Intracranial biomechanics following cortical contusion in live rats

Alfasi, Abdulghader M; Shulyakov, Alexander V.; Bigio, Marc R. Del

doi:10.3171/2013.7.jns121973

Cited by 13 publications

(4 citation statements)

References 33 publications

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“…The effective elastic modulus was 100 -600 Pa, depending on the location and indentation depth, and grey matter was stiffer than white mater. More recently, AFM indentation showed that injury softens the brain and spinal cord (Moeendarbary et al, 2017), in agreement with previous investigations (Alfasi et al, 2013;Shafieian et al, 2009). Elastic moduli of the intact cortex were 200-300 Pa. All AFM studies of the rodent brain to date have neglected viscoelastic effects.…”

Section: Atomic Force Microscopy Studies In Ratssupporting

confidence: 86%

Biomechanical simulation of traumatic brain injury in the rat

Finan

2019

Clinical Biomechanics

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Important progress in mathematical modeling and measurement of biomechanical properties has led to credible, predictive simulations of traditional, experimental models of traumatic brain injury in the rat, such as controlled cortical impact. However, recent trends such as the increasing popularity of closed head models and blast models create new biomechanical challenges. Investigators studying rat brain biomechanics must continue to innovate to keep pace with these developments.

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Section: Atomic Force Microscopy Studies In Ratssupporting

confidence: 86%

Biomechanical simulation of traumatic brain injury in the rat

Finan

2019

Clinical Biomechanics

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“…The feasibility of using diffusion tensor imaging in in-vivo detection and tracking of these structural changes, both during the progression of hydrocephalus and after shunting surgery, has recently been documented (Eskandari et al, 2014;Hattingen et al, 2010). Also Alfasi et al (2013) studied these structural damages and their effect on the brain tissue's viscoelastic properties. They concluded that factors such as edema and tissue's necrosis weaken the brain's elastic and viscous properties at the early stages of hydrocephalus.…”

Section: Resultsmentioning

confidence: 98%

Dual-porosity poroviscoelasticity and quantitative hydromechanical characterization of the brain tissue with experimental hydrocephalus data

Mehrabian

Abousleiman

Mapstone

et al. 2015

Journal of Theoretical Biology

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“…With MRE, several studies of preclinical models have indicated its potential usefulness in TBI. The mechanical properties of the brain (as measured by MRE) have been found to change following brain injury in living rat and mice ( Alfasi et al, 2013 ; Boulet et al, 2013 ). Furthermore, using a TBI mouse model, a longitudinal study of MRE demonstrated that the elastic modulus of the injured brain tissue was higher than that of the contralateral hemisphere 1 h after injury ( Feng et al, 2017 ).…”

Section: Advanced Magnetic Resonance Imaging Based Techniquesmentioning

confidence: 99%

Advanced Neuroimaging Role in Traumatic Brain Injury: A Narrative Review

Yang

Jin

et al. 2022

Front. Neurosci.

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Traumatic brain injury (TBI) is a common source of morbidity and mortality among civilians and military personnel. Initial routine neuroimaging plays an essential role in rapidly assessing intracranial injury that may require intervention. However, in the context of TBI, limitations of routine neuroimaging include poor visualization of more subtle changes of brain parenchymal after injury, poor prognostic ability and inability to analyze cerebral perfusion, metabolite and mechanical properties. With the development of modern neuroimaging techniques, advanced neuroimaging techniques have greatly boosted the studies in the diagnosis, prognostication, and eventually impacting treatment of TBI. Advances in neuroimaging techniques have shown potential, including (1) Ultrasound (US) based techniques (contrast-enhanced US, intravascular US, and US elastography), (2) Magnetic resonance imaging (MRI) based techniques (diffusion tensor imaging, magnetic resonance spectroscopy, perfusion weighted imaging, magnetic resonance elastography and functional MRI), and (3) molecular imaging based techniques (positron emission tomography and single photon emission computed tomography). Therefore, in this review, we aim to summarize the role of these advanced neuroimaging techniques in the evaluation and management of TBI. This review is the first to combine the role of the US, MRI and molecular imaging based techniques in TBI. Advanced neuroimaging techniques have great potential; still, there is much to improve. With more clinical validation and larger studies, these techniques will be likely applied for routine clinical use from the initial research.

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Intracranial biomechanics following cortical contusion in live rats

Cited by 13 publications

References 33 publications

Biomechanical simulation of traumatic brain injury in the rat

Biomechanical simulation of traumatic brain injury in the rat

Dual-porosity poroviscoelasticity and quantitative hydromechanical characterization of the brain tissue with experimental hydrocephalus data

Advanced Neuroimaging Role in Traumatic Brain Injury: A Narrative Review

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