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Cerebral cortex thickness estimation method based on three-dimensional Laplace operator

A technology of Laplacian operator and cerebral cortex, which is applied in MRI detection of cerebral cortex morphology changes, early diagnosis of neurodegenerative diseases, and can solve problems such as poor estimation accuracy of cerebral cortex thickness

Inactive Publication Date: 2020-02-21
LUDONG UNIVERSITY
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Problems solved by technology

[0005] 2) Due to the complex topological structure of the cerebral cortex, at a certain grid resolution, the obtained discrete potential energy field distribution makes the estimation accuracy of the subsequent cerebral cortex thickness poor. How to construct an effective computational geometric method and improve the calculation accuracy is an urgent need Another key technical problem solved

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  • Cerebral cortex thickness estimation method based on three-dimensional Laplace operator
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  • Cerebral cortex thickness estimation method based on three-dimensional Laplace operator

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Embodiment Construction

[0025] The purpose of this invention is to provide a method for estimating the thickness of the cerebral cortex based on the three-dimensional Laplacian, which is characterized in that it is based on solving the overlapping areas of the cerebral cortex, and constructs a tetrahedral grid structure inside the cerebral cortex. The three-dimensional Laplace operator and the finite element method calculate the temperature field distribution inside the cerebral cortex, and combine the determination of the local isothermal surface and the determination of the direction of the gradient line to find the corresponding points on the inner and outer surfaces of the cerebral cortex, thereby calculating the temperature distribution of the cerebral cortex. The thickness characteristics of , the specific steps are described as follows:

[0026] Step 1: Detect and mark overlapping areas. First, determine which triangular mesh vertices on the surface of the white matter layer have crossed and o...

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Abstract

Cerebral cortex thickness estimation in brain magnetic resonance imaging (MRI) is an important technical means for researching brain development and neurodegenerative diseases in neuroimaging. The invention provides a cerebral cortex thickness estimation algorithm based on a three-dimensional Laplace operator, which can accurately capture geometrical morphological characteristics in brain nuclearmagnetic resonance imaging. The method comprises the following steps: firstly, starting from the elimination of a cross overlapping region generated on the surface of a gray matter layer and the surface of a white matter layer, constructing a tetrahedral mesh which reflects the inherent geometrical characteristics of the brain and is matched with MRI; secondly, constructing a three-dimensional Laplace operator by utilizing a geometric constraint relationship of a tetrahedral mesh, and calculating the distribution of a cerebral cortex internal temperature field under a Diels boundary by utilizing a finite element method; then, determining a local isothermal surface, obtaining the gradient line direction of the isothermal surface in the temperature field through a calculation geometry method, and a tetrahedral mesh unit where internal points on a gradient line are located is rapidly locked through a half-half surface data storage structure; and finally obtaining the thickness characteristic information of the cerebral cortex according to the direction and the step length of each gradient line by combining the set gradient step length. According to the method, the morphological structure detection capability of the cerebral cortex can be effectively improved by constructing a high-quality cerebral cortex tetrahedral mesh and determining a high-precision temperature field gradientline.

Description

technical field [0001] The invention belongs to the field of computer application technology, relates to MRI cerebral cortex morphology change detection technology, and is used for early diagnosis of neurodegenerative diseases such as AD. Background technique [0002] Alzheimer's disease (AD) is a degenerative neurological disease with insidious onset, manifested by generalized dementia such as memory impairment, aphasia, apraxia, agnostic spatial skill impairment, executive dysfunction, and personality and behavioral changes. characteristics, seriously endangering the healthy development of the elderly. In order to better treat and prevent AD diseases, it is necessary to accurately diagnose mild cognitive impairment (MCI) who are easily transformed into AD diseases. With the aggravation of AD symptoms, the corresponding changes in cerebral cortex morphology show thinning of the cortical thickness. Therefore, by estimating the thickness information of the overall cerebral c...

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Application Information

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IPC IPC(8): G06F30/23G06T17/20G16H50/20G06F119/08
CPCG06T17/20G06T2210/41G16H50/20
Inventor 王刚孔得平范永辉
Owner LUDONG UNIVERSITY
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