From mice to mind: Strategies and progress in translating neuroregeneration

Burns, Terry C.; Verfaillie, Catherine M.

doi:10.1016/j.ejphar.2015.03.041

Cited by 16 publications

(18 citation statements)

References 131 publications

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“…Alternatively, OPCs, may also possess trophic and supportive functions in similar manner to NSCs, such as ability to modulate inflammation, secrete neuroprotective compounds, promote endogenous neurogenesis augment neuronal plasticity. 12,85 As such, OPC transplantation may mediate behavioral recovery via multiple synergistic actions of cell replacement, avoiding secondary cellular changes consequent to myelin and OPC loss, as well as potentially a plethora of other trophic mechanisms.…”

Section: Preclinical Cognitive Benefitsmentioning

confidence: 99%

Radiation-induced brain injury: low-hanging fruit for neuroregeneration

Burns

Awad

et al. 2016

FOC

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Brain radiation is a fundamental tool in neurooncology to improve local tumor control, but it leads to profound and progressive impairments in cognitive function. Increased attention to quality of life in neurooncology has accelerated efforts to understand and ameliorate radiation-induced cognitive sequelae. Such progress has coincided with a new understanding of the role of CNS progenitor cell populations in normal cognition and in their potential utility for the treatment of neurological diseases. The irradiated brain exhibits a host of biochemical and cellular derangements, including loss of endogenous neurogenesis, demyelination, and ablation of endogenous oligodendrocyte progenitor cells. These changes, in combination with a state of chronic neuroinflammation, underlie impairments in memory, attention, executive function, and acquisition of motor and language skills. Animal models of radiation-induced brain injury have demonstrated a robust capacity of both neural stem cells and oligodendrocyte progenitor cells to restore cognitive function after brain irradiation, likely through a combination of cell replacement and trophic effects. Oligodendrocyte progenitor cells exhibit a remarkable capacity to migrate, integrate, and functionally remyelinate damaged white matter tracts in a variety of preclinical models. The authors here critically address the opportunities and challenges in translating regenerative cell therapies from rodents to humans. Although valiant attempts to translate neuroprotective therapies in recent decades have almost uniformly failed, the authors make the case that harnessing human radiation-induced brain injury as a scientific tool represents a unique opportunity to both successfully translate a neuroregenerative therapy and to acquire tools to facilitate future restorative therapies for human traumatic and degenerative diseases of the central nervous system.

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Section: Preclinical Cognitive Benefitsmentioning

confidence: 99%

Radiation-induced brain injury: low-hanging fruit for neuroregeneration

Burns

Awad

et al. 2016

FOC

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“…Some potentially neuroregenerative treatments currently being studied for the treatment of traumatic spinal cord injury include chondroitinase ABC, self-assembling peptides, and rho inhibition [56]. In addition, cell-based therapies, including the use of embryonic stem cells, neural stem cells, induced pluripotent stem cells, mesenchymal stromal cells, Schwann cells, olfactory ensheathing cells, and macrophages, have shown promise in preclinical and a few clinical trials [117]. However, these trials focus on traumatic injury, and potential regenerative capacity in SCI has to be elucidated.…”

Section: Discussionmentioning

confidence: 99%

Current and emerging treatment options for spinal cord ischemia

Nardone

Pikija

Mutzenbach

et al. 2016

Drug Discovery Today

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“…may be impossible to represent effectively in any other species. In these cases, we must seek ethical and feasible ways to study them in humans, as well as identify relevant endophenotypes, biomarkers, and constituent mechanisms that are accessible in non‐human models …”

Section: Finding Routes Around Obstaclesmentioning

confidence: 99%

“…The complexity of most human diseases far exceeds what any single model (however carefully constructed or evolutionarily fortuitous) can represent . Thinking in terms of a portfolio rather than merely replacing one model with another is a way to capture more diversity without sacrificing the power of well‐developed core models, which are very good at what they do − even though they alone ca not do everything.…”

Section: Finding Routes Around Obstaclesmentioning

confidence: 99%

Animal Models in Translational Research: Rosetta Stone or Stumbling Block?

Bolker

2017

BioEssays

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Leading animal models are powerful tools for translational research, but they also present obstacles. Poorly conducted preclinical research in animals is a common cause of translational failure, but even when such research is well-designed and carefully executed, challenges remain. In particular, dominant models may bias research directions, elide essential aspects of human disease, omit important context, or subtly shift research targets. Recognizing these stumbling blocks can help us find ways to avoid them: employing a wider range of models, incorporating more realistic environmental conditions, better aligning studies between animals and patients, and focusing on human biology and therapeutic goals. Such changes are costly; but insisting it would be impractical or unrealistic to change strategies offers no way out of the current impasse. Rather, we must acknowledge the obstacles as well as the advantages presented by core models, and direct some of our investments in translational research toward getting around them.

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From mice to mind: Strategies and progress in translating neuroregeneration

Cited by 16 publications

References 131 publications

Radiation-induced brain injury: low-hanging fruit for neuroregeneration

Radiation-induced brain injury: low-hanging fruit for neuroregeneration

Current and emerging treatment options for spinal cord ischemia

Animal Models in Translational Research: Rosetta Stone or Stumbling Block?

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