Cellular and Molecular Mechanisms of Glial Scarring and Progressive Cavitation:<i>In Vivo</i>and<i>In Vitro</i>Analysis of Inflammation-Induced Secondary Injury after CNS Trauma

Fitch, Michael T.; Doller, Catherine; Combs, Colin K.; Landreth, Gary E.; Silver, Jerry

doi:10.1523/jneurosci.19-19-08182.1999

Cited by 503 publications

(366 citation statements)

References 83 publications

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“…Some have suggested that degenerating axons and their dying terminals may be a trigger for such extracellular matrix production by astrocytes (see Massey, et al, in this issue). Evidence also suggests that the inflammatory infiltration and activation associated with CNS injury is associated with production of inhibitory molecules, as CSPGs are associated with breakdown of the blood brain barrier and infiltrating macrophages present within a lesion site (Fitch, et al, 1999;Fitch and Silver, 1997a), a phenomenon that is also seen with activation of oligodendrocyte precursor cells after injury (Rhodes, et al, 2006). Pro-inflammatory molecules that activate microglial cells and macrophages can trigger astrocyte gliosis and upregulation of proteoglycans (Fitch, et al, 1999), upregulation of NG2 proteoglycan by oligodendrocyte precursor cells (Rhodes, et al, 2006), and cytokines associated with inflammation can also influence astrocyte extracellular matrix production (DiProspero et al, 1997).…”

Section: Triggers For the Production Of Inhibitory Extracellular Matrixmentioning

confidence: 99%

“…Microglial cells from the CNS and activated macrophages from the periphery both respond to trauma in the brain and spinal cord, and this inflammatory response may contribute to secondary tissue damage after the primary insult (Blight, 1994;Fitch, et al, 1999). This cascade of secondary damage, progressive cavitation, and glial scarring was demonstrated in an in vivo model of inflammation using microinjection of zymosan, a non-toxic, specific phagocytic activator of the macrophage mannose receptor and the beta-glucan site of the CR3 integrin receptor (Fitch, et al, 1999). The resulting inflammation leads to significant axotomy and increases in astrocyte cavity size, while control injections of latex microspheres do not induce this damaging inflammatory cascade.…”

Section: Triggers For the Production Of Inhibitory Extracellular Matrixmentioning

confidence: 99%

“…Astrocytes are important for neurotransmitter regulation (Schousboe and Westergaarde, 1995), ion homeostasis (Walz, 1989), blood brain barrier maintenance (Wolburg and Risau, 1995), and the production of extracellular matrix molecules destined for the basal lamina and perineuronal net (Ard et al, 1993;Bernstein et al, 1985;Canning et al, 1996;Grierson et al, 1990;Massey et al, 2006;McKeon et al, 1991;SmithThomas et al, 1994;Tom et al, 2004a). After injury, they are also the major cell type responsible for walling off areas of damage to protect the fragile brain tissue from further erosion (Fitch et al, 1999;Myer et al, 2006). The formation of a mechanically obstructive glial scar composed of astrocytes and connective tissue elements was at one time thought to explain the failure of regeneration within the CNS after injury (Windle and Chambers, 1950).…”

Section: Introductionmentioning

confidence: 99%

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CNS injury, glial scars, and inflammation: Inhibitory extracellular matrices and regeneration failure

Fitch

Silver

2008

Experimental Neurology

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877

657

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Spinal cord and brain injuries lead to complex cellular and molecular interactions within the central nervous system in an attempt to repair the initial tissue damage. Many studies have illustrated the importance of the glial cell response to injury, and the influences of inflammation and wound healing processes on the overall morbidity and permanent disability that result. The abortive attempts of neuronal regeneration after spinal cord injury are influenced by inflammatory cell activation, reactive astrogliosis and the production of both growth promoting and inhibitory extracellular molecules. Despite the historical perspective that the glial scar was a mechanical barrier to regeneration, inhibitory molecules in the forming scar and methods to overcome them have suggested molecular modification strategies to allow neuronal growth and functional regeneration. Unlike myelin associated inhibitory molecules, which remain at largely static levels before and after central nervous system trauma, inhibitory extracellular matrix molecules are dramatically upregulated during the inflammatory stages after injury providing a window of opportunity for the delivery of candidate therapeutic interventions. While high dose methylprednisolone steroid therapy alone has not proved to be the solution to this difficult clinical problem, other strategies for modulating inflammation and changing the make up of inhibitory molecules in the extracellular matrix are providing robust evidence that rehabilitation after spinal cord and brain injury has the potential to significantly change the outcome for what was once thought to be permanent disability.

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Section: Triggers For the Production Of Inhibitory Extracellular Matrixmentioning

confidence: 99%

Section: Triggers For the Production Of Inhibitory Extracellular Matrixmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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CNS injury, glial scars, and inflammation: Inhibitory extracellular matrices and regeneration failure

Fitch

Silver

2008

Experimental Neurology

Self Cite

877

657

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“…[11][12][13][14] The nontraumatic injection of the micgroglia/macrophage activator zymosan into the brain and spinal cord results in cavitation, demyelination, and axonal injury. 15,16 The molecules released by mature phagocytes, including superoxide, hydrogen peroxide, hypochlorous acid, as well as neurotoxic chemokines and cytokines may be partially responsible for axonal damage and retraction, and neuronal death. 17 The second-generation tetracycline derivative, minocycline, has been shown to be an antiinflammatory agent.…”

Section: Neuroprotection In the Setting Of Scimentioning

confidence: 99%

Setting the stage for functional repair of spinal cord injuries: a cast of thousands

2005

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Here we review mechanisms and molecules that necessitate protection and oppose axonal growth in the injured spinal cord, representing not only a cast of villains but also a company of therapeutic targets, many of which have yet to be fully exploited. We next discuss recent progress in the fields of bridging, overcoming conduction block and rehabilitation after spinal cord injury (SCI), where several treatments in each category have entered the spotlight, and some are being tested clinically. Finally, studies that combine treatments targeting different aspects of SCI are reviewed. Although experiments applying some treatments in combination have been completed, auditions for each part in the much-sought combination therapy are ongoing, and performers must demonstrate robust anatomical regeneration and/or significant return of function in animal models before being considered for a lead role.Spinal Cord (2005) 43, 134-161.

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“…They further showed in a culture model that progressive cavitation could be prevented by treatment with anti-in¯ammatory agents which inhibited macrophage in¯ammatory gene transcription. 44 Further evidence for the detrimental role of neutrophils and macrophages is that reactive oxygen species are produced during the process of phagocytosis by these cells. 45 Thus, neutrophil in¯ux in a SCI has been associated with oxidative damage of surrounding healthy tissue.…”

Section: In¯ammatory Responsesmentioning

confidence: 99%

Progress in Spinal Cord Research - A refined strategy for the International Spinal Research Trust

2000

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Achieving regeneration in the central nervous system represents one of the greatest intellectual and practical challenges in neurobiology, and yet it is an absolute requirement if spinal cord injury patients are to have any hope of recovery. The mission of the International Spinal Research Trust (ISRT), established in 1980, is to raise money speci®cally for spinal research, with a view to ending the permanence of paralysis caused by spinal cord injury. This review summarises some of the major steps forward made in recent years in understanding the mechanisms involved in spinal cord injury and where these discoveries ®t in with the ISRT's overall objectives. We review approaches aimed at (1) preventing immediate adverse reactions to injury such as neuronal death and scar formation; (2) minimising inhibitory properties of the CNS environment and maximising the growth potential of damaged neurons; (3) understanding axonal guidance systems that will be required for directed outgrowth and functional reconnection; and (4) optimising the function of surviving systems. We also discuss infrastructural' prerequisites for applying knowledge gained through spinal research to the clinical condition, including basic scienti®c issues such as developing representative animal models of spinal cord injury and sensitive quantitative methods for assessing growth and functional restoration. In addition, we point out the importance of communication. The need to share knowledge between research groups is vital for advancing our understanding of injury and repair mechanisms. Equally important is the need for communication between basic scientists and clinicians which will be essential for what is the ultimate goal of the ISRT, the development of relevant treatment strategies that will prove bene®cial to the spinal injured patient. Spinal Cord (2000) 38, 449 ± 472

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Cellular and Molecular Mechanisms of Glial Scarring and Progressive Cavitation:In VivoandIn VitroAnalysis of Inflammation-Induced Secondary Injury after CNS Trauma

Cited by 503 publications

References 83 publications

CNS injury, glial scars, and inflammation: Inhibitory extracellular matrices and regeneration failure

CNS injury, glial scars, and inflammation: Inhibitory extracellular matrices and regeneration failure

Setting the stage for functional repair of spinal cord injuries: a cast of thousands

Progress in Spinal Cord Research - A refined strategy for the International Spinal Research Trust

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