David A Lampman scite author profile

A step-response method has been developed to extract the properties (amplitudes and decay time constants) of intrinsic-eddy-current-sourced magnetic fields generated in whole-body magnetic resonance imaging systems when pulsed field gradients are applied. Exact compensation for the eddy-current effect is achieved through a polynomial rooting procedure and matrix inversion once the 2 N properties of the N-term decay process are known. The output of the inversion procedure yields the required characteristics of the filter for spectrum magnitude and phase equalization. The method is described for the general case along with experimental results for one-, two-, and three-term inversions. The method's usefulness is demonstrated for the usually difficult case of long-term (200-1000-ms) eddy-current compensation. Field-gradient spectral flatness measurements over 30 mHz-100 Hz are given to validate the method.

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RF heating of deep brain stimulation implants in open‐bore vertical MRI systems: A simulation study with realistic device configurations

Golestanirad

Kazemivalipour

Lampman

et al. 2019

Magnetic Resonance in Med

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Purpose Patients with deep brain stimulation (DBS) implants benefit highly from MRI, however, access to MRI is restricted for these patients because of safety hazards associated with RF heating of the implant. To date, all MRI studies on RF heating of medical implants have been performed in horizontal closed‐bore systems. Vertical MRI scanners have a fundamentally different distribution of electric and magnetic fields and are now available at 1.2T, capable of high‐resolution structural and functional MRI. This work presents the first simulation study of RF heating of DBS implants in high‐field vertical scanners. Methods We performed finite element electromagnetic simulations to calculate specific absorption rate (SAR) at tips of DBS leads during MRI in a commercially available 1.2T vertical coil compared to a 1.5T horizontal scanner. Both isolated leads and fully implanted systems were included. Results We found 10‐ to 30‐fold reduction in SAR implication at tips of isolated DBS leads, and up to 19‐fold SAR reduction at tips of leads in fully implanted systems in vertical coils compared to horizontal birdcage coils. Conclusions If confirmed in larger patient cohorts and verified experimentally, this result can open the door to plethora of structural and functional MRI applications to guide, interpret, and advance DBS therapy.

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Comparison of SAR distribution of hip and knee implantable devices in 1.5T conventional cylindrical‐bore and 1.2T open‐bore vertical MRI systems

Fujimoto

Zaidi

Lampman

et al. 2021

Magnetic Resonance in Med

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Magnetic resonance imaging is one of the most widely used diagnostic medical imaging modalities used for various diseases. The most common RF body coil design used in the clinical practice consists of a cylindrical tube-like coil known as a birdcage coil. There is increasing use of high field strengths (1.0 T and higher) open-bore vertical MR systems due to an increase in obesity in the patient population. These open-bore MRI systems consist of a planar-pair RF body coil.

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5485087 Magnetic resonance insert gradient coils with parabolic returns for improved access

Morich¹,

Petropoulos²,

Lampman³

1996

Magnetic Resonance Imaging

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Volume selective 1H NMR spectroscopy with solvent suppression

Lampman¹,

Hurst²,

McNally³

et al. 1986

Magnetic Resonance Imaging

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David A Lampman

Exact temporal eddy current compensation in magnetic resonance imaging systems

RF heating of deep brain stimulation implants in open‐bore vertical MRI systems: A simulation study with realistic device configurations

Comparison of SAR distribution of hip and knee implantable devices in 1.5T conventional cylindrical‐bore and 1.2T open‐bore vertical MRI systems

5485087 Magnetic resonance insert gradient coils with parabolic returns for improved access

Volume selective 1H NMR spectroscopy with solvent suppression

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