Wireless deep-subwavelength metamaterial enabling sub-mm resolution magnetic resonance imaging

Alipour, Akbar; Ünal, Emre; Atalar, Ergin; Demir, Hilmi Volkan

doi:10.1016/j.sna.2018.03.024

Cited by 5 publications

(2 citation statements)

References 44 publications

(50 reference statements)

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“…When designing a resonator, it is desirable to control the capacitance and inductance to tune the resonator 48 , 49 . The built-in distributed capacitance between the metal layers in BCSRR structure used to tune the resonator avoids the need for any lumped element capacitance.…”

Section: Methodsmentioning

confidence: 99%

Improvement of magnetic resonance imaging using a wireless radiofrequency resonator array

Alipour

Seifert

Delman

et al. 2021

Sci Rep

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In recent years, new human magnetic resonance imaging systems operating at static magnetic fields strengths of 7 Tesla or higher have become available, providing better signal sensitivity compared with lower field strengths. However, imaging human-sized objects at such high field strength and associated precession frequencies is limited due to the technical challenges associated with the wavelength effect, which substantially disturb the transmit field uniformity over the human body when conventional coils are used. Here we report a novel passive inductively-coupled radiofrequency resonator array design with a simple structure that works in conjunction with conventional coils and requires only to be tuned to the scanner’s operating frequency. We show that inductive-coupling between the resonator array and the coil improves the transmit efficiency and signal sensitivity in the targeted region. The simple structure, flexibility, and cost-efficiency make the proposed array design an attractive approach for altering the transmit field distribution specially at high field systems, where the wavelength is comparable with the tissue size.

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Section: Methodsmentioning

confidence: 99%

Improvement of magnetic resonance imaging using a wireless radiofrequency resonator array

Alipour

Seifert

Delman

et al. 2021

Sci Rep

Self Cite

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“…Metamaterials are artificial structures with a unique arrangement of elements that can modify the distribution of the electromagnetic (EM) field, rendering them a very promising class of devices for EM engineering. [13][14][15][16][17] They are structures that have several constituent elements in any given direction. Surface-type metamaterials are generally called metafilms or metasurfaces.…”

Section: Introductionmentioning

confidence: 99%

Enhancing the brain MRI at ultra‐high field systems using a meta‐array structure

Alipour,

Seifert,

Delman

et al. 2023

Medical Physics

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BackgroundThe main advantage of ultra‐high field (UHF) magnetic resonance neuroimaging is theincreased signal‐to‐noise ratio (SNR) compared with lower field strength imaging. However, the wavelength effect associated with UHF MRI results in radiofrequency (RF) inhomogeneity, compromising whole brain coverage for many commercial coils. Approaches to resolving this issue of transmit field inhomogeneity include the design of parallel transmit systems (PTx), RF pulse design, and applying passive RF shimming such as high dielectric materials. However, these methods have some drawbacks such as unstable material parameters of dielectric pads, high‐cost, and complexity of PTx systems. Metasurfaces are artificial structures with a unique platform that can control the propagation of the electromagnetic (EM) waves, and they are very promising for engineering EM device. Implementation of meta‐arrays enhancing MRI has been explored previously in several studies.PurposeThe aim of this study was to assess the effect of new meta‐array technology on enhancing the brain MRI at 7T. A meta‐array based on a hybrid structure consisting of an array of broadside‐coupled split‐ring resonators and high‐permittivity materials was designed to work at the Larmor frequency of a 7 Tesla (7T) MRI scanner. When placed behind the head and neck, this construct improves the SNR in the region of the cerebellum,brainstem and the inferior aspect of the temporal lobes.MethodsNumerical electromagnetic simulations were performed to optimize the meta‐array design parameters and determine the RF circuit configuration. The resultant transmit‐efficiency and signal sensitivity improvements were experimentally analyzed in phantoms followed by healthy volunteers using a 7T whole‐body MRI scanner equipped with a standard one‐channel transmit, 32‐channel receive head coil. Efficacy was evaluated through acquisition with and without the meta‐array using two basic sequences: gradient‐recalled‐echo (GRE) and turbo‐spin‐echo (TSE).ResultsExperimental phantom analysis confirmed two‐fold improvement in the transmit efficiency and 1.4‐fold improvement in the signal sensitivity in the target region. In vivo GRE and TSE images with the meta‐array in place showed enhanced visualization in inferior regions of the brain, especially of the cerebellum, brainstem, and cervical spinal cord.ConclusionAddition of the meta‐array to commonly used MRI coils can enhance SNR to extend the anatomical coverage of the coil and improve overall MRI coil performance. This enhancement in SNR can be leveraged to obtain a higher resolution image over the same time slot or faster acquisition can be achieved with same resolution. Using this technique could improve the performance of existing commercial coils at 7T for whole brain and other applications.

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Carbon nanospheres induced high negative permittivity in nanosilver-polydopamine metacomposites

Dong

et al. 2019

Carbon

190

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Wireless deep-subwavelength metamaterial enabling sub-mm resolution magnetic resonance imaging

Cited by 5 publications

References 44 publications

Improvement of magnetic resonance imaging using a wireless radiofrequency resonator array

Improvement of magnetic resonance imaging using a wireless radiofrequency resonator array

Enhancing the brain MRI at ultra‐high field systems using a meta‐array structure

Carbon nanospheres induced high negative permittivity in nanosilver-polydopamine metacomposites

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