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1. Superconducting and low temperature RF Coils for Ultra-Low-Field MRI: A Study on SNR Performance

Author

Bhosale, Aditya A, Payne, Komlan, and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

This study incorporates electromagnetic simulations to assess the performance of multi-turn solenoid coils for ultra-low field MR imaging with various conductor materials (superconducting material, low-temperature copper, and room-temperature copper) across different human samples (elbow, knee, and brain). At 70 mT, superconducting materials performed significantly better than both room-temperature and low-temperature copper. The high Q-factor of the superconducting material indicates lower energy loss, which is useful for MR imaging. Furthermore, B1+ field efficiency increased significantly with superconducting materials, indicating superior performance. SNR evaluations revealed that materials with higher conductivity significantly improve SNR, which is critical for producing high-quality MR images. These results show that superconducting and low-temperature copper materials can significantly improve MR imaging quality at ultra-low fields, which has important implications for coil design and optimization., Comment: 26 pages, 7 figures, 3 tables

Published
2024

2. Quantitative Evaluation of Microstrip, Dipole, and L/C Loop pTx Arrays for UHF MR Imaging

Author

De, Debolina, Bhosale, Aditya A., and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

Ultra-high field MRI (7T+) unlocks a new era of brain research with superior resolution and signal-to-noise. Capturing intricate neural activity and detailed soft tissue pathology, this technology, coupled with advanced RF coil arrays, holds immense potential for clinical diagnosis and discovery. For high-field body imaging, microstrip resonators and dipole arrays for high-field body imaging show promise due to high-frequency operation and improved decoupling. Microstrip arrays excel in compactness, reduced radiation loss, and customizable lengths. Dipole arrays excel in deeper body penetration. Shorter wavelengths at ultrahigh fields can cause image inhomogeneity and elevated SAR. Multichannel transmit arrays address these issues. This research compares three common array types (L/C loop, microstrip, dipole) using CST Studio simulations to evaluate electric/magnetic fields and decoupling. This can guide RF array selection for ultrahigh field MRI.

Published
2024

3. Multimodal surface coils for low-field MR imaging

Author

Zhao, Yunkun, Bhosale, Aditya A, and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

Leveraging the potential of low-field Magnetic Resonance Imaging (MRI), our study introduces the multimodal surface RF coil, a design tailored to overcome the limitations of conventional coils in this context. The inherent challenges of low-field MRI, notably suboptimal signal-to-noise ratio (SNR) and the need for specialized RF coils, are effectively addressed by our novel design. The multimodal surface coil is characterized by a unique assembly of resonators, optimized for both B1 efficiency and low-frequency tuning capabilities, essential for low-field applications. This paper provides a thorough investigation of the conceptual framework, design intricacies, and bench test validation of the multimodal surface coil. Through detailed simulations and comparative analyses, we demonstrate its superior performance in terms of B1 field efficiency, outperforming conventional surface coils.

Published
2023

4. Electric Field and SAR Reduction in High Impedance RF Arrays by Using High Permittivity Materials for 7T MR Imaging

Author

Bhosale, Aditya Ashok, Zhao, Yunkun, and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

Higher frequencies and shorter wavelengths present significant design issues at ultra-high fields, making multi-channel array setup a critical component for ultra-high field MR imaging. The requirement for multi-channel arrays, as well as ongoing efforts to increase the number of channels in an array, are always limited by the major issue known as inter-element coupling. This coupling affects the current and field distribution, noise correlation between channels, and frequency of array elements, lowering imaging quality and performance. To realize the full potential of UHF MRI, we must ensure that the coupling between array elements is kept to a minimum. High-impedance coils allow array systems to completely realize their potential by providing optimal isolation while requiring minimal design modifications. These minor design changes, which demand the use of low capacitance on the conventional loop to induce elevated impedance, result in a significant safety hazard that cannot be overlooked. High electric fields are formed across these low capacitance lumped elements, which may result in higher SAR values in the imaging subject, depositing more power and, ultimately, providing a greater risk of tissue heating-related injury to the human sample. We propose an innovative method of utilizing high-dielectric material to effectively reduce electric fields and SAR values in the imaging sample while preserving the B1 efficiency and inter-element decoupling between the array elements to address this important safety concern with minimal changes to the existing array design comprising high-impedance coils., Comment: 12 pages, 18 figures, 2 tables

Published
2023

5. Coupled stack-up volume RF coils for low-field MR imaging

Author

Zhao, Yunkun, Bhosale, Aditya A, and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

The advent of low field open magnetic resonance imaging (MRI) systems has greatly expanded the accessibility of MRI technology to meet a wide range of patient needs. However, the inherent challenges of low-field MRI, such as limited signal-to-noise ratios and limited availability of dedicated RF coil, have prompted the need for innovative coil designs that can improve imaging quality and diagnostic capabilities. In response to these challenges, we introduce the coupled stack-up volume coil, a novel RF coil design that addresses the shortcomings of conventional birdcage in the context of low field open MRI. The proposed coupled stack-up volume coil design utilizes a unique architecture that optimizes both transmit/receive efficiency and RF field homogeneity and offers the advantage of a simple design and construction, making it a practical and feasible solution for low field MRI applications. This paper presents a comprehensive exploration of the theoretical framework, design considerations, and experimental validation of this innovative coil design. Through rigorous analysis and empirical testing, we demonstrate the superior performance of the coupled stack-up volume coil in achieving improved transmit/receive efficiency and more uniform magnetic field distribution compared to traditional birdcage coils., Comment: 23 pages, 9 Figures

Published
2023

6. Dual-tuned Coaxial-transmission-line RF coils for Hyperpolarized 13C and Deuterium 2H Metabolic MRS Imaging at Ultrahigh Fields

Author

Payne, Komlan, Zhao, Yunkun, Bhosale, Aditya Ashok, and Zhang, Xiaoliang

Subjects
Physics - Medical Physics, Electrical Engineering and Systems Science - Systems and Control
Abstract

$Objective:$ Information on the metabolism of tissues in both healthy and diseased states plays a significant role in the detection and understanding of tumors, neurodegenerative diseases, diabetes, and other metabolic disorders. Hyperpolarized carbon-13 magnetic resonance imaging ($^{13}$C-HPMRI) and deuterium metabolic imaging ($^2$H-DMI) are two emerging X-nuclei used as practical imaging tools to investigate tissue metabolism. However due to their low gyromagnetic ratios ($\gamma_{13C}$ = 10.7 MHz/T; $\gamma_{2H}$ = 6.5 MHz/T) and natural abundance, such method required a sophisticated dual-tuned radiofrequency (RF) coil. $ Methods:$ Here, we report a dual-tuned coaxial transmission line (CTL) RF coil agile for metabolite information operating at 7T with independent tuning capability. The design analysis has demonstrated how both resonant frequencies can be individually controlled by simply varying the constituent of the design parameters. $Results:$ Numerical results have demonstrated a broadband tuning range capability, covering most of the X-nucleus signal, especially the $^{13}$C and $^2$H spectra at 7T. Furthermore, in order to validate the feasibility of the proposed design, both dual-tuned $^1$H/$^{13}$C and $^1$H/$^2$H RF coils are fabricated using a semi-flexible RG-405 .086" coaxial cable and bench test results (scattering parameters and magnetic field efficiency/distribution) are successfully obtained. $Conclusion:$ The proposed dual-tuned RF coils reveal highly effective magnetic field obtained from both proton and heteronuclear signal which is crucial for accurate and detailed imaging. $Significance:$ The successful development of this new dual-tuned RF coil technique would provide a tangible and efficient tool for ultrahigh field metabolic MR imaging., Comment: 10 pages, 9 figures

Published
2023

7. Double Cross Magnetic Wall Decoupling for Quadrature Transceiver RF Array Coils using Common-Mode Differential-mode Resonators

Author

Payne, Komlan, Bhosale, Aditya Ashok, and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

In contrast to linearly polarized RF coil arrays, quadrature transceiver coil arrays are capable of improving signal-to-noise ratio (SNR), spatial resolution and parallel imaging performance. Owing to a reduced excitation power, low specific absorption rate can be also obtained using quadrature RF coils. However, due to the complex nature of their structure and their electromagnetic proprieties, it is challenging to achieve sufficient electromagnetic decoupling while designing multichannel quadrature RF coil arrays, particularly at ultrahigh fields. In this work, we proposed a double cross magnetic wall decoupling for quadrature transceiver RF arrays and implemented the decoupling method on common-mode differential mode quadrature (CMDM) quadrature transceiver arrays at ultrahigh field of 7T. The proposed magnetic decoupling wall comprised of two intrinsic decoupled loops is used to reduce the mutual coupling between all the multi-mode current present in the quadrature CMDM array. The decoupling network has no physical connection with the CMDMs' coils giving leverage over size adjustable RF arrays. In order to validate the feasibility of the proposed cross magnetic decoupling wall, systematic studies on the decoupling performance based on the impedance of two intrinsic loops are numerically performed. A pair of quadrature transceiver CMDMs is constructed along with the proposed decoupling network and their scattering matrix is characterized using a network analyzer. The measured results show all the current modes coupling are concurrently suppressed using the proposed cross magnetic wall. Moreover, field distribution, and SNR intensity are numerically obtained for a well-decoupled 8-channel quadrature knee-coil array., Comment: 9 pages, 10 Figures

Published
2022
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8. An Abstraction for Distributed Stencil Computations Using Charm++

Author

Bhosale, Aditya, Fink, Zane, Kale, Laxmikant, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Diehl, Patrick, editor, Schuchart, Joseph, editor, Valero-Lara, Pedro, editor, and Bosilca, George, editor

Published
2024
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9. A Multichannel RF Transceiver Array with mixed L-C loop and microstrip elements for Foot/Ankle MR Imaging at 7T

Author

Bhosale, Aditya, Ying, Leslie, and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

It is technically challenging to design efficient transceiver coil arrays for foot and ankle imaging at ultrahigh fields due to the irregular geometry of the anatomy. Shortened wavelength because of the high operation frequency at ultrahigh fields increases phase variation, leading to inhomogeneous B1 distribution in the imaging sample. In this work, we propose a hybrid design with mixed L-C loops and microstrip resonators for multichannel foot/ankle transceiver arrays at the ultrahigh field of 7T. The proposed transceiver array consists of 14 microstrip resonators and 5 L-C loop coils to cover the entire region of interest of the irregular-shaped foot/ankle with a relatively uniform B1 distribution at 7T. The feasibility and field behavior of the proposed design are systematically investigated numerically., Comment: 8 pages,9 figures

Published
2022

11. High Dielectric Sheet to reduce Electric Fields and Flatten Magnetic Fields in Self-decoupled Radiofrequency coils for MR Imaging

Author

Bhosale, Aditya and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

High impedance RF coils, such as self-decoupled coils, reduce the electromagnetic coupling between the coil elements and eliminates the use of complex decoupling technologies. Although the high impedance design promises excellent decoupling between the coil elements, it also results in high electric fields across the RF coil, leading to potential safety problems during imaging. It also causes B1 field asymmetry, ultimately leading to difficulties in imaging quantification. In this study, we propose and investigate using a high dielectric sheet to reduce the electric fields across the coil and achieve excellent electromagnetic decoupling among the coil elements, thereby ensuring safer MRI at ultra-high fields and maintaining high imaging performance., Comment: 7 pages, 8 figures , Published in 2021 ISMRM & SMRT Annual Meeting & Exhibition

Published
2022

12. Design of a 13-Channel Hybrid Array System for Foot/Ankle Magnetic Resonance Imaging at 7T/300MHz

Author

Bhosale, Aditya, Ying, Leslie, and Zhang, Xiaoliang

Subjects
Physics - Medical Physics
Abstract

Microstrip lines are being used in MR applications due to their unique properties, such as reduced radiation loss, high-frequency capability, and reduced perturbation of sample loading to the RF coil compared to conventional coils. Here, we present the design of the 13-channel hybrid array consisting of 12 Microstrips, 1 volume half birdcage coil placed on the foot/ankle phantom, and high permittivity materials to cover the maximum area of the subject at 7T/300MHz. We demonstrate using electromagnetic simulations, magnetic field distribution, SAR performance, and the coupling performance of the array elements. This work provides an ultrahigh field multichannel RF solution to lower extremity MR imaging with excellent imaging coverage and field uniformity., Comment: 12 pages, 7 figures , Published in 2022 Joint Annual Meeting ISMRM-ESMRMB & ISMRT 31st Annual Meeting. Corresponding author: Xiaoliang Zhang xzhang89@buffalo.edu

Published
2022

15. PySPH: a Python-based framework for smoothed particle hydrodynamics

Author

Ramachandran, Prabhu, Bhosale, Aditya, Puri, Kunal, Negi, Pawan, Muta, Abhinav, Dinesh, A, Menon, Dileep, Govind, Rahul, Sanka, Suraj, Sebastian, Amal S, Sen, Ananyo, Kaushik, Rohan, Kumar, Anshuman, Kurapati, Vikas, Patil, Mrinalgouda, Tavker, Deep, Pandey, Pankaj, Kaushik, Chandrashekhar, Dutt, Arkopal, and Agarwal, Arpit

Subjects
Physics - Computational Physics, Computer Science - Mathematical Software
Abstract

PySPH is an open-source, Python-based, framework for particle methods in general and Smoothed Particle Hydrodynamics (SPH) in particular. PySPH allows a user to define a complete SPH simulation using pure Python. High-performance code is generated from this high-level Python code and executed on either multiple cores, or on GPUs, seamlessly. It also supports distributed execution using MPI. PySPH supports a wide variety of SPH schemes and formulations. These include, incompressible and compressible fluid flow, elastic dynamics, rigid body dynamics, shallow water equations, and other problems. PySPH supports a variety of boundary conditions including mirror, periodic, solid wall, and inlet/outlet boundary conditions. The package is written to facilitate reuse and reproducibility. This paper discusses the overall design of PySPH and demonstrates many of its features. Several example results are shown to demonstrate the range of features that PySPH provides., Comment: 39 pages, 19 figures

Published
2019
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18. Electric field and SAR reduction in high-impedance RF arrays by using high permittivity materials for 7T MR imaging.

Author

Bhosale, Aditya A., Zhao, Yunkun, and Zhang, Xiaoliang

Subjects
*MAGNETIC resonance imaging, *ELECTRIC fields, *PERMITTIVITY, *CURRENT distribution, *SOFT tissue injuries, *MAGNETORESISTANCE
Abstract

In the field of ultra-high field MR imaging, the challenges associated with higher frequencies and shorter wavelengths necessitate rigorous attention to multichannel array design. While the need for such arrays remains, and efforts to increase channel counts continue, a persistent impediment—inter-element coupling—constantly hinders development. This coupling degrades current and field distribution, introduces noise correlation between channels, and alters the frequency of array elements, affecting image quality and overall performance. The goal of optimizing ultra-high field MRI goes beyond resolving inter-element coupling and includes significant safety considerations related to the design changes required to achieve high-impedance coils. Although these coils provide excellent isolation, the higher impedance needs special design changes. However, such changes pose a significant safety risk in the form of strong electric fields across low-capacitance lumped components. This process may raise Specific Absorption Rate (SAR) values in the imaging subject, increasing power deposition and, as a result, the risk of tissue heating-related injury. To balance the requirement of inter-element decoupling with the critical need for safety, we suggest a new solution. Our method uses high-dielectric materials to efficiently reduce electric fields and SAR values in the imaging sample. This intervention tries to maintain B1 efficiency and inter-element decoupling within the existing array design, which includes high-impedance coils. Our method aims to promote the full potential of ultra-high field MRI by alleviating this critical safety concern with minimal changes to the existing array setup. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Advance Security System

Author

Kurundkar, Sangeeta, primary, Bhole, Gaurav, additional, Bele, Shreyash, additional, Bhoge, Bhagyesh, additional, and Bhosale, Aditya, additional

Published
2023
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22. Dual-Tuned Coaxial-Transmission-Line RF Coils for Hyperpolarized 13C and Deuterium 2H Metabolic MRS Imaging at Ultrahigh Fields

Author

Payne, Komlan, Zhao, Yunkun, Bhosale, Aditya Ashok, and Zhang, Xiaoliang

Abstract

Objective: Information on the metabolism of tissues in healthy and diseased states plays a significant role in the detection and understanding of tumors, neurodegenerative diseases, diabetes, and other metabolic disorders. Hyperpolarized carbon-13 magnetic resonance imaging (13C-HPMRI) and deuterium metabolic imaging (2H-DMI) are two emerging X-nuclei used as practical imaging tools to investigate tissue metabolism. However due to their low gyromagnetic ratios (ɣ13C = 10.7 MHz/T; ɣ2H = 6.5 MHz/T) and natural abundance, such method required a sophisticated dual-tuned radiofrequency (RF) coil. Methods: Here, we report a dual-tuned coaxial transmission line (CTL) RF coil agile for metabolite information operating at 7T with independent tuning capability. The design analysis has demonstrated how both resonant frequencies can be individually controlled by simply varying the constituent of the design parameters. Results: Numerical results have demonstrated a broadband tuning range capability, covering most of the X-nucleus signal, especially the 13C and 2H spectra at 7T. Furthermore, in order to validate the feasibility of the proposed design, both dual-tuned 1H/13C and 1H/2H CTLs RF coils are fabricated using a semi-flexible RG-405 .086" coaxial cable and bench test results (scattering parameters and magnetic field efficiency/distribution) are successfully obtained. Conclusion: The proposed dual-tuned RF coils reveal highly effective magnetic field obtained from both proton and heteronuclear signal which is crucial for accurate and detailed imaging. Significance: The successful development of this new dual-tuned RF coil technique would provide a tangible and efficient tool for ultrahigh field metabolic MR imaging.

Published
2024
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24. Dual-tuned Coaxial-transmission-line RF coils with Independent Tuning Capabilities for X-nuclear Metabolic MRS Imaging at Ultrahigh Magnetic Fields

Author

Payne, Komlan, Zhao, Yunkun, Bhosale, Aditya Ashok, and Zhang, Xiaoliang

Subjects
FOS: Electrical engineering, electronic engineering, information engineering, FOS: Physical sciences, Medical Physics (physics.med-ph), Systems and Control (eess.SY), Physics - Medical Physics, Electrical Engineering and Systems Science - Systems and Control
Abstract

Information on the metabolism of tissues in both healthy and diseased states has potential for detecting tumors, neurodegeneration diseases, diabetes, and many metabolic disorders in biomedical studies. Hyperpolarized carbon-13 magnetic resonance imaging (13C-HPMRI) and deuterium metabolic imaging (2H-DMI) are two emerging X-nuclei used as practical imaging tools to investigate tissue metabolism. However due to their low gyromagnetic ratios ($\gamma_{13C}$ = 10.7 MHz/T; $\gamma_{2H}$ = 6.5 MHz/T) and natural abundance, such method required the use of a sophisticated dual-tuned radio frequency (RF) coil where the X-nucleus signal is associated with the proton signal used for anatomical reference. Here, we report a dual-tuned coaxial transmission line (CTL) RF coil agile for metabolite information operating at 7T with independent tuning capability. Analysis based on full-wave simulation has demonstrated how both resonant frequencies can be individually controlled by simply varying the constituent of the design parameters. A broadband tuning range capability is obtained, covering most of the X-nucleus signal, especially the 13C and 2H spectra at 7T. Numerical results has demonstrated the effectiveness of the magnetic field produced by the proposed dual-tuned 1H/13C and 1H/2H CTLs RF coils. Furthermore, in order to validate the feasibility of the proposed design, both dual-tuned CTLs prototypes are designed and fabricated using a semi-flexible RG-405 .086" coaxial cable and bench test results (scattering parameters and magnetic field efficiency/distributions) are successfully obtained., Comment: 9 pages, 7 figures

Published
2023
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26. PySPH: A Python-based Framework for Smoothed Particle Hydrodynamics

Author

Ramachandran, Prabhu, primary, Bhosale, Aditya, additional, Puri, Kunal, additional, Negi, Pawan, additional, Muta, Abhinav, additional, Dinesh, A., additional, Menon, Dileep, additional, Govind, Rahul, additional, Sanka, Suraj, additional, Sebastian, Amal S., additional, Sen, Ananyo, additional, Kaushik, Rohan, additional, Kumar, Anshuman, additional, Kurapati, Vikas, additional, Patil, Mrinalgouda, additional, Tavker, Deep, additional, Pandey, Pankaj, additional, Kaushik, Chandrashekhar, additional, Dutt, Arkopal, additional, and Agarwal, Arpit, additional

Published
2021
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34. Coupled stack-up volume RF coils for low-field open MR imaging.

Author

Zhao Y, Bhosale AA, and Zhang X

Abstract

Background: Low-field open magnetic resonance imaging (MRI) systems, typically operating at magnetic field strengths below 1 Tesla, has greatly expanded the accessibility of MRI technology to meet a wide range of patient needs. However, the inherent challenges of low-field MRI, such as limited signal-to-noise ratios and limited availability of dedicated radiofrequency (RF) coils, have prompted the need for innovative coil designs that can improve imaging quality and diagnostic capabilities., Purpose: In response to these challenges, we introduce the coupled stack-up volume coil, a novel RF coil design that addresses the shortcomings of conventional birdcage in the context of low-field open MRI., Methods: The proposed coupled stack-up volume coil design utilizes a unique architecture that optimizes both transmit/receive efficiency and RF field homogeneity and offers the advantage of a simple design and construction, making it a practical and feasible solution for low-field MRI applications. This paper presents a comprehensive exploration of the theoretical framework, design considerations, and experimental validation of this innovative coil design., Results: We demonstrate the superior performance of the coupled stack-up volume coil in achieving 47.7% higher transmit/receive efficiency and 68% more uniform magnetic field distribution compared to traditional birdcage coils in electromagnetic simulations. Bench tests results show that the B1 field efficiency of coupled stack-up volume coil is 57.3% higher compared with that of conventional birdcage coil., Conclusions: The proposed coupled stack-up volume coil outperforms the conventional birdcage coil in terms of B1 efficiency, imaging coverage, and low-frequency operation capability. This design provides a robust and simple solution to low-field MR RF coil design.

Published
2024
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39. Coupled stack-up volume RF coils for low-field MR imaging.

Author

Zhao Y, Bhosale AA, and Zhang X

Abstract

Motivation: Low-field MRI has garnered significant attention in recent years due to its unique advantages in safety, cost-effectiveness and accessibility. However, lower field strength comes with an inherently lower SNR as its primary limitation., Goals: In this work, we introduce a novel volume RF coil design using coupled stack-up resonators to mitigate this challenge., Approach: To demonstrate the proposed design, we take 0.5T as an example field strength and designed a prototype coupled stack-up volume coil operating in the 20MHz range., Results: Compared to the birdcage coil, the proposed design significantly improves RF field efficiency and homogeneity, ultimately enhancing the performance of low-field MRI., Impact: The proposed stack-up volume coil outperforms the standard birdcage coil in B1 efficiency and field homogeneity at low fields, ultimately improving the performance of low-field MRI and advancing its applications.

Published
2024

40. Dual-Tuned Coaxial-Transmission-Line RF Coils for Hyperpolarized 13 C and Deuterium 2 H Metabolic MRS Imaging at Ultrahigh Fields.

Author

Payne K, Zhao Y, Bhosale AA, and Zhang X

Subjects
Magnetic Resonance Imaging methods, Magnetic Resonance Imaging instrumentation, Magnetic Resonance Spectroscopy instrumentation, Magnetic Resonance Spectroscopy methods, Radio Waves, Deuterium chemistry, Carbon Isotopes, Phantoms, Imaging, Equipment Design
Abstract

Objective: Information on the metabolism of tissues in healthy and diseased states plays a significant role in the detection and understanding of tumors, neurodegenerative diseases, diabetes, and other metabolic disorders. Hyperpolarized carbon-13 magnetic resonance imaging ( 13 C-HPMRI) and deuterium metabolic imaging ( 2 H-DMI) are two emerging X-nuclei used as practical imaging tools to investigate tissue metabolism. However due to their low gyromagnetic ratios (ɣ 13C = 10.7 MHz/T; ɣ 2H = 6.5 MHz/T) and natural abundance, such method required a sophisticated dual-tuned radiofrequency (RF) coil., Methods: Here, we report a dual-tuned coaxial transmission line (CTL) RF coil agile for metabolite information operating at 7T with independent tuning capability. The design analysis has demonstrated how both resonant frequencies can be individually controlled by simply varying the constituent of the design parameters., Results: Numerical results have demonstrated a broadband tuning range capability, covering most of the X-nucleus signal, especially the 13 C and 2 H spectra at 7T. Furthermore, in order to validate the feasibility of the proposed design, both dual-tuned 1 H/ 13 C and 1 H/ 2 H CTLs RF coils are fabricated using a semi-flexible RG-405 .086" coaxial cable and bench test results (scattering parameters and magnetic field efficiency/distribution) are successfully obtained., Conclusion: The proposed dual-tuned RF coils reveal highly effective magnetic field obtained from both proton and heteronuclear signal which is crucial for accurate and detailed imaging., Significance: The successful development of this new dual-tuned RF coil technique would provide a tangible and efficient tool for ultrahigh field metabolic MR imaging.

Published
2024
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43. Multimodal surface coils for small animal MR imaging at ultrahigh fields.

Author

Zhao Y, Bhosale AA, and Zhang X

Abstract

Motivation: High performance RF coils are needed for better SNR so that higher resolution and spectral dispersion can be obtained in small animal MR imaging., Goals: To develop a surface coil with improved SNR over the conventional surface coil for small animal imaging at 7T., Approach: A small animal surface coil is designed based on multimodal surface coil technique. The coil is investigated and compared with conventional surface coil using full-wave electromagnetic simulations., Results: The multimodal surface coil shows superior B1 field efficiency and lower E field over standard coils, indicating a potential to gain SNR and resolution., Impact: The proposed multimodal surface coil can operate at high frequency and provides improved SNR over conventional surface coils at 7T, opening avenues for highly efficient coil design in small animal imaging, ultimately enabling the detection of previously indiscernible physiological details.

Published
2024

44. Electric Field and SAR Reduction in High Impedance RF Arrays by Using High Permittivity Materials for 7T MR Imaging.

Author

Bhosale AA, Zhao Y, and Zhang X

Abstract

Higher frequencies and shorter wavelengths present significant design issues at ultra-high fields, making multi-channel array setup a critical component for ultra-high field MR imaging. The requirement for multi-channel arrays, as well as ongoing efforts to increase the number of channels in an array, are always limited by the major issue known as inter-element coupling. This coupling affects the current and field distribution, noise correlation between channels, and frequency of array elements, lowering imaging quality and performance. To realize the full potential of UHF MRI, we must ensure that the coupling between array elements is kept to a minimum. High-impedance coils allow array systems to completely realize their potential by providing optimal isolation while requiring minimal design modifications. These minor design changes, which demand the use of low capacitance on the conventional loop to induce elevated impedance, result in a significant safety hazard that cannot be overlooked. High electric fields are formed across these low capacitance lumped elements, which may result in higher SAR values in the imaging subject, depositing more power and, ultimately, providing a greater risk of tissue heating-related injury to the human sample. We propose an innovative method of utilizing high-dielectric material to effectively reduce electric fields and SAR values in the imaging sample while preserving the B1 efficiency and inter-element decoupling between the array elements to address this important safety concern with minimal changes to the existing array design comprising high-impedance coils.

Published
2023

45. Coupled stack-up volume RF coils for low-field MR imaging.

Author

Zhao Y, Bhosale AA, and Zhang X

Abstract

The advent of low field open magnetic resonance imaging (MRI) systems has greatly expanded the accessibility of MRI technology to meet a wide range of patient needs. However, the inherent challenges of low-field MRI, such as limited signal-to-noise ratios and limited availability of dedicated RF coil, have prompted the need for innovative coil designs that can improve imaging quality and diagnostic capabilities. In response to these challenges, we introduce the coupled stack-up volume coil, a novel RF coil design that addresses the shortcomings of conventional birdcage in the context of low field open MRI. The proposed coupled stack-up volume coil design utilizes a unique architecture that optimizes both transmit/receive efficiency and RF field homogeneity and offers the advantage of a simple design and construction, making it a practical and feasible solution for low field MRI applications. This paper presents a comprehensive exploration of the theoretical framework, design considerations, and experimental validation of this innovative coil design. Through rigorous analysis and empirical testing, we demonstrate the superior performance of the coupled stack-up volume coil in achieving improved transmit/receive efficiency and more uniform magnetic field distribution compared to traditional birdcage coils.

Published
2023

46. Dual-tuned Coaxial-transmission-line RF coils for Hyperpolarized 13 C and Deuterium 2 H Metabolic MRS Imaging at Ultrahigh Fields.

Author

Payne K, Zhao Y, Bhosale AA, and Zhang X

Abstract

Objective: Information on the metabolism of tissues in healthy and diseased states plays a significant role in the detection and understanding of tumors, neurodegenerative diseases, diabetes, and other metabolic disorders. Hyperpolarized carbon-13 magnetic resonance imaging ( 13 C-HPMRI) and deuterium metabolic imaging ( 2 H-DMI) are two emerging X-nuclei used as practical imaging tools to investigate tissue metabolism. However due to their low gyromagnetic ratios (ɣ 13C = 10.7 MHz/T; ɣ 2H = 6.5 MHz/T) and natural abundance, such method required a sophisticated dual-tuned radiofrequency (RF) coil., Methods: Here, we report a dual-tuned coaxial transmission line (CTL) RF coil agile for metabolite information operating at 7T with independent tuning capability. The design analysis has demonstrated how both resonant frequencies can be individually controlled by simply varying the constituent of the design parameters., Results: Numerical results have demonstrated a broadband tuning range capability, covering most of the X-nucleus signal, especially the 13 C and 2 H spectra at 7T. Furthermore, in order to validate the feasibility of the proposed design, both dual-tuned 1 H/ 13 C and 1 H/ 2 H CTLs RF coils are fabricated using a semi-flexible RG-405 .086" coaxial cable and bench test results (scattering parameters and magnetic field efficiency/distribution) are successfully obtained., Conclusion: The proposed dual-tuned RF coils reveal highly effective magnetic field obtained from both proton and heteronuclear signal which is crucial for accurate and detailed imaging., Significance: The successful development of this new dual-tuned RF coil technique would provide a tangible and efficient tool for ultrahigh field metabolic MR imaging.

Published
2023

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