell viability, proliferation, and cell uptake efficiency were assessed. The bi-HNTs showed cytocompatibility at a wide range of concentrations. Compared with regular-sized HNTs, reduced HNTs (~6 microns) were taken up by cells in more significant amounts, but increased cytotoxicity lead to apoptosis. Multi-photon images confirmed the intracellular location of bi-HNTs, and the method of cell entry was mainly through caveolae-mediated endocytosis. The bi-HNTs showed a high drug loading efficiency with methotrexate and a prolonged period of release. Most importantly, bi-HNTs were designed as a drug carrier to target cancer cells specifically, and imaging data shows that non-cancerous cells were unaffected after exposure to MTX-doped bi-HNTs. All data provide support for our nanoparticle design as a mechanism to selectively target cancer cells and significantly reduce the side-effects caused by off-targeting of anti-cancer drugs.

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“…The majority of experimental studies using a number of different controlled brain injuries in rodents focused on the very early period after TBI, in particular the cellular, inflammatory and molecular mechanisms that orchestrate beneficial shielding of non-injured tissue and repair, but also pro-inflammatory secondary damage [35][36][37] . In contrast to the substantial advance in the understanding of early post-TBI events, long-lasting, protracted changes of behavior are less well studied.…”

mentioning

confidence: 99%

Low brain endocannabinoids associated with persistent non-goal directed nighttime hyperactivity after traumatic brain injury in mice

Vogel

Wilken-Schmitz

Hummel

et al. 2020

Sci Rep

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Traumatic brain injury (TBI) is a frequent cause of chronic headache, fatigue, insomnia, hyperactivity, memory deficits, irritability and posttraumatic stress disorder. Recent evidence suggests beneficial effects of pro-cannabinoid treatments. We assessed in mice levels of endocannabinoids in association with the occurrence and persistence of comparable sequelae after controlled cortical impact in mice using a set of long-term behavioral observations in IntelliCages, motor and nociception tests in two sequential cohorts of TBI/sham mice. TBI mice maintained lower body weights, and they had persistent low levels of brain ethanolamide endocannabinoids (eCBs: AEA, OEA, PEA) in perilesional and subcortical ipsilateral brain tissue (6 months), but rapidly recovered motor functions (within days), and average nociceptive responses were within normal limits, albeit with high variability, ranging from loss of thermal sensation to hypersensitivity. TBI mice showed persistent non-goal directed nighttime hyperactivity, i.e. they visited rewarding and non-rewarding operant corners with high frequency and random success. On successful visits, they made more licks than sham mice resulting in net over-licking. The lower the eCBs the stronger was the hyperactivity. In reward-based learning and reversal learning tasks, TBI mice were not inferior to sham mice, but avoidance memory was less stable. Hence, the major late behavioral TBI phenotype was non-goal directed nighttime hyperactivity and "over-licking" in association with low ipsilateral brain eCBs. The behavioral phenotype would agree with a "post-TBI hyperactivity disorder". The association with persistently low eCBs in perilesional and subcortical regions suggests that eCB deficiency contribute to the post-TBI psychopathology.

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Time course images of cellular injury and recovery in murine brain with high-resolution GRIN lens system

Cited by 18 publications

References 65 publications

Rapid and Reversible Development of Axonal Varicosities: A New Form of Neural Plasticity

Rapid and Reversible Development of Axonal Varicosities: A New Form of Neural Plasticity

Cellular Analysis and Chemotherapeutic Potential of a Bi-Functionalized Halloysite Nanotube

Low brain endocannabinoids associated with persistent non-goal directed nighttime hyperactivity after traumatic brain injury in mice

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