A portable single‐sided magnet system for remote NMR measurements of pulmonary function

Dabaghyan, M.; Muradyan, Iga; Hrovat, Alan; Butler, James P.; Frederick, Eric; Zhou, Feng; Kyriazis, Angelos; Hardin, C. Corey; Patz, Samuel; Hrovat, Mirko I.

doi:10.1002/nbm.3149

Cited by 15 publications

(6 citation statements)

References 32 publications

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“…A typical system of off the shelf components may consist of a ZHL-3A+ power amplifier from Mini-Circuits (US$229) fed to the input to an nmrservice.de transcoupler (duplexer) that operates from 0.7 to 1 MHz (US$735) and the return signal amplified using a Mini-Circuits ZFL-500LN (US$93) giving a cost of more than US$1000. Advances in permanent magnet technology has seen report of applications of low field unilateral magnets below 20 mT corresponding to frequencies below 1 MHz [7]. In this work we demonstrate that the current generation of operational amplifiers, in the form of a simple inverting design, can effectively provide the power and preamplifiers in this frequency range and at a fraction of the cost of commercial components.…”

Section: Introductionmentioning

confidence: 67%

Operational Amplifiers Revisited for Low Field Magnetic Resonance Relaxation Time Measurement Electronics

Almazrouei¹,

Newton²,

Morris³

2019

The 6th International Electronic Conference on Sensors and Applications

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Advances in permanent magnet technology has seen more reports of sensor applications of low field magnetic resonance. Whilst most are either in the 10–20 MHz range or in the earth’s field, measurements at below 1 MHz are beginning to become more widespread. This range is below the need for careful radio frequency electronics design but above the audio domain and represents an interesting cross over. Many commercial spectrometers do not include the pulse power amplifier, duplexer and preamplifier as these depend on the frequency range used. In this work we demonstrate that, with the current specifications of the humble operational amplifier, the most simple form of an inverting design using only two resistors and decoupling, can effectively provide this ‘front end’ electronics. The low powers used mean crossed Ge diodes provide an excellent duplexer and it is suitable for battery powered applications.

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Section: Introductionmentioning

confidence: 67%

Operational Amplifiers Revisited for Low Field Magnetic Resonance Relaxation Time Measurement Electronics

Almazrouei¹,

Newton²,

Morris³

2019

The 6th International Electronic Conference on Sensors and Applications

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“…Figure 2b shows the top view of the magnet array. Unlike Dabaghyan et al [16], who made use of a solenoid to interrogate a large sample volume, a planar coil was produced using a milled 75 μm FR4 Printed Circuit Board (PCB) with 5 turns at a line width of 2 mm, with 1mm spacing between tracks, inner and outer coil lengths of 82 mm and 105 mm, respectively, and inner and outer coil widths of 40 mm and 67 mm, respectively, with an epoxy resin coating applied post-production. The coil is also visible in Figure 2b.…”

Section: Methodsmentioning

confidence: 87%

“…In an article by Dabaghyan et al [16], the authors presented a unilateral magnet design which, like the NMR MoUSE, provides a B 0 parallel with the surface of the magnet. Their magnet was constructed from two rectangular arrays of 240 small NdFeB magnets, around 400 mm between centers with a saddle point at around 80 mm above the magnet surface and with a field strength at this point of 10 mT (note that this is more than an order of magnitude smaller than the 0.25 T and above of the profile NMR-MoUSE family).…”

Section: Methodsmentioning

confidence: 99%

NMR CAPIBarA: Proof of Principle of a Low-Field Unilateral Magnetic Resonance System for Monitoring of the Placenta during Pregnancy

et al. 2019

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A growing body of literature shows that the transverse relaxation times of the placenta change during pregnancy and may be an early indicator of disease. Magnetic resonance imaging (MRI) of pregnant women is not, however, currently used frequently despite this evidence. One significant barrier to adoption is the cost of undertaking an MRI scan and the over utilization of existing equipment. Low-field nuclear magnetic resonance (NMR) offers a low-cost alternative, capable of measuring transverse relaxation in a single point in space. Ultrasound imaging (US) is routinely used at several points during pregnancy but is not capable of early detection of pre-eclampsia, for example. It does, however, provide a technique that is capable of locating the placenta with ease. In combination with a single point low-field measurement, localised with ultrasound imaging allows access to this exciting technique without the need for an expensive traditional MRI. In this work, we present a unilateral system (NMR CAPIBarA), operating at a magnetic field of only 18mT, which measures transverse relaxation times at distances from its surface equivalent to the positioning of a human placenta. Data are presented to characterise the system using relation time standards covering the full transverse relaxation time range relevant for the developing placenta, which are also measured on a 1.5 T clinical MRI scanner.

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“…There are two broad classes of optimization target fields: one which consists of a linear static magnetic field gradient perpendicular to the surface of the magnet [ 28 , 32 , 33 , 35 , 41 , 45 , 49 ] or a localized ‘sweet spot’ consisting of a ROI in which the magnetic field is relatively homogeneous in all three dimensions [ 29 , 30 , 34 , 42 , 43 , 48 , 50 ]. In the next section we will use the EA model we developed to find an optimized magnet design solution by varying the relative positions of the individual permanent cubic magnets.…”

Section: Magnet Array Designmentioning

confidence: 99%

Deep neural-network based optimization for the design of a multi-element surface magnet for MRI applications

2022

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We present a combination of a CNN-based encoder with an analytical forward map for solving inverse problems. We call it an encoder-analytic (EA) hybrid model. It does not require a dedicated training dataset and can train itself from the connected forward map in a direct learning fashion. A separate regularization term is not required either, since the forward map also acts as a regularizer. As it is not a generalization model it does not suffer from overfitting. We further show that the model can be customized to either finding a specific target solution or one that follows a given heuristic. As an example, we apply this approach to the design of a multi-element surface magnet for low-field magnetic resonance imaging (MRI). We further show that the EA model can outperform the benchmark genetic algorithm model currently used for magnet design in MRI, obtaining almost 10 times better results.

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A portable single‐sided magnet system for remote NMR measurements of pulmonary function

Cited by 15 publications

References 32 publications

Operational Amplifiers Revisited for Low Field Magnetic Resonance Relaxation Time Measurement Electronics

Operational Amplifiers Revisited for Low Field Magnetic Resonance Relaxation Time Measurement Electronics

NMR CAPIBarA: Proof of Principle of a Low-Field Unilateral Magnetic Resonance System for Monitoring of the Placenta during Pregnancy

Deep neural-network based optimization for the design of a multi-element surface magnet for MRI applications

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