Extended magnetic resonance imaging studies on the effect of classically activated microglia transplantation on white matter regeneration following spinal cord focal injury in adult rats (original) (raw)
Related papers
Advances in Bioscience and Biotechnology, 2012
This work examines whether microglia-conditioned medium (MCM) is beneficial in stressed spinal cord cells or tissues. MCM was separated into two fractions by 50 kDa molecular cutoff centrifugation. MCM not only promoted survival of neuronal and oligodendroglial cells but effectively reduced LPS stimulation in spinal cord cultures. We further utilized the NYU weight-drop device to induce contusive spinal cord injury (SCI) in rats. Immediately after dropping the impactor from a height of 25 mm onto thoracic spinal segment, MCM was intrathecally administered. At 6 weeks post-injury, SCI rats receiving MCM > 50 kDa treatment showed significant hindlimb improvement over MCM < 50 kDa-or vehicletreated SCI rats. Consistently, more preserved nerve fibers and fewer activated microglia were found in the injured epicenter of MCM-treated SCI rats. Taken together, secreted substances, mainly > 50 kDa, of microglia was neuroprotective against spinal cord injury.
Role of microglia in spinal cord injury
Neuroscience Letters, 2019
This mini-review discusses the role of microglia after spinal cord injury. This review describes differences between the roles of microglia and monocyte derived macrophages interaction between microglia and other cell types in the injured spinal cord the impact of microglia depletion
Microglia limit lesion expansion and promote functional recovery after spinal cord injury in mice
2018
Traumatic spinal cord injury (SCI) elicits a robust intraspinal inflammatory reaction that is dominated by at least two major subpopulations of macrophages, i.e., those derived from resident microglia and another from monocytes that infiltrate the injury site from the circulation. Previously, we implicated monocyte-derived macrophages (MDMs) as effectors of acute post-injury pathology after SCI; however, it is still unclear whether microglia also contribute to lesion pathology. Assigning distinct functional roles to microglia and MDMs in vivo has been difficult because these CNS macrophage subsets are morphologically and phenotypically similar. Here, to characterize the role that microglia play in experimental models of thoracic spinal contusion or lumbar crush injury, mice were fed vehicle chow or chow laced with a CSF1R receptor antagonist, PLX5622. Feeding PLX5622 depletes microglia. In both groups, spontaneous recovery of hindlimb motor function was evaluated for up to 8 weeks p...
Frontiers in Molecular Neuroscience
Research on microglia has established the differentiation between the so-called M1 and M2 phenotypes. However, new frameworks have been proposed attempting to discern between meaningful microglia profiles. We have set up an in vitro microglial activation model by adding an injured spinal cord (SCI) lysate to microglial cultures, obtained from postnatal rats, in order to mimic the environment of the spinal cord after injury. We found that under the presence of the SCI lysate microglial cells changed their phenotype, developing less ramified but longer processes, and proliferated. The SCI lysate also led to upregulation of pro-inflammatory cytokines, such as IL-1β, IL-6, and TNF-α, downregulation of the anti-inflammatory cytokines IL-10 and IL-4, and a biphasic profile of iNOS. In addition, a latex beads phagocytosis assay revealed the SCI lysate stimulated the phagocytic capacity of microglia. Flow cytometry analysis indicated that microglial cells showed a pro-inflammatory profile i...
Journal of Neurotrauma, 2012
Spinal cord injury (SCI) in dogs is a well recognized animal model to study pathogenesis and treatment modalities of the debilitating human disease. To define the contributing role of microglial cell activation to the secondary wave following SCI, microglia from 15 dogs with SCI confirmed by imaging, gross, and histopathological examination were isolated and characterized in terms of morphology, immunophenotype, and function ex vivo by flow cytometry, allowing single cell analysis. The results were compared to region-specific findings obtained from healthy control dogs. Light microscopy revealed a significant enhancement of myelinophagia within the traumatized spinal cord of dogs who had had SCI for ‡5 days. Immunophenotypical characterization revealed increased expression of B7-1, B7-2, MHC II, CD1c, ICAM 1, CD14, CD44, and CD45 emphasizing the enhanced function of microglia as co-stimulators of T cells, in leukocyte adhesion and aggregation, and for lipid or glycolipid presentation. In addition, phagocytosis and reactive oxygen species (ROS) generation were significantly increased in dogs with spinal cord trauma. Regional differences within the spinal cord were observed by demonstrating disparities in microglial immunophenotypes in the traumatized cervical compared to the thoracolumbar spinal cord. In contrast to histopathology, microglia activation analyzed on a single cell basis did not depend upon the time span following SCI.
Severity- and Time-Dependent Activation of Microglia in Spinal Cord Injury
International Journal of Molecular Sciences
A spinal cord injury (SCI) initiates a number of cascades of biochemical reactions and intercellular interactions, the outcome of which determines the regenerative potential of the nervous tissue and opens up capacities for preserving its functions. The key elements of the above-mentioned processes are microglia. Many assumptions have been put forward, and the first evidence has been obtained, suggesting that, depending on the severity of SCI and the post-traumatic period, microglia behave differently. In this regard, we conducted a study to assess the microglia behavior in the model of mild, moderate and severe SCI in vitro for various post-traumatic periods. We reported for the first time that microglia make a significant contribution to both anti- and pro-inflammatory patterns for a prolonged period after severe SCI (60 dpi), while reduced severities of SCI do not lead to prolonged activation of microglia. The study also revealed the following trend: the greater the severity of t...
Theranostics, 2021
No curative treatment is available for any deficits induced by spinal cord injury (SCI). Following injury, microglia undergo highly diverse activation processes, including proliferation, and play a critical role on functional recovery. In a translational objective, we investigated whether a transient pharmacological reduction of microglia proliferation after injury is beneficial for functional recovery after SCI in mice and nonhuman primates. The colony stimulating factor-1 receptor (CSF1R) regulates proliferation, differentiation, and survival of microglia, we thus used an oral administration of GW2580, a CSF1R inhibitor. First, transient post-injury GW2580 administration in mice improves motor function recovery, promotes tissues preservation and/or reorganization (identified by coherent anti-stokes Raman scattering microscopy), and modulates glial reactivity. Second, post-injury GW2580-treatment in nonhuman primates reduces microglia proliferation, improves functional motor function recovery, and promotes tissue protection. Notably, three months after lesion microglia reactivity returned to baseline value. Finally, to initiate the investigation on molecular mechanisms induced by a transient post-SCI GW2580-treatment, we used microglia-specific transcriptomic analysis in mice. Notably, we detected a downregulation in the expression of inflammatory-associated genes and we identified genes that were up-regulated by SCI and further downregulated by the treatment. Thus, a transient oral GW2580 treatment post-injury may provide a promising therapeutic strategy for SCI patients and may also be extended to other central nervous system disorders displaying microglia activation.
Cells
Microglia and astrocytes play an important role in the regulation of immune responses under various pathological conditions. To detect environmental cues associated with the transformation of reactive microglia (M1) and astrocytes (A1) into their polarization states (anti-inflammatory M2 and A2 phenotypes), we studied time-dependent gene expression in naive and injured spinal cord. The relationship between astrocytes and microglia and their polarization states were studied in a rat model after Th9 compression (40g/15 min) in acute and subacute stages at the lesion site, and both cranially and caudally. The gene expression of microglia/macrophages and M1 microglia was strongly up-regulated at the lesion site and caudally one week after SCI, and attenuated after two weeks post-SCI. GFAP and S100B, and A1 astrocytes were profoundly expressed predominantly two weeks post-SCI at lesion site and cranially. Gene expression of anti-inflammatory M2a microglia (CD206, CHICHI, IL1rn, Arg-1), M...
Experimental Neurology, 2003
Recent attempts by other investigators to enhance repair processes in the spinal cord have involved the administration of X rays to spinal cord injury sites. Although some functional improvement has been reported, the underlying cellular changes within the irradiated spinal cords are not clear. Studies initiated recently in this laboratory examined the potential of X rays to modulate nonneuronal cell populations associated with an injury site in adult mammalian spinal cords. These studies revealed a unique and previously unreported radiosensitivity of the microglial cell population. Administration of X radiation to a unilateral dorsal lesion cavity in the cervical spinal cord revealed a significant decrease (approximately half) in numbers of microglia associated with the cavity. Even more unexpected were the significant decreases in microglial cells observed on the nonlesioned side of the spinal cord or in sham-operated spinal cords in irradiated rats. In contrast to reports of others, densitometric quantification of GFAP immunoreactive cells and processes indicated no differences in the astrocytic reactions associated with the lesion cavities between nonirradiated and irradiated groups in our studies. The demonstration that exposure of a spinal cord injury site to radiation modifies the responses of certain components of the glial environment to injury may offer a noninvasive approach for direct treatment of that site. Studies are in progress to determine if this altered glial environment enhances the extension of regrowing axons from a peripheral nerve graft across the interface with the irradiated lesion cavity and into the spinal cord parenchyma.