Implant‐friendly MRI of deep brain stimulation electrodes at 7 T
暂无分享,去创建一个
[1] E. Atalar,et al. Effect of field strength on RF power deposition near conductive leads: A simulation study of SAR in DBS lead models during MRI at 1.5 T—10.5 T , 2022, bioRxiv.
[2] E. Atalar,et al. A workflow for predicting temperature increase at the electrical contacts of deep brain stimulation electrodes undergoing MRI , 2022, Magnetic resonance in medicine.
[3] G. Metzger,et al. A nine‐channel transmit/receive array for spine imaging at 10.5 T: Introduction to a nonuniform dielectric substrate antenna , 2021, Magnetic resonance in medicine.
[4] Matthew D. Johnson,et al. 7T MRI and Computational Modeling Supports a Critical Role of Lead Location in Determining Outcomes for Deep Brain Stimulation: A Case Report , 2021, Frontiers in Human Neuroscience.
[5] J. Rosenow,et al. Patient’s body composition can significantly affect RF power deposition in the tissue around DBS implants: ramifications for lead management strategies and MRI field-shaping techniques , 2020, Physics in medicine and biology.
[6] T. Moh,et al. Linear Algebra and Its Applications , 2020, Series on University Mathematics.
[7] E. Atalar,et al. Eigenmode analysis of the scattering matrix for the design of MRI transmit array coils , 2020, Magnetic resonance in medicine.
[8] J. Rosenow,et al. Effect of Device Configuration and Patient's Body Composition on the RF Heating and Nonsusceptibility Artifact of Deep Brain Stimulation Implants During MRI at 1.5T and 3T , 2020, Journal of magnetic resonance imaging : JMRI.
[9] F. Seifert,et al. Parallel transmission medical implant safety testbed: Real‐time mitigation of RF induced tip heating using time‐domain E‐field sensors , 2020, Magnetic resonance in medicine.
[10] E. Atalar,et al. Accelerating the co-simulation method for the design of transmit array coils for MRI , 2020, Magnetic Resonance Materials in Physics, Biology and Medicine.
[11] Bastien Guerin,et al. Parallel transmission to reduce absorbed power around deep brain stimulation devices in MRI: Impact of number and arrangement of transmit channels , 2020, Magnetic resonance in medicine.
[12] Angel Torrado-Carvajal,et al. In vivo human head MRI at 10.5T: A radiofrequency safety study and preliminary imaging results , 2019, Magnetic resonance in medicine.
[13] Lawrence L. Wald,et al. Reconfigurable MRI technology for low-SAR imaging of deep brain stimulation at 3T: Application in bilateral leads, fully-implanted systems, and surgically modified lead trajectories , 2019, NeuroImage.
[14] Maria Ida Iacono,et al. The ‘virtual DBS population’: five realistic computational models of deep brain stimulation patients for electromagnetic MR safety studies , 2019, Physics in medicine and biology.
[15] Noam Harel,et al. A simple geometric analysis method for measuring and mitigating RF induced currents on Deep Brain Stimulation leads by multichannel transmission/reception , 2019, NeuroImage.
[16] Guillermo Sapiro,et al. Patient-specific anatomical model for deep brain stimulation based on 7 Tesla MRI , 2018, PloS one.
[17] Thomas Stieglitz,et al. Should patients with brain implants undergo MRI? , 2018, Journal of neural engineering.
[18] L. Wald,et al. Realistic modeling of deep brain stimulation implants for electromagnetic MRI safety studies , 2018, Physics in medicine and biology.
[19] A Pfrommer,et al. Combination of surface and ‘vertical’ loop elements improves receive performance of a human head transceiver array at 9.4 T , 2018, NMR in biomedicine.
[20] Maria Ida Iacono,et al. Local SAR near deep brain stimulation (DBS) electrodes at 64 and 127 MHz: A simulation study of the effect of extracranial loops , 2017, Magnetic resonance in medicine.
[21] Azma Mareyam,et al. Feasibility of using linearly polarized rotating birdcage transmitters and close‐fitting receive arrays in MRI to reduce SAR in the vicinity of deep brain simulation implants , 2017, Magnetic resonance in medicine.
[22] Dirk Voit,et al. 16‐channel bow tie antenna transceiver array for cardiac MR at 7.0 tesla , 2016, Magnetic resonance in medicine.
[23] Peter R Luijten,et al. The fractionated dipole antenna: A new antenna for body imaging at 7 Tesla , 2016, Magnetic resonance in medicine.
[24] Greig Scott,et al. Controlling radiofrequency‐induced currents in guidewires using parallel transmit , 2015, Magnetic resonance in medicine.
[25] Simon J. Graham,et al. Investigation of Parallel Radiofrequency Transmission for the Reduction of Heating in Long Conductive Leads in 3 Tesla Magnetic Resonance Imaging , 2015, PloS one.
[26] J. L. Herraiz,et al. Parallel transmit pulse design for patients with deep brain stimulation implants , 2015, Magnetic resonance in medicine.
[27] R. Turner,et al. A 16‐channel dual‐row transmit array in combination with a 31‐element receive array for human brain imaging at 9.4 T , 2014, Magnetic resonance in medicine.
[28] E. Atalar,et al. Reduction of the radiofrequency heating of metallic devices using a dual‐drive birdcage coil , 2013, Magnetic resonance in medicine.
[29] Yigitcan Eryaman,et al. Reduction of implant RF heating through modification of transmit coil electric field , 2011, Magnetic resonance in medicine.
[30] Aviva Abosch,et al. Effect of the extracranial deep brain stimulation lead on radiofrequency heating at 9.4 Tesla (400.2 MHz) , 2010, Journal of magnetic resonance imaging : JMRI.
[31] Steen Moeller,et al. A 32‐channel lattice transmission line array for parallel transmit and receive MRI at 7 tesla , 2010, Magnetic resonance in medicine.
[32] Steen Moeller,et al. A geometrically adjustable 16‐channel transmit/receive transmission line array for improved RF efficiency and parallel imaging performance at 7 Tesla , 2008, Magnetic resonance in medicine.
[33] Markus Vester,et al. Degenerate mode band‐pass birdcage coil for accelerated parallel excitation , 2007, Magnetic resonance in medicine.
[34] Philip A Starr,et al. Microelectrode-guided implantation of deep brain stimulators into the globus pallidus internus for dystonia: techniques, electrode locations, and outcomes. , 2006, Neurosurgical focus.
[35] Jean A. Tkach,et al. Permanent Neurological Deficit Related to Magnetic Resonance Imaging in a Patient with Implanted Deep Brain Stimulation Electrodes for Parkinson’s Disease: Case Report , 2005, Neurosurgery.
[36] A. Benabid,et al. Five-year follow-up of bilateral stimulation of the subthalamic nucleus in advanced Parkinson's disease. , 2003, The New England journal of medicine.
[37] P. Krack,et al. Deep-brain stimulation of the subthalamic nucleus or the pars interna of the globus pallidus in Parkinson's disease. , 2001, The New England journal of medicine.
[38] A. Benabid,et al. Chronic electrical stimulation of the ventralis intermedius nucleus of the thalamus as a treatment of movement disorders. , 1996, Journal of neurosurgery.
[39] A. Benabid,et al. Effect on parkinsonian signs and symptoms of bilateral subthalamic nucleus stimulation , 1995, The Lancet.
[40] R. Bansal,et al. Antenna theory; analysis and design , 1984, Proceedings of the IEEE.
[41] Kamil Ugurbil,et al. Evaluation of a 16-Channel Transceiver Loop + Dipole Antenna Array for Human Head Imaging at 10.5 Tesla , 2020, IEEE Access.
[42] E. Eskandar,et al. Mechanisms of deep brain stimulation. , 2016, Journal of neurophysiology.
[43] K. Ugurbil,et al. Very Fast Multi Channel B 1 Calibration at High Field in the Small Flip Angle Regime , 2008 .
[44] Ergin Atalar,et al. of the 23 rd Annual EMBS International Conference , October 25-28 , Istanbul , Turkey RF Safety of Wires in Interventional MRI : Using a Safety Index , 2004 .
[45] C. Balanis. Advanced Engineering Electromagnetics , 1989 .