Numerical evaluation of systematic errors of a non-invasive intracranial pressure measurement

Q3 Earth and Planetary Sciences

Energetika Pub Date : 2018-10-29 DOI:10.6001/energetika.v64i3.3805

Edgaras Misiulis, Gediminas Skarbalius, A. Džiugys

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引用次数: 1

Abstract

Intracranial pressure (ICP) monitoring procedure can be applied to aid in secondary brain damage prevention. A high invasiveness of commonly used ICP measuring methods poses a risk of complications, and therefore new non-invasive methods are currently being developed. A promising non-invasive ICP measurement method is based on the existence of pressure balance state, which is driven by the unique morphological property of ophthalmic artery (OA). The value of ICP can be obtained by evaluating blood flow or artery characteristics in different OA segments, intracranial OA segment (IOA) and extracranial OA segment (EOA). In order to increase measurement accuracy, the systematic errors must be evaluated, which requires an implementation of a numerical model encompassing various physical phenomena. In this paper, a developed numerical model is presented, which was used to solve a transient fluid–structure interaction (FSI) problem of the pulsatile blood flow in a straight, physically meaningful anisotropic, hyperelastic OA, with ICP and external pressure (Pe) loads. It was found that the systematic error based on mean cross-sectional area difference between IOA and EOA segments was {–1.48, –1.37, –1.17} mmHg with ICP = {10, 20, 30} mmHg, respectively. The systematic error based on mean blood flow velocity difference between IOA and EOA segments was {–1.84, –1.76, –1.625} mmHg with ICP = {10, 20, 30} mmHg, respectively. The presented numerical model examined the worst-case scenario in terms of boundary conditions, which were immovable, while lengths of OA segments were physiologically relevant statistical means; however, the obtained systematic errors still met the clinical standards of ANSI/AAMI, where it is stated that the error should not exceed the ± 2 mmHg in the range of 0–20 mmHg of ICP. Boundary conditions and compliance affects the systematic error in both ways (reduce or increase it); this may explain the low systematic errors obtained in experimental studies by other authors.

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无创颅内压测量系统误差的数值评估

颅内压（ICP）监测程序可用于辅助预防继发性脑损伤。常用ICP测量方法的高侵入性会带来并发症的风险，因此目前正在开发新的非侵入性方法。一种很有前途的无创ICP测量方法是基于压力平衡状态的存在，这是由眼动脉（OA）独特的形态学特性驱动的。ICP的值可以通过评估不同OA段、颅内OA段（IOA）和颅外OA段（EOA）的血流或动脉特征来获得。为了提高测量精度，必须评估系统误差，这需要实现包含各种物理现象的数值模型。本文提出了一个新的数值模型，用于求解具有ICP和外压（Pe）载荷的直的、物理意义的各向异性超弹性OA中脉动血流的瞬态流体-结构相互作用（FSI）问题。研究发现，基于IOA和EOA节段之间平均横截面积差的系统误差分别为{-1.48，-1.37，-1.17}mmHg，ICP={10，20，30}mmHg。IOA段和EOA段之间基于平均血流速度差的系统误差分别为{-1.84，-1.76，-1.625}mmHg，ICP={10，20，30}mmHg。所提出的数值模型从边界条件的角度考察了最坏情况，边界条件是不可移动的，而OA段的长度是生理相关的统计手段；然而，所获得的系统误差仍然符合ANSI/AAMI的临床标准，其中指出，在0–20 mmHg的ICP范围内，误差不应超过±2 mmHg。边界条件和顺应性在两个方面影响系统误差（减少或增加它）；这可以解释其他作者在实验研究中获得的低系统误差。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Energetika Energy-Energy Engineering and Power Technology

CiteScore

2.10

自引率

0.00%

发文量

期刊介绍： The journal publishes original scientific, review and problem papers in the following fields: power engineering economics, modelling of energy systems, their management and optimization, target systems, environmental impacts of power engineering objects, nuclear energetics, its safety, radioactive waste disposal, renewable power sources, power engineering metrology, thermal physics, aerohydrodynamics, plasma technologies, combustion processes, hydrogen energetics, material studies and technologies, hydrology, hydroenergetics. All papers are reviewed. Information is presented on the defended theses, various conferences, reviews, etc.