Traumatic Brain Injury Detection Using Electrophysiological Methods

Rapp, Paul E.; Keyser, David O.; Albano, A. M.; Hernandez, Rene S; Gibson, Douglas; Zambon, Robert A.; Hairston, W. David; Hughes, John D.; Krystal, Andrew D.; Nichols, Andrew S.

doi:10.3389/fnhum.2015.00011

Cited by 118 publications

(113 citation statements)

References 385 publications

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“…[45][46][47] Some studies even indicate the possibility of using the EEG as a central nervous system dysfunctions marker. [48][49][50][51] As an example, the specific measurements derived from an electroencephalogram could indicate cortical areas most affected in cases of traumatic brain injury, and may thus be useful for the development of tools for its diagnosis. 48 Furthermore, it would help in the determination of the lesion and the time of return to post-injury sports activities in athletes.…”

Section: ■ Discussionmentioning

confidence: 99%

“…[48][49][50][51] As an example, the specific measurements derived from an electroencephalogram could indicate cortical areas most affected in cases of traumatic brain injury, and may thus be useful for the development of tools for its diagnosis. 48 Furthermore, it would help in the determination of the lesion and the time of return to post-injury sports activities in athletes. 51 Our findings may guide further studies on the use of EEG as the central nervous system dysfunction marker, considering our finding that cortical changes after a relatively short condition of movement deprivation.…”

Section: ■ Discussionmentioning

confidence: 99%

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Gamma absolute power reveals activation of motor areas after hand immobilization

Machado¹,

França²,

Teixeira³

et al. 2016

Medical Express

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OBJECTIVE:To analyze changes in gamma band absolute power in motor cortical areas, before and after a condition of hand immobilization for 48 hours. METHOD: Fifteen healthy volunteers, aged between 20 and 30, were submitted to EEG assessment before and after 48 hours of immobilization of the dominant hand, while performing a motor task triggered by a visual stimulus. A two-way repeated measures ANOVA with two within-group factors (moment x condition), each one with two levels (before vs. after visual stimuli; before vs. after 48-hour HI, respectively) was used to test for changes in beta band absolute power. RESULTS: Statistical analysis revealed that hand immobilization caused changes in cortical areas. A significant increase in gamma band absolute power was found after hand immobilization at electrodes F3 (p = 0.001) at F4 (p = 0.001) and at Fz (p = 0.001), at C3 (p = 0.001), C4 (p = 0.001) and Cz (p = 0.001). CONCLUSION: These results reveal that oscillations of the gamma band can be a cortical strategy to solve the effect of less activation due to movement restriction. Knowledge of the functioning of motor cortical areas after a condition of immobilization can lead to more effective strategies in rehabilitation.

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Section: ■ Discussionmentioning

confidence: 99%

Section: ■ Discussionmentioning

confidence: 99%

Gamma absolute power reveals activation of motor areas after hand immobilization

Machado¹,

França²,

Teixeira³

et al. 2016

Medical Express

View full text Add to dashboard Cite

show abstract

“…Again, this requires accurate kinematic input as well as reliable clinical evaluation of injury (e.g., via quantitative electroencephalography (qEEG) 38 , diffusion tensor imaging (DTI) 3,34 , and functional magnetic resonance imaging (fMRI) 21 ) of a sizeable population to train the model, without which, the practical value of a computational model is rather limited. Nevertheless, if sufficiently accurate strains can be estimated in real-time, the pcBRA may accelerate the process of identifying the causal or correlative relationships between measured external head impacts, estimated tissue mechanical responses, observed neuroimaging and cognitive alterations, and diagnosed concussions in the real world.…”

Section: Introductionmentioning

confidence: 99%

Performance Evaluation of a Pre-computed Brain Response Atlas in Dummy Head Impacts

Zhao

Kuo

et al. 2017

Ann Biomed Eng

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A pre-computed brain response atlas (pcBRA) may have the potential to accelerate the investigation of the biomechanical mechanisms of traumatic brain injury on a large-scale. In this study, we further enhance the technique and evaluate its performance using angular velocity profiles from dummy head impacts. Using the pcBRA to simplify profiles into acceleration-only shapes, sufficiently accurate strain estimates were obtained for impacts with a major dominating velocity peak. However, they were largely under-estimated when substantial deceleration occurred that reversed the direction of angular velocity. For these impacts, estimation accuracy was substantially improved with a biphasic profile simplification (average correlation coefficient and linear regression slope of 0.92±0.03 and 0.95±0.07 for biphasic shapes, respectively, vs. 0.80±0.06 and 0.80±0.08 for acceleration-only shapes). Peak maximum principal strain (εp) and cumulative strain damage measure (CSDM) from the estimated strains consistently correlated stronger than kinematic metrics with respect to the baseline εp and CSDM from the directly simulated responses, regardless of the brain region (e.g., correlation of 0.93 vs. 0.75 compared to Brain Injury Criterion (BrIC) for εp in the whole-brain, and 0.91 vs. 0.47 compared to BrIC for CSDM in the corpus callosum). These findings further support the pre-computation technique for accurate, real-time strain estimation, which could be important to accelerate the pace of model-based brain injury studies in the future.

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“…Cognitive processes are the result of transient synchronization of local and distributed neuronal assemblies [57]. Neuronal oscillations must balance the need for transient synchronization and the pathological, runaway hyper-synchronization that results in an epileptic seizure.…”

Section: Detection Of Ae and Asdmentioning

confidence: 99%

Nonlinear EEG biomarker profiles for autism and absence epilepsy

Bosl

Loddenkemper

Nelson

2017

Neuropsychiatr Electrophysiol

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Background: Although autism and epilepsy are considered to be different disorders, epileptiform EEG activity is common in people with autism even when overt seizures are not present. The relatively high comorbidity between autism and all epilepsy syndromes suggests the possibility of common underlying neurophysiological mechanisms. Although many different epilepsies may be comorbid with autism, absence epilepsy is a generalized epilepsy syndrome with seizures that appear as staring spells, with no motor signs and no focal lesions, making it more difficult to diagnose. Application of nonlinear methods for EEG signal analysis may enable characterization of brain activity that can help to delineate neurophysiological commonalities and differences between autism and epilepsy. Multiscale entropy and recurrence quantitative analysis (RQA) were computed from EEG signals derived from children with autism or absence epilepsy and compared with the goal of finding significant and potentially clinically useful biomarkers neurophysiological differences between these two childhood disorders. Methods: Multiscale entropy and a multiscale version of RQA were computed from EEG data obtained from 92 children were collected in two different settings at Boston Children's Hospital. Short segments of alert resting state EEG were selected for analysis. A complexity index derived from entropy and RQA methods was computed from each of 19 standard EEG channels for all subjects using publicly available software. Statistical comparisons were made between the groups. Machine learning classifiers were also used to determine which derived features were most significantly different among the groups, and to determine classification specificity and sensitivity. Results: Significant differences were found between absence, autism, and control groups in a number of different scalp locations and the values of complexity index. Autism values appeared to be intermediate between epilepsy and control in many locations, and differences between controls and absence patients were more widely distributed across scalp locations. Classification algorithms were able to distinguish absence epilepsy and autism cases from controls with high (>95%) accuracy. Importantly, two independent control groups, although they were derived from different settings and with different equipment were statistically indistinguishable.

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Traumatic Brain Injury Detection Using Electrophysiological Methods

Cited by 118 publications

References 385 publications

Gamma absolute power reveals activation of motor areas after hand immobilization

Gamma absolute power reveals activation of motor areas after hand immobilization

Performance Evaluation of a Pre-computed Brain Response Atlas in Dummy Head Impacts

Nonlinear EEG biomarker profiles for autism and absence epilepsy

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