Harnessing neuroplasticity for clinical applications

Cramer, Steven C.; Sur, Mriganka; Dobkin, Bruce H.; O'Brien, C.; Sanger, Terence D.; Trojanowski, John Q.; Rumsey, Judith M.; Hicks, Ramona; Cameron, Judy L.; Chen, Daofen; Chen, Wen G.; Cohen, Leonardo G.; deCharms, Christopher; Duffy, Charles J.; Eden, Guinevere F.; Fetz, Eberhard E.; Filart, Rosemarie; Freund, Michelle; Grant, Steven; Haber, Suzanne N.; Kalivas, Peter W.; Kolb, Bryan; Kramer, Arthur F.; Lynch, Minda; Mayberg, Helen S.; McQuillen, Patrick S.; Nitkin, Ralph; Pascual‐Leone, Álvaro; Reuter‐Lorenz, Patricia A.; Schiff, Nicholas D.; Sharma, Anu; Shekim, Lana; Stryker, Michael P.; Sullivan, Edith V.; Vinogradov, Sophia

doi:10.1093/brain/awr039

Cited by 916 publications

(678 citation statements)

References 223 publications

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“…It will be important to determine the longer-term impact of exercise as well as outcomes following longer and more frequent training periods. As is the case for many interventions focused on brain repair, 47 we acknowledge that our sample size was relatively small. We do note, however, that our sample size and/or participation rate are consistent with prior exercise trials in children.…”

Section: Neurooncologymentioning

confidence: 99%

Exercise training for neural recovery in a restricted sample of pediatric brain tumor survivors: a controlled clinical trial with crossover of training versus no training

Riggs

Piscione

Laughlin

et al. 2016

NEUONC

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Background. Exercise promotes repair processes in the mouse brain and improves cognition in both mice and humans. It is not known whether these benefits translate to human brain injury, particularly the significant injury observed in children treated for brain tumors. Methods. We conducted a clinical trial with crossover of exercise training versus no training in a restricted sample of children treated with radiation for brain tumors. The primary outcome was change in brain structure using MRI measures of white matter (ie, fractional anisotropy [FA]) and hippocampal volume [mm 3 ]). The secondary outcome was change in reaction time (RT)/accuracy across tests of attention, processing speed, and short-term memory. Linear mixed modeling was used to test the effects of time, training, training setting, and carryover. Results. Twenty-eight participants completed training in either a group (n=16) or a combined group/home (n=12) setting. Training resulted in increased white matter FA (Δ=0.05, P<.001). A carryover effect was observed for participants ~12 weeks after training (Δ=0.05, P<.001). Training effects were observed for hippocampal volume (Δ=130.98mm 3 ; P=.001) and mean RT (Δ=-457.04ms, P=0.36) but only in the group setting. Related carryover effects for hippocampal volume (Δ=222.81mm 3 , P=.001), and RT (Δ=-814.90ms, P=.005) were also observed. Decreased RT was predicted by increased FA (R=-0.62, P=.01). There were no changes in accuracy. Conclusions. Exercise training is an effective means for promoting white matter and hippocampal recovery and improving reaction time in children treated with cranial radiation for brain tumors. Key wordsbrain recovery | cranial radiation | exercise | neuroplasticity | pediatric brain tumor

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Section: Neurooncologymentioning

confidence: 99%

Exercise training for neural recovery in a restricted sample of pediatric brain tumor survivors: a controlled clinical trial with crossover of training versus no training

Riggs

Piscione

Laughlin

et al. 2016

NEUONC

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“…To test for hemispheric laterality, models were divided into a Left-sided (Models 1, 3, 4, 5, 6, 7, 9, 10, 11) and a Right-sided Family (Models 2,8,12,13,14,15,16,17,18). To test for directionality of working memory information three Families where created for each experimental condition, Forward (Models 3,5,10,14,16,17), Backwards (Models 4,6,9,13,15,18) and Lateral (Models 1,2,7,8,11,12). All models were included in the BMS procedure, both when comparing individual models and model Families.…”

Section: Model Comparisonmentioning

confidence: 99%

“…We applied random effects BMS at the Family level to clarify the contribution of each hemisphere (Left: Models 1, 3,4,5,6,7,9,10,11;Right: Models 2,8,12,13,14,15,16,17,18) and to elucidate the direction of information (Forward, Backward or Lateral) at different memory loads. The Left-sided Family showed the highest exceedance probability (65%; Figure 3A) in the 1-back modulation.…”

Section: Family-wise Comparisonsmentioning

confidence: 99%

Dynamic causal modeling of load-dependent modulation of effective connectivity within the verbal working memory network

2013

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This is the accepted version of the paper.This version of the publication may differ from the final published version. Permanent repository link AbstractNeuroimaging studies have consistently shown that working memory (WM) tasks engage a distributed neural network that primarily includes the dorsolateral prefrontal (DLPFC), the parietal (PAR) and the anterior cingulate cortices (ACC). The current challenge is to provide a mechanistic account of the changes observed in regional activity. To achieve this we characterised neuroplastic responses in effective connectivity between these regions at increasing WM loads using Dynamic Causal Modeling of functional magnetic resonance imaging data obtained from healthy individuals during a verbal n-back task. Our data demonstrate that increasing memory load was associated with (a) right-hemisphere dominance, (b) increasing forward (i.e. posterior to anterior) effective connectivity within the WM network, and (c) reduction in individual variability in WM network architecture resulting in the right-hemisphere forward model reaching an exceedance probability of 99% in the most demanding condition. Our results provide direct empirical support that task difficulty, in our case WM load, is a significant moderator of short-term plasticity, complementing existing theories of task-related reduction in variability in neural networks.

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“…43) Spontaneous clinical improvement in stroke, trauma, and spinal cord injuries is associated with observable changes at both the cellular level and within the functional connectivity of the relevant neural networks. 44) Moreover, therapies designed to employ the brain's plasticity have been shown to mimic or exceed these changes. For example, studies of post-stroke therapies demonstrate both restoration of functional organization and creation of neuronal projections [45][46][47] while similar studies of brain or spinal cord injuries correlate clinical improvement with observable changes in functional and structural neuroimaging.…”

Section: Neuroplasticity As a Therapeutic Target In Schizophreniamentioning

confidence: 99%

Cognitive Remediation for Schizophrenia

Mogami¹

2012

PsycEXTRA Dataset

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Harnessing neuroplasticity for clinical applications

Cited by 916 publications

References 223 publications

Exercise training for neural recovery in a restricted sample of pediatric brain tumor survivors: a controlled clinical trial with crossover of training versus no training

Exercise training for neural recovery in a restricted sample of pediatric brain tumor survivors: a controlled clinical trial with crossover of training versus no training

Dynamic causal modeling of load-dependent modulation of effective connectivity within the verbal working memory network

Cognitive Remediation for Schizophrenia

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