Cytokine and Growth Factor Activation In Vivo and In Vitro after Spinal Cord Injury

García, Elisa; Aguilar-Cevallos, Jorge; Silva-García, Raúl; Ibarra, Antonio

doi:10.1155/2016/9476020

Cited by 114 publications

(104 citation statements)

References 234 publications

(298 reference statements)

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“…Several mechanisms of T cell-derived harm (parts a–c ) and benefit (parts d–f ) have been proposed. a | T cells that acquire either the type 1 T helper (T H 1) or T H 17 phenotypes after CNS injury can secrete cytokines such as interleukin-17 (IL-17), IL-23 and interferon-γ(IFNγ), which have detrimental actions 126 . b | In certain circumstances, T cells can acquire detrimental auto-immune activity, skewing to a T H 1 phenotype and resulting in increased tissue injury.…”

Section: Figurementioning

confidence: 99%

How and why do T cells and their derived cytokines affect the injured and healthy brain?

2017

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The evolution of adaptive immunity provides enhanced defence against specific pathogens, as well as homeostatic immune surveillance of all tissues. Despite being ‘immune privileged’, the CNS uses the assistance of the immune system in physiological and pathological states. In this Opinion article, we discuss the influence of adaptive immunity on recovery after CNS injury and on cognitive and social brain function. We further extend a hypothesis that the pro-social effects of interferon-regulated genes were initially exploited by pathogens to increase host–host transmission, and that these genes were later recycled by the host to form part of an immune defence programme. In this way, the evolution of adaptive immunity may reflect a host–pathogen ‘arms race’.

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Section: Figurementioning

confidence: 99%

How and why do T cells and their derived cytokines affect the injured and healthy brain?

2017

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“…23,33,37,38 TNF-α acts as an effector molecule in brain development and is often involved in different signaling pathways to elicit the activation of macrophages and glial cells for neurotoxin production and to initiate the apoptosis/ death process in neurons. [39][40][41] Until now, the overall role of α α α α α α α α α α α α Figure 5 The levels of sOD, MDa, Il-4, Il-6, Il-8, Il-10, and NO in the rat brain tissue (n=10). Notes: (A) sOD; (B) MDa; (C) Il-4; (D) Il-6; (E) Il-8 and Il-10; (F) NO.…”

Section: Discussionmentioning

confidence: 99%

PEG-<em>b</em>-(PELG-<em>g</em>-PLL) nanoparticles as TNF-α nanocarriers: potential cerebral ischemia/reperfusion injury therapeutic applications

Xu¹,

Gu²,

Hu³

et al. 2017

IJN

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“…Growth factor release immediately after injury can help protect neurons from secondary injury (Garcia et al, 2016). However, the scaffolds must also enable long-term delivery of growth factor to regenerate axons during the chronic phase of injury.…”

Section: Biomaterials For Sci and Strategies To Tune The Rate Of Relementioning

confidence: 99%

Biomaterials for Local, Controlled Drug Delivery to the Injured Spinal Cord

Ziemba

Gilbert

2017

Front. Pharmacol.

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Affecting approximately 17,000 new people each year, spinal cord injury (SCI) is a devastating injury that leads to permanent paraplegia or tetraplegia. Current pharmacological approaches are limited in their ability to ameliorate this injury pathophysiology, as many are not delivered locally, for a sustained duration, or at the correct injury time point. With this review, we aim to communicate the importance of combinatorial biomaterial and pharmacological approaches that target certain aspects of the dynamically changing pathophysiology of SCI. After reviewing the pathophysiology timeline, we present experimental biomaterial approaches to provide local sustained doses of drug. In this review, we present studies using a variety of biomaterials, including hydrogels, particles, and fibers/conduits for drug delivery. Subsequently, we discuss how each may be manipulated to optimize drug release during a specific time frame following SCI. Developing polymer biomaterials that can effectively release drug to target specific aspects of SCI pathophysiology will result in more efficacious approaches leading to better regeneration and recovery following SCI.

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Cytokine and Growth Factor Activation In Vivo and In Vitro after Spinal Cord Injury

Cited by 114 publications

References 234 publications

How and why do T cells and their derived cytokines affect the injured and healthy brain?

How and why do T cells and their derived cytokines affect the injured and healthy brain?

PEG-<em>b</em>-(PELG-<em>g</em>-PLL) nanoparticles as TNF-α nanocarriers: potential cerebral ischemia/reperfusion injury therapeutic applications

Biomaterials for Local, Controlled Drug Delivery to the Injured Spinal Cord

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Cytokine and Growth Factor Activation In Vivo and In Vitro after Spinal Cord Injury

Cited by 114 publications

References 234 publications

How and why do T cells and their derived cytokines affect the injured and healthy brain?

How and why do T cells and their derived cytokines affect the injured and healthy brain?

PEG-<em>b</em>-(PELG-<em>g</em>-PLL) nanoparticles as TNF-&alpha; nanocarriers: potential cerebral ischemia/reperfusion injury therapeutic applications

Biomaterials for Local, Controlled Drug Delivery to the Injured Spinal Cord

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Resources

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PEG-<em>b</em>-(PELG-<em>g</em>-PLL) nanoparticles as TNF-α nanocarriers: potential cerebral ischemia/reperfusion injury therapeutic applications