Characterization and Construction of a Robust and Elastic Wall-Less Flow Phantom for High Pressure Flow Rate Using Doppler Ultrasound Applications

A Doppler ultrasound is a noninvasive test that can be used to estimate the blood flow through the vessels. Presently, few flow phantoms are being used to be qualified for long-term utilize and storage with high physiological flow rate Doppler ultrasound. The main drawback of the two hydrogel materi...

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Main Authors: Ammar A. Oglat, MZ Matjafri, Nursakinah Suardi, Mohammad A. Oqlat, Ahmad A. Oqlat, Mostafa A Abdelrahman, O.F.Farhat, Muntaser S. Ahmad, Batool N. Alkhateb, Sylvester J. Gemanam, Sabri M.Shalbi, Raed Abdalrheem, Marwan Shipli, Mohammad Marashdeh
Format: Article
Language:English
Published: Natural and Engineering Sciences 2018-10-01
Series:Natural and Engineering Sciences
Subjects:
BMF
TMM
Online Access:http://www.nesciences.com/download.php?id=395
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spelling doaj-4b037582d1594beab764a2eff08d91b52020-11-25T00:36:42ZengNatural and Engineering SciencesNatural and Engineering Sciences2458-89892458-89892018-10-013335937710.28978/nesciences.468972Characterization and Construction of a Robust and Elastic Wall-Less Flow Phantom for High Pressure Flow Rate Using Doppler Ultrasound ApplicationsAmmar A. OglatMZ MatjafriNursakinah SuardiMohammad A. OqlatAhmad A. OqlatMostafa A AbdelrahmanO.F.FarhatMuntaser S. AhmadBatool N. AlkhatebSylvester J. GemanamSabri M.ShalbiRaed AbdalrheemMarwan ShipliMohammad MarashdehA Doppler ultrasound is a noninvasive test that can be used to estimate the blood flow through the vessels. Presently, few flow phantoms are being used to be qualified for long-term utilize and storage with high physiological flow rate Doppler ultrasound. The main drawback of the two hydrogel materials items (Konjac (K) and carrageenan (C) (KC)) that it is not fit for long-term storage and easy to deteriorate. Thus, this research study focuses on the characterization and construction of a robust and elastic wall-less flow phantom with suitable acoustical properties of TMM. The mechanisms for the fabrication of a wall-less flow phantom utilizing a physically strong material such as K, C, and gelatin (bovine skin)-based TMM were explained. In addition, the clinical ultrasound (Hitachi Avius (HI)) system was used as the main instrument for data acquisition. Vessel mimicking material (VMM) with dimensions of 15.0 mm depth equal to those of human common carotid arteries (CCA) were obtained with pulsatile flow. The acoustical properties (speed of sound and attenuation were 1533±2 m/s and 0.2 dB/cm. MHz, respectively) of a new TMM were agreed with the IEC 61685 standards. Furthermore, the velocity percentages error were decreased with increase in the Doppler angle (the lowest % error (3%) it was at 53◦). The gelatin from bovine skin was a proper material to be added to KC to enhance the strength of TMM during for long-term utilize and storage of high-flow of blood mimicking Fluid (BMF). This wall-less flow phantom will be a suitable instrument for examining in-vitro research studies.http://www.nesciences.com/download.php?id=395BMFTMMWall-less Flow PhantomAcoustical PropertiesClinical Doppler Ultrasound (HI)
collection DOAJ
language English
format Article
sources DOAJ
author Ammar A. Oglat
MZ Matjafri
Nursakinah Suardi
Mohammad A. Oqlat
Ahmad A. Oqlat
Mostafa A Abdelrahman
O.F.Farhat
Muntaser S. Ahmad
Batool N. Alkhateb
Sylvester J. Gemanam
Sabri M.Shalbi
Raed Abdalrheem
Marwan Shipli
Mohammad Marashdeh
spellingShingle Ammar A. Oglat
MZ Matjafri
Nursakinah Suardi
Mohammad A. Oqlat
Ahmad A. Oqlat
Mostafa A Abdelrahman
O.F.Farhat
Muntaser S. Ahmad
Batool N. Alkhateb
Sylvester J. Gemanam
Sabri M.Shalbi
Raed Abdalrheem
Marwan Shipli
Mohammad Marashdeh
Characterization and Construction of a Robust and Elastic Wall-Less Flow Phantom for High Pressure Flow Rate Using Doppler Ultrasound Applications
Natural and Engineering Sciences
BMF
TMM
Wall-less Flow Phantom
Acoustical Properties
Clinical Doppler Ultrasound (HI)
author_facet Ammar A. Oglat
MZ Matjafri
Nursakinah Suardi
Mohammad A. Oqlat
Ahmad A. Oqlat
Mostafa A Abdelrahman
O.F.Farhat
Muntaser S. Ahmad
Batool N. Alkhateb
Sylvester J. Gemanam
Sabri M.Shalbi
Raed Abdalrheem
Marwan Shipli
Mohammad Marashdeh
author_sort Ammar A. Oglat
title Characterization and Construction of a Robust and Elastic Wall-Less Flow Phantom for High Pressure Flow Rate Using Doppler Ultrasound Applications
title_short Characterization and Construction of a Robust and Elastic Wall-Less Flow Phantom for High Pressure Flow Rate Using Doppler Ultrasound Applications
title_full Characterization and Construction of a Robust and Elastic Wall-Less Flow Phantom for High Pressure Flow Rate Using Doppler Ultrasound Applications
title_fullStr Characterization and Construction of a Robust and Elastic Wall-Less Flow Phantom for High Pressure Flow Rate Using Doppler Ultrasound Applications
title_full_unstemmed Characterization and Construction of a Robust and Elastic Wall-Less Flow Phantom for High Pressure Flow Rate Using Doppler Ultrasound Applications
title_sort characterization and construction of a robust and elastic wall-less flow phantom for high pressure flow rate using doppler ultrasound applications
publisher Natural and Engineering Sciences
series Natural and Engineering Sciences
issn 2458-8989
2458-8989
publishDate 2018-10-01
description A Doppler ultrasound is a noninvasive test that can be used to estimate the blood flow through the vessels. Presently, few flow phantoms are being used to be qualified for long-term utilize and storage with high physiological flow rate Doppler ultrasound. The main drawback of the two hydrogel materials items (Konjac (K) and carrageenan (C) (KC)) that it is not fit for long-term storage and easy to deteriorate. Thus, this research study focuses on the characterization and construction of a robust and elastic wall-less flow phantom with suitable acoustical properties of TMM. The mechanisms for the fabrication of a wall-less flow phantom utilizing a physically strong material such as K, C, and gelatin (bovine skin)-based TMM were explained. In addition, the clinical ultrasound (Hitachi Avius (HI)) system was used as the main instrument for data acquisition. Vessel mimicking material (VMM) with dimensions of 15.0 mm depth equal to those of human common carotid arteries (CCA) were obtained with pulsatile flow. The acoustical properties (speed of sound and attenuation were 1533±2 m/s and 0.2 dB/cm. MHz, respectively) of a new TMM were agreed with the IEC 61685 standards. Furthermore, the velocity percentages error were decreased with increase in the Doppler angle (the lowest % error (3%) it was at 53◦). The gelatin from bovine skin was a proper material to be added to KC to enhance the strength of TMM during for long-term utilize and storage of high-flow of blood mimicking Fluid (BMF). This wall-less flow phantom will be a suitable instrument for examining in-vitro research studies.
topic BMF
TMM
Wall-less Flow Phantom
Acoustical Properties
Clinical Doppler Ultrasound (HI)
url http://www.nesciences.com/download.php?id=395
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