Neural Tissue Motion Impacts Cerebrospinal Fluid Dynamics at the Cervical Medullary Junction: A Patient-Specific Moving-Boundary Computational Model

Pahlavian Soroush Heidari; Loth Francis; Luciano Mark; Oshinski John; Martin Bryn A.

首页> 外文期刊>Annals of Biomedical Engineering: The Journal of the Biomedical Engineering Society >Neural Tissue Motion Impacts Cerebrospinal Fluid Dynamics at the Cervical Medullary Junction: A Patient-Specific Moving-Boundary Computational Model

【24h】

Neural Tissue Motion Impacts Cerebrospinal Fluid Dynamics at the Cervical Medullary Junction: A Patient-Specific Moving-Boundary Computational Model

机译：神经组织运动影响颈髓交界处的脑脊液动力学：特定于患者的移动边界计算模型。

获取原文

获取原文并翻译 | 示例

掌桥外文数据库（机构版） >>

开具论文收录证明 >>

文献代查 >>

页面导航

摘要
著录项
相似文献
相关主题

摘要

Central nervous system (CNS) tissue motion of the brain occurs over 30 million cardiac cycles per year due to intracranial pressure differences caused by the pulsatile blood flow and cerebrospinal fluid (CSF) motion within the intracranial space. This motion has been found to be elevated in type 1 Chiari malformation. The impact of CNS tissue motion on CSF dynamics was assessed using a moving-boundary computational fluid dynamics (CFD) model of the cervical-medullary junction (CMJ). The cerebellar tonsils and spinal cord were modeled as rigid surfaces moving in the caudocranial direction over the cardiac cycle. The CFD boundary conditions were based on in vivo MR imaging of a 35-year old female Chiari malformation patient with similar to 150-300 A mu m motion of the cerebellar tonsils and spinal cord, respectively. Results showed that tissue motion increased CSF pressure dissociation across the CMJ and peak velocities up to 120 and 60%, respectively. Alterations in CSF dynamics were most pronounced near the CMJ and during peak tonsillar velocity. These results show a small CNS tissue motion at the CMJ can alter CSF dynamics for a portion of the cardiac cycle and demonstrate the utility of CFD modeling coupled with MR imaging to help understand CSF dynamics.

机译：由于颅内压差是由颅内空间内的脉动血流和脑脊液（CSF）运动引起的，颅内压差每年导致大脑的中枢神经系统（CNS）组织运动超过3000万个心动周期。已经发现该运动在1型Chiari畸形中升高。中枢神经系统组织运动对脑脊液动力学的影响使用颈髓交界处（CMJ）的移动边界计算流体动力学（CFD）模型进行评估。小脑扁桃体和脊髓被建模为在整个心动周期中沿顶颅方向移动的刚性表面。 CFD边界条件基于一名35岁女性Chiari畸形患者的体内MR成像，其小脑扁桃体和脊髓运动分别接近150-300 Aμm。结果显示，组织运动增加了跨CMJ的CSF压力解离，峰值速度分别高达120％和60％。在CMJ附近和扁桃体峰值速度期间，CSF动力学变化最为明显。这些结果表明，CMJ处的少量CNS组织运动可以改变一部分心动周期的CSF动态，并证明CFD建模与MR成像结合使用有助于了解CSF动态。

著录项

来源
《Annals of Biomedical Engineering: The Journal of the Biomedical Engineering Society》 |2015年第12期|共13页
作者
Pahlavian Soroush Heidari; Loth Francis; Luciano Mark; Oshinski John; Martin Bryn A.;
展开▼
作者单位

展开▼
收录信息
原文格式 PDF
正文语种 eng
中图分类生物医学工程;
关键词
Cerebrospinal fluid; Computational fluid dynamics; Moving boundary simulation; Central nervous system;

机译：脑脊液;计算流体动力学;运动边界模拟;中枢神经系统;

相似文献

外文文献
中文文献
专利

1. Neural Tissue Motion Impacts Cerebrospinal Fluid Dynamics at the Cervical Medullary Junction: A Patient-Specific Moving-Boundary Computational Model [J] . Pahlavian Soroush Heidari, Loth Francis, Luciano Mark, Annals of Biomedical Engineering: The Journal of the Biomedical Engineering Society . 2015,第12期

机译：神经组织运动影响颈髓交界处的脑脊液动力学：特定于患者的移动边界计算模型。
2. Impact of Neurapheresis System on Intrathecal Cerebrospinal Fluid Dynamics: A Computational Fluid Dynamics Study [J] . Khani Mohammadreza, Sass Lucas R., McCabe Aaron R., Journal of biomechanical engineering. . 2020,第2期

机译：神经施系统对鞘内脑脊液动力学的影响：计算流体动力学研究
3. Open oral cavity has little effects on upper airway aerodynamics in children with obstructive sleep apnea syndrome: A computational fluid dynamics study based on patient-specific models [J] . Chen Shuai, Wang Jingying, Liu Dongxu, Journal of Biomechanics . 2021,第1期

机译：开放口腔对患有阻塞性睡眠呼吸暂停综合征的儿童的上呼吸道空气动力学产生影响：基于患者专用模型的计算流体动力学研究
4. 4D MRI FLOW QUANTIFICATION OF CEREBROSPINAL FLUID MOTION IN THE CERVICAL SPINE IN HEALTHY SUBJECTS AND CHIARI MALFORMATION PATIENTS: HOW DO THE RESULTS COMPARE WITH 3D COMPUTATIONAL FLUID DYNAMICS? [C] . Theresia I. Yiallourou, Alexander.C Bunk, Jan-Robert Kroeger, ASME summer bioengineering conference;SBC2012 . 2012

机译：健康受试者和手足病畸形患者颈椎脑脊液运动的4D MRI流动定量：结果与3D计算流体动力学相比如何？
5. Non-invasive Assessment of Cerebrospinal Fluid and Brain Tissue Biomechanics Using MRI and Computational Modeling [D] . Heidari Pahlavian, Soroush. 2018

机译：利用MRI和计算建模的非侵入性评估脑脊液和脑组织生物力学
6. Neural tissue motion impacts cerebrospinal fluid dynamics at the cervical medullary junction: a patient-specific moving-boundary computational model [O] . Soroush Heidari Pahlavian, Francis Loth, Mark Luciano, -1

机译：神经组织运动影响颈髓交界处的脑脊髓液动力学：特定于患者的移动边界计算模型
7. Neural Tissue Motion Impacts Cerebrospinal Fluid Dynamics at the Cervical Medullary Junction: A Patient-Specific Moving-Boundary Computational Model [O] . Soroush Heidari Pahlavian, Francis Loth, Mark Luciano, 2015

机译：神经组织运动会影响颈椎髓质交界处的脑脊液动力学：患者特异性的移动边界计算模型

Neural Tissue Motion Impacts Cerebrospinal Fluid Dynamics at the Cervical Medullary Junction: A Patient-Specific Moving-Boundary Computational Model

摘要

著录项

相似文献

相关主题

期刊订阅