Abstract
Brain shift and herniation are important signs of increased intracranial pressure (ICP) caused by hematomas or other types of intracranial mass. We propose a novel finite-element model that can be deformed in response to increased ICP. The half sphere model of the brain is partially divided into two compartments by the intact mid-sagittal plane, allowing subfalcine herniation. A 40 mm circle in the center of its equatorial plane allows transtentorial herniation. We perform a single load step, structural static analysis, simulating a left-sided subdural hematoma (SDH) compressing the cerebral hemispheres from the outer surface of the left hemisphere. Subfalcine and transtentorial brain herniations are reproduced and visualized. The Poisson’s ratio represents the tightness of the brain and the pressure load represents the ICP. There is a linear relationship between maximal deformation and the pressure load. The maximal deformation at the basal circumference and that at the basal midline closely resembles the maximal thickness of the SDH and the midline shift. We have developed a simple finite-element model that can simulate brain shift and herniation caused by pressure loads exerted on its surface by a mass. The experimental results correlate well with clinical observation on patients with acute and chronic SDH.
Highlights
Brain deformation after applying a 20-mmHg pressure load is shown in the upper middle part of Fig. 1, using a cutaway view from the anterior-inferior aspect using coronal (Y-Z) cutting planes 20 mm anterior to the center of the basal planes through the center of the subfalcine space
We have proposed a simplified FE model that can be applied to simulating brain shift caused by an subdural hematoma (SDH)
In the first part of our experiment, our model with “standard” biomechanical parameters is subject to different pressure loads
Summary
MATEC Web of Conferences 169, 01046 (2018). MATEC Web of Conferences systemic or intracranial conditions, secondary injury may aggravate primary brain injury, but it can be ameliorated by taking specific measures. The edematous and deformed brain can produce increased intracranial pressure (ICP), resulting in brain shift, which is an important manifestation of secondary injury. The injured cerebral hemisphere may herniate through the subfalcine space (SFS) to the other side, resulting in subfalcine herniation (SFH), appearing as midline shift (MLS) on brain images such as computed tomography (CT) studies [2]. With further elevation of the ICP, the medial part of the cerebrum may herniate through the tentorial incisura (TI), resulting in transtentorial herniation (TTH) and brain stem compression. Biomechanics is devoted to the analysis, measurement and modeling of the effects which are measured quantitatively under various mechanical loading situations in biological systems. There has been no biomechanical model dedicated to simulating brain herniation in the literature
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