Quantitative Strain Mapping of an Abdominal Aortic Aneurysm

概要

Source: Hannah L. Cebull1, Arvin H. Soepriatna1, John J. Boyle2 and Craig J. Goergen1

1Weldon School of Biomedical Engineering, Purdue University, West Lafayette, Indiana

2Mechanical Engineering & Materials Science, Washington University in St. Louis, St Louis, Missouri

The mechanical behavior of soft tissues, such as blood vessels, skin, tendons, and other organs, are strongly influenced by their composition of elastin and collagen, which provide elasticity and strength. The fiber orientation of these proteins depends on the type of soft tissue and can range from a single preferred direction to intricate meshed networks, which can become altered in diseased tissue. Therefore, soft tissues often behave anisotropically on the cellular and organ level, creating a need for three-dimensional characterization. Developing a method for reliably estimating strain fields within complex biological tissues or structures is important to mechanically characterize and understande disease. Strain represents how soft tissue relatively deforms over time, and it can be described mathematically through various estimations.

Acquiring image data over time allows deformation and strain to be estimated. However, all medical imaging modalities contain some amount of noise, which increases the difficulty of accurately estimating in vivo strain. The technique described here successfully overcomes these issues by using a direct deformation estimation (DDE) method to calculate spatially varying 3D strain fields from volumetric image data.

Current strain estimation methods include digital image correlation (DIC) and digital volume correlation. Unfortunately, DIC can only accurately estimate strain from a 2D plane, severely limiting the application of this method. While useful, 2D methods such as DIC have difficulty quantifying strain in regions that undergo 3D deformation. This is because out-of-plane motion creates deformation errors. Digital volume correlation is a more applicable method that divides the initial volume data into regions and finds the most similar region of the deformed volume, thereby reducing out-of-plane error. However, this method proves to be sensitive to noise and requires assumptions about the mechanical properties of the material.

The technique demonstrated here eliminates these issues by using a DDE method, thus making it very useful in the analysis of medical imaging data. Furthermore, it is robust to high or localized strain. Here we describe the acquisition of gated, volumetric 4D ultrasound data, its conversion into an analyzable format, and the use of a custom Matlab code to estimate 3D deformation and corresponding Green-Lagrange strains, a parameter that better describes large deformations. The Green-Lagrange strain tensor is implemented in many 3D strain estimation methods because it allows for F to be calculated from a Least Squares Fit (LSF) of the displacements. The equation below represents the Green-Lagrange strain tensor, E, where F and I represent the deformation gradient and second order identity tensor, respectively.

Equation 1 (1)

手順

1. 4D Ultrasound Set-up

  1. When using the imaging software, use a laptop capable of running mathematical computing software to automate the 4D acquisition process. Connect the laptop with this custom code to the ultrasound system via the USB port. Note that the imaging software has a 4D ultrasound feature integrated into the software.
  2. After turning on the ultrasound system, set up the physiological monitoring unit while also ensuring that the heart rate and temperature buttons are on. Initialize the 3D

Log in or to access full content. Learn more about your institution’s access to JoVE content here

結果

Using the procedure described above, 4D ultrasound of an angiotensin II-induced suprarenal dissecting abdominal aortic aneurysm (AAA) of a mouse was acquired. Multiple short-axis EKV video loops were acquired along the aorta and combined to create 4D data, as shown in Figure 1. This data was then converted into a MAT file using a custom code, which was then analyzed in a 3D strain calculation code using a warping function. After optimizing the parameters of the code for a specific data set,

Log in or to access full content. Learn more about your institution’s access to JoVE content here

申請書と概要

Localized in vivo mechanical characterization is an important part of understanding the growth and remodeling of biological tissues. Compared to existing approaches, the strain quantification procedure described here uses an improved method of accurately calculating 3D strain through optimally warping the undeformed image before cross-correlation. This method does not use any material assumptions in determining strains within tissue volumes. Unfortunately, the strain estimation is reliable only down to a kernel

Log in or to access full content. Learn more about your institution’s access to JoVE content here

タグ
Quantitative Strain MappingAbdominal Aortic AneurysmThree dimensional Strain ImagingSoft TissuesExtracellular CompositionMechanical BehaviorAgingDiseaseComplex Biological TissuesDeformation Estimation MethodSpatially Varying Three dimensional Strain FieldsElastinCollagenProtein Orientation

スキップ先...

0:07

Overview

1:14

Principles of Strain Mapping

3:40

4D Ultrasound Set-up

4:58

Ultrasound Image Acquisition

5:45

Image Analysis

7:30

Results

8:41

Applications

10:02

Summary

このコレクションのビデオ:

article

Now Playing

Quantitative Strain Mapping of an Abdominal Aortic Aneurysm

Biomedical Engineering

4.6K 閲覧数

article

光学・共焦点顕微鏡による生体試料のイメージング

Biomedical Engineering

35.6K 閲覧数

article

生体試料のSEMイメージング

Biomedical Engineering

23.5K 閲覧数

article

ナノドラッグキャリアのバイオディストリビューション:SEMの応用

Biomedical Engineering

9.2K 閲覧数

article

腹部大オルタの高周波超音波イメージング

Biomedical Engineering

14.4K 閲覧数

article

インフラレナル大オルタにおける血液と脂質を画像化する光音響断層撮影

Biomedical Engineering

5.7K 閲覧数

article

心臓磁気共鳴イメージング

Biomedical Engineering

14.6K 閲覧数

article

脳動脈瘤における血流の計算流体力学シミュレーション

Biomedical Engineering

11.7K 閲覧数

article

腹部大動脈瘤の近赤外蛍光イメージング

Biomedical Engineering

8.2K 閲覧数

article

非侵襲的な血圧測定技術

Biomedical Engineering

11.8K 閲覧数

article

心電図(心電図)信号の獲得と解析

Biomedical Engineering

104.1K 閲覧数

article

リバーブルバイオマテリアルの引張強度

Biomedical Engineering

7.4K 閲覧数

article

マウス脊髄のマイクロCTイメージング

Biomedical Engineering

7.9K 閲覧数

article

ラットにおける非侵襲的ACL損傷後の膝関節変性の可視化

Biomedical Engineering

8.2K 閲覧数

article

SPECTとCTイメージングを組み合わせて心臓機能を可視化

Biomedical Engineering

11.0K 閲覧数

JoVE Logo

個人情報保護方針

利用規約

一般データ保護規則

研究

教育

JoVEについて

Copyright © 2023 MyJoVE Corporation. All rights reserved