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Removing the barriers of plasticity after experimental brain injury

Christensen, Jakob Hakon LU (2018)
Abstract
Ischemic stroke and traumatic brain injuries (TBI) are leading causes of disability and death worldwide. Both injuries result in regional cell death and disruption of local and remote functional neuronal networks, leading to loss of neurological function. Despite much effort spent on developing pharmacological therapies to reduce neuronal damage following these conditions, no neuroprotective strategies have reached clinical use. Spontaneous recovery of lost function after stroke and TBI is limited but can be enhanced by rehabilitative strategies that stimulate experience-driven brain plasticity.

In the experimental setting, exposure to multimodal stimulation by enriched environments (EE) stimulates brain plasticity and recovery... (More)
Ischemic stroke and traumatic brain injuries (TBI) are leading causes of disability and death worldwide. Both injuries result in regional cell death and disruption of local and remote functional neuronal networks, leading to loss of neurological function. Despite much effort spent on developing pharmacological therapies to reduce neuronal damage following these conditions, no neuroprotective strategies have reached clinical use. Spontaneous recovery of lost function after stroke and TBI is limited but can be enhanced by rehabilitative strategies that stimulate experience-driven brain plasticity.

In the experimental setting, exposure to multimodal stimulation by enriched environments (EE) stimulates brain plasticity and recovery following brain injuries. At the system level, we demonstrated that improvement of tactile- proprioceptive function following rehabilitation in EE was associated with enhanced functional-connectivity among distinct brain regions involved in integration of multisensory input and control of movement. Inhibition of the metabotropic glutamate receptor 5 (mGluR5) and genetic disruption of peri- neuronal nets facilitated remodeling of resting-state networks within contralesional cortical sensorimotor areas during stroke recovery. Using the EE regime, we identified several molecular barriers, which appear to impair functional recovery and plasticity in the first weeks following stroke and TBI. These included peri- lesional inflammation, parvalbumin expressing GABAergic inhibitory interneurons and aberrant mGluR5 activation.

Overall this thesis presents novel data regarding molecular and network level mechanisms of plasticity, and provide potential targets for future therapies, which may support rehabilitation of patients following matured brain injury. (Less)
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author
supervisor
opponent
  • Assistant Professor Otte, Willem M., University Medical Center Utrecht, The Netherlands
organization
publishing date
type
Thesis
publication status
published
subject
keywords
Resting-state functional connectivity, Optical imaging, Stroke, Recovery, Enriched environment, Parvalbumin, Perineuronal nets, Traumatic brain injury, Microglia.
pages
66 pages
publisher
Lund University: Faculty of Medicine
defense location
Segerfalksalen, BMC A10, Sölvegatan 17 i Lund.
defense date
2018-03-28 13:15:00
ISBN
978-91-7619-592-5
language
English
LU publication?
yes
additional info
ISSN 1652-8220 Lund University, Faculty of Medicine Doctoral Dissertation Series 2018:25
id
bcb59b98-744f-4af7-9c42-d19118a28456
date added to LUP
2018-03-05 22:57:42
date last changed
2019-11-19 13:49:34
@phdthesis{bcb59b98-744f-4af7-9c42-d19118a28456,
  abstract     = {{Ischemic stroke and traumatic brain injuries (TBI) are leading causes of disability and death worldwide. Both injuries result in regional cell death and disruption of local and remote functional neuronal networks, leading to loss of neurological function. Despite much effort spent on developing pharmacological therapies to reduce neuronal damage following these conditions, no neuroprotective strategies have reached clinical use. Spontaneous recovery of lost function after stroke and TBI is limited but can be enhanced by rehabilitative strategies that stimulate experience-driven brain plasticity.<br/><br/>In the experimental setting, exposure to multimodal stimulation by enriched environments (EE) stimulates brain plasticity and recovery following brain injuries. At the system level, we demonstrated that improvement of tactile- proprioceptive function following rehabilitation in EE was associated with enhanced functional-connectivity among distinct brain regions involved in integration of multisensory input and control of movement. Inhibition of the metabotropic glutamate receptor 5 (mGluR5) and genetic disruption of peri- neuronal nets facilitated remodeling of resting-state networks within contralesional cortical sensorimotor areas during stroke recovery. Using the EE regime, we identified several molecular barriers, which appear to impair functional recovery and plasticity in the first weeks following stroke and TBI. These included peri- lesional inflammation, parvalbumin expressing GABAergic inhibitory interneurons and aberrant mGluR5 activation.<br/><br/>Overall this thesis presents novel data regarding molecular and network level mechanisms of plasticity, and provide potential targets for future therapies, which may support rehabilitation of patients following matured brain injury.}},
  author       = {{Christensen, Jakob Hakon}},
  isbn         = {{978-91-7619-592-5}},
  keywords     = {{Resting-state functional connectivity, Optical imaging, Stroke, Recovery, Enriched environment, Parvalbumin, Perineuronal nets, Traumatic brain injury, Microglia.}},
  language     = {{eng}},
  publisher    = {{Lund University: Faculty of Medicine}},
  school       = {{Lund University}},
  title        = {{Removing the barriers of plasticity after experimental brain injury}},
  year         = {{2018}},
}