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Title Authors PubMed ID
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3 Investigation of Phase-Change Droplets and Fast Imaging for Indicator Dilution Measurement of Flow Zajac Z; Helfield B; Williams R; Sheeran P; Tremblay-Darveau C; Yoo K; Burns PN; 40387284
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4 The effect of micro-vessel viscosity on the resonance response of a two-microbubble system Yusefi H; Helfield B; 39705920
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6 Investigating the Accumulation of Submicron Phase-Change Droplets in Tumors. Helfield BL, Yoo K, Liu J, Williams R, Sheeran PS, Goertz DE, Burns PN 32732167
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7 Simulation of Capillary Hemodynamics and Comparison with Experimental Results of Microphantom Perfusion Weighted Imaging. S S, N RA 32637373
PHYSICS
8 A dataset of multi-contrast population-averaged brain MRI atlases of a Parkinson׳s disease cohort. Xiao Y, Fonov V, Chakravarty MM, Beriault S, Al Subaie F, Sadikot A, Pike GB, Bertrand G, Collins DL 28491942
PERFORM

 

Title:Simulation of Capillary Hemodynamics and Comparison with Experimental Results of Microphantom Perfusion Weighted Imaging.
Authors:S SN RA
Link:https://www.ncbi.nlm.nih.gov/pubmed/32637373?dopt=Abstract
DOI:10.31661/jbpe.v0i0.910
Publication:Journal of biomedical physics & engineering
Keywords:Capillary HemodynamicsCerebral Blood VolumeContrast MediaPerfusion ImagingPhantoms, Imaging
PMID:32637373 Category:J Biomed Phys Eng Date Added:2020-07-09
Dept Affiliation: PHYSICS
1 MSc Student, Physics and Medical Engineering Department, Medical Faculty, Tehran University of Medical Sciences, Tehran, Iran.
2 PhD, Department of Medical Physics and Biomedical Engineering, Faculty of Medicine, Tehran University of Medical Sciences (TUMS), Tehran, Iran.
3 PhD, PERFORM Preventive Medicine and Health Care Center, Concordia University, Montreal, Quebec, Canada.
4 PhD, Medical Pharmaceutical Sciences Research Center (MPRC), the institute of Pharmaceutical Sciences, Tehran University of Medical Sciences, Tehran, Iran.

Description:

Simulation of Capillary Hemodynamics and Comparison with Experimental Results of Microphantom Perfusion Weighted Imaging.

J Biomed Phys Eng. 2020 Jun;10(3):291-298

Authors: S S, N RA

Abstract

Background: Perfusion imaging, one of MRI's techniques, is widely used to test damaged tissues of the body. The parameters used in this technique include cerebral blood flow (CBF), cerebral blood volume (CBV), and mean transit time (MTT). The MRI scanner contains a device called a "phantom", which controls the accuracy of various imaging models.

Objective: Our goal is to design and produce a microphantom to control the perfusion-imaging model in MRI scanners.

Material and Methods: Firstly, in an analytical study type, we designed the phantom based on Murray's minimum work rule using AutoCAD software. Next, the phantom was fabricated using lithography and then imaged using a Siemens Magnetom 3T Prisma MRI scanner at the National Brain Laboratory. Finally, the velocity and pressure in the capillary network was simulated using COMSOL software.

Results: CBF, CBV, and MTT curves for the capillary network were obtained at different times. In addition, the simulations showed that the velocity and pressure in the capillary network were between 0.0001 and 0.0005 m/s and between 5 and 25 mm/Hg, respectively.

Conclusion: The fabricated microphantom was used to simulate the movement of blood within tissues of the body. Different parameters of perfusion imaging were measured inside the phantom, and they in the phantom were similar to in the body.

PMID: 32637373 [PubMed]




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