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Low-cost MRI System for Teaching

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Abstract:

Magnetic resonance imaging instrumentation is taught at Texas A&M University through the ECEN 463 course and its graduate level equivalent. This class guides students thr...Show More

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Abstract:

Magnetic resonance imaging instrumentation is taught at Texas A&M University through the ECEN 463 course and its graduate level equivalent. This class guides students through several labs where they design their own desktop MRI system using various hardware components and LabVIEW. Because the system uses professional grade equipment, the cost of each lab station is high. As a result, there are only four lab stations available, which limits the class to 32 students. The equipment also contains parts that have become obsolete, inhibiting the ability to maintain the system long term. This project focuses on using easily accessible and more affordable equipment for the MRI system. It can also potentially provide opportunities for remote learning, where students could work on assignments off-campus. Other projects have aimed to design low-cost MRI systems with an emphasis on clinical applications or which require advanced FPGA programming skills or pre-programmed modules. This project will develop the MRI instrumentation with updated off-the-shelf components. The current equipment will be replaced with two Analog Discovery 2 devices, which are low-cost teaching tools. It will also feature inexpensive transmit and receive chains, off-the-shelf gradient amplifiers suitable for teaching, gradient coils for signal localization, and a lighter-weight Halbach magnet. In this stage of the project, projections and images have been captured using a 0.06T permanent magnet. In addition to validating successful system operation, each lab of the course will be integrated with current materials to comply with the new equipment. Hardware and software resources will also be prepared and scaled to meet classroom needs and ensure a smooth transition. The goal of the project is to use the new system starting in the fall 2023 semester.Clinical Relevance— This project shows that low-cost equipment can be implemented into a working MRI system. The intent for this project may be educationally f...

Published in: 2023 45th Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC)

Date of Conference: 24-27 July 2023

Date Added to IEEE Xplore: 11 December 2023

ISBN Information:

ISSN Information:

PubMed ID: 38083320

DOI: 10.1109/EMBC40787.2023.10340036

Conference Location: Sydney, Australia

References is not available for this document.

Contents

I. Introduction

Magnetic resonance imaging is a technology that aids physicians in many ways, from helping to identify malignant tumors to analyzing spinal cord injuries and effects from brain trauma [1]. Due to the high costs of MRI equipment, several groups have investigated how to construct inexpensive desktop imaging systems. Educational MRI scanners have been developed for an undergraduate research teaching lab at MIT and have been used by more than 800 students [2]. A separate project at Northwestern University focused on a teaching system for demonstrating foundations of MRI [3]. The ECEN 463 course at Texas A&M University covers MRI instrumentation and teaches students how to construct a desktop MRI system to produce basic images. The original system for the class was developed using NI hardware and LabVIEW to program pulse sequences [4]. However, the current laboratory equipment used for the course is expensive and not scalable. The limited availability of the tools restricts class sizes and the amount of time students have to work on their labs. This project focuses on designing new instrumentation to replace the current ECEN 463 setup to allow more students to have access to the course, with the flexibility to work on their own outside of class.

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Low-cost MRI System for Teaching

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I. Introduction

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Low-cost MRI System for Teaching

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Abstract:

Metadata

Abstract:

ISSN Information:

I. Introduction

References

IEEE Account

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Profile Information

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