Pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm

Non-invasively reosolving spatial distribution of tissue metabolites serves as a diagnostic tool to in-vivo metabolism thus making magnetic resonance spectroscopic imaging (MRSI) a very useful application. The tissue concentrations of various metabolites reveal disease state and pseudo-progression o...

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Main Author: Bhattacharya, Ipshita
Other Authors: Jacob, Mathews
Format: Others
Language:English
Published: University of Iowa 2017
Subjects:
Online Access:https://ir.uiowa.edu/etd/6058
https://ir.uiowa.edu/cgi/viewcontent.cgi?article=7736&context=etd
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spelling ndltd-uiowa.edu-oai-ir.uiowa.edu-etd-77362019-11-09T09:28:27Z Pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm Bhattacharya, Ipshita Non-invasively reosolving spatial distribution of tissue metabolites serves as a diagnostic tool to in-vivo metabolism thus making magnetic resonance spectroscopic imaging (MRSI) a very useful application. The tissue concentrations of various metabolites reveal disease state and pseudo-progression of tumors. Also, bio-chemical changes manifest much earlier than structural changes that are achieved using standard magnetic resonance imaging(MRI). However, MRSI has not achieved its potential due to several technical challenges that are specic to it. Several technical advances in the eld of MRI does not translate to MRSI. The specic limitations which make MRSI challenging include long scan times, poor spatial resolution, extremely low signal to noise ratio (SNR). In the last few decades, research in MRSI has focused on advanced data acquisition and reconstruction methods, however they cannot achieve high resolution and feasible scan time. Moreover there are several artifacts that lead to increase of spatial resolution not to mention starved SNR. Existing methods cannot deal with these limitations which considerably impacts applications of MRSI. This thesis work we revisit these problems and introduce data acquisition and reconstruction techniques to address several such challenges. In the first part of the thesis we introduce a variable density spiral acquisition technique which achieves high SNR corresponding to metabolites of interest while reducing truncation artifacts. Along with that we develop a novel compartmentalized reconstruction framework to recover high resolution data from lipid unsuppressed data. Avoiding lipid suppression not only reduces scan time and reliability but also improves SNR which is otherwise reduced even further with existing lipid suppression methods. The proposed algorithm exploits the idea that the lipid and metabolite compartment reside in low-dimensional subspace and we use orthogonality priors to reduce overlap of subspaces. We also look at spectral artifacts like Nyquist ghosting which is a common problem with spectral interleaving. Especially in echo-planar spectroscopic imaging (EPSI), one of the most popular MRSI techniques, maintaining a spatial and spectral resolution requires interleaving. Due to scanner inconsistencies spurious peaks arise which makes quantication inecient. In this thesis a novel structural low-rank prior is used to reduce and denoise spectra and achieve high resolution ESPI data. Finally we look at accelerating multi-dimensional spectroscopic problems. Resolving spectra in two dimensions can help study overlapping spectra and achieve more insight. However with an increased dimension the scan time increases. We developed an algorithm for accelerating this method by recovering data from undersampled measurements. We demonstrate the performance in two applications, 2D infra red spectroscopy and 2D MR spectroscopy . The aim of the thesis is to solve these challenges in MRSI from a signal processing perspective and be able to achieve higher resolution data in practical scan time to ultimately help MRSI reach its potential. 2017-05-01T07:00:00Z dissertation application/pdf https://ir.uiowa.edu/etd/6058 https://ir.uiowa.edu/cgi/viewcontent.cgi?article=7736&context=etd Copyright © 2017 Ipshita Bhattacharya Theses and Dissertations eng University of IowaJacob, Mathews Low-rank based algorithms Magnetic Resonance Imaging Optimization Algorithm Spectroscopy Structured low-rank Electrical and Computer Engineering
collection NDLTD
language English
format Others
sources NDLTD
topic Low-rank based algorithms
Magnetic Resonance Imaging
Optimization Algorithm
Spectroscopy
Structured low-rank
Electrical and Computer Engineering
spellingShingle Low-rank based algorithms
Magnetic Resonance Imaging
Optimization Algorithm
Spectroscopy
Structured low-rank
Electrical and Computer Engineering
Bhattacharya, Ipshita
Pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm
description Non-invasively reosolving spatial distribution of tissue metabolites serves as a diagnostic tool to in-vivo metabolism thus making magnetic resonance spectroscopic imaging (MRSI) a very useful application. The tissue concentrations of various metabolites reveal disease state and pseudo-progression of tumors. Also, bio-chemical changes manifest much earlier than structural changes that are achieved using standard magnetic resonance imaging(MRI). However, MRSI has not achieved its potential due to several technical challenges that are specic to it. Several technical advances in the eld of MRI does not translate to MRSI. The specic limitations which make MRSI challenging include long scan times, poor spatial resolution, extremely low signal to noise ratio (SNR). In the last few decades, research in MRSI has focused on advanced data acquisition and reconstruction methods, however they cannot achieve high resolution and feasible scan time. Moreover there are several artifacts that lead to increase of spatial resolution not to mention starved SNR. Existing methods cannot deal with these limitations which considerably impacts applications of MRSI. This thesis work we revisit these problems and introduce data acquisition and reconstruction techniques to address several such challenges. In the first part of the thesis we introduce a variable density spiral acquisition technique which achieves high SNR corresponding to metabolites of interest while reducing truncation artifacts. Along with that we develop a novel compartmentalized reconstruction framework to recover high resolution data from lipid unsuppressed data. Avoiding lipid suppression not only reduces scan time and reliability but also improves SNR which is otherwise reduced even further with existing lipid suppression methods. The proposed algorithm exploits the idea that the lipid and metabolite compartment reside in low-dimensional subspace and we use orthogonality priors to reduce overlap of subspaces. We also look at spectral artifacts like Nyquist ghosting which is a common problem with spectral interleaving. Especially in echo-planar spectroscopic imaging (EPSI), one of the most popular MRSI techniques, maintaining a spatial and spectral resolution requires interleaving. Due to scanner inconsistencies spurious peaks arise which makes quantication inecient. In this thesis a novel structural low-rank prior is used to reduce and denoise spectra and achieve high resolution ESPI data. Finally we look at accelerating multi-dimensional spectroscopic problems. Resolving spectra in two dimensions can help study overlapping spectra and achieve more insight. However with an increased dimension the scan time increases. We developed an algorithm for accelerating this method by recovering data from undersampled measurements. We demonstrate the performance in two applications, 2D infra red spectroscopy and 2D MR spectroscopy . The aim of the thesis is to solve these challenges in MRSI from a signal processing perspective and be able to achieve higher resolution data in practical scan time to ultimately help MRSI reach its potential.
author2 Jacob, Mathews
author_facet Jacob, Mathews
Bhattacharya, Ipshita
author Bhattacharya, Ipshita
author_sort Bhattacharya, Ipshita
title Pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm
title_short Pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm
title_full Pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm
title_fullStr Pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm
title_full_unstemmed Pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm
title_sort pushing the limits of spectroscopic imaging using novel low-rank based reconstruction algorithm
publisher University of Iowa
publishDate 2017
url https://ir.uiowa.edu/etd/6058
https://ir.uiowa.edu/cgi/viewcontent.cgi?article=7736&context=etd
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