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ORCIDLaleh Golestanirad
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2020 – today
- 2024
[c24]Yalcin Tur, Jasmine Vu, Selam Waktola, Alpay Medetalibeyoglu, Laleh Golestanirad, Ulas Bagci:
Prediction of MRI-Induced Power Absorption in Patients with DBS Leads. CBMS 2024: 490-495- [c23]Tayeb Zaidi, Francesca Marturano, Giorgio Bonmassar, Laleh Golestanirad:
Reduction of Medical Device Heating During Mri At 1.5 T and 3 T: Design and Experimental Validation of A New Lead Construct. ISBI 2024: 1-5 - 2023
- [c22]Bhumi Bhusal, Fuchang Jiang, Jasmine Vu, Pia Sanpitak, Laleh Golestanirad:
Implants talk to each-other: RF heating changes when two DBS leads are present simultaneously during MRI. EMBC 2023: 1-5 - [c21]Fuchang Jiang, Kaylee R. Henry, Bhumi Bhusal, Gregory Webster, Giorgio Bonmassar, Daniel Kim, Laleh Golestanirad:
RF-induced heating of capped and uncapped abandoned epicardial leads during MRI at 1.5 T and 3 T. EMBC 2023: 1-5 - [c20]Pia Sanpitak, Bhumi Bhusal, Jasmine Vu, Laleh Golestanirad:
Low-field MRI's Spark on Implant Safety: A Closer Look at Radiofrequency Heating. EMBC 2023: 1-5 - [c19]Jasmine Vu, Bhumi Bhusal, Joshua M. Rosenow, Julie Pilitsis, Laleh Golestanirad:
Optimizing the trajectory of deep brain stimulation leads reduces RF heating during MRI at 3 T: Characteristics and clinical translation. EMBC 2023: 1-5 - [c18]Jasmine Vu, Pia Sanpitak, Bhumi Bhusal, Fuchang Jiang, Laleh Golestanirad:
Rapid prediction of MRI-induced RF heating of active implantable medical devices using machine learning. EMBC 2023: 1-4 - [c17]Tayeb Zaidi, Giorgio Bonmassar, Laleh Golestanirad:
Multi-Segment Leads To Reduce RF Heating in MRI: A Computational Evaluation at 1.5T and 3T. EMBC 2023: 1-4 - 2022
- [c16]Kaylee R. Henry, Milina M. Miulli, Behzad Elahi, Joshua M. Rosenow, Mark J. Nolt, Laleh Golestanirad:
Analysis of the intended and actual orientations of directional deep brain stimulation leads across deep brain stimulation systems. EMBC 2022: 1725-1728 - [c15]Noa B. Nuzov
, Bhumi Bhusal, Kaylee R. Henry, Fuchang Jiang, Joshua M. Rosenow, Behzad Elahi, Laleh Golestanirad:
True location of deep brain stimulation electrodes differs from what is seen on postoperative magnetic resonance images: An anthropomorphic phantom study. EMBC 2022: 1863-1866 - [c14]Fuchang Jiang, Bhumi Bhusal, Pia Sanpitak, Gregory Webster, Andrada Popescu, Daniel Kim, Giorgio Bonmassar, Laleh Golestanirad:
A comparative study of MRI-induced RF heating in pediatric and adult populations with epicardial and endocardial implantable electronic devices. EMBC 2022: 4014-4017 - [c13]Bhumi Bhusal, Fuchang Jiang, Daniel Kim, Kyungpyo Hong, Michael C. Monge, Gregory Webster, Giorgio Bonmassar, Laleh Golestanirad:
The Position and Orientation of the Pulse Generator Affects MRI RF Heating of Epicardial Leads in Children. EMBC 2022: 5000-5003 - 2021
- [c12]Can Zheng, Xinlu Chen, Bach Thanh Nguyen, Pia Sanpitak, Jasmine Vu, Ulas Bagci, Laleh Golestanirad:
Predicting RF Heating of Conductive Leads During Magnetic Resonance Imaging at 1.5 T: A Machine Learning Approach*. EMBC 2021: 4204-4208 - [c11]Jasmine Vu, Bhumi Bhusal, Joshua M. Rosenow, Julie Pilitsis, Laleh Golestanirad:
Modifying surgical implantation of deep brain stimulation leads significantly reduces RF-induced heating during 3 T MRI. EMBC 2021: 4978-4981 - [c10]Pia Sanpitak, Bhumi Bhusal, Bach Thanh Nguyen, Jasmine Vu, Kelvin Chow, Xiaoming Bi, Laleh Golestanirad:
On the accuracy of Tier 4 simulations to predict RF heating of wire implants during magnetic resonance imaging at 1.5 T. EMBC 2021: 4982-4985 - [c9]Bach Thanh Nguyen, Bhumi Bhusal, Kate Fawcett, Laleh Golestanirad:
Radiofrequency heating of retained cardiac leads during magnetic resonance imaging at 1.5 T and 3 T. EMBC 2021: 4986-4989 - [c8]Fuchang Jiang, Behzad Elahi, Mohit Saxena, Ilknur Telkes, Marisa DiMarzio, Julie G. Pilitsis, Laleh Golestanirad:
Patient-specific modeling of the volume of tissue activated (VTA) is associated with clinical outcome of DBS in patients with an obsessive-compulsive disorder. EMBC 2021: 5889-5892 - 2020
- [c7]Fuchang Jiang, Nguyen Tran Bach, Behzad Elahi, Julie Pilitsis, Laleh Golestanirad:
Effect of Biophysical Model Complexity on Predictions of Volume of Tissue Activated (VTA) during Deep Brain Stimulation. EMBC 2020: 3629-3633 - [c6]Bhumi Bhusal, Nguyen Tran Bach, Jasmine Vu, Behzad Elahi, Joshua M. Rosenow, Mark J. Nolt, Julie Pilitsis, Marisa DiMarzio, Laleh Golestanirad:
Device Configuration and Patient's Body Composition Significantly Affect RF Heating of Deep Brain Stimulation Implants During MRI: An Experimental Study at 1.5T and 3T. EMBC 2020: 5192-5197 - [c5]Jasmine Vu, Bhumi Bhusal, Nguyen Tran Bach, Laleh Golestanirad:
Evaluating Accuracy of Numerical Simulations in Predicting Heating of Wire Implants During MRI at 1.5 T. EMBC 2020: 6107-6110 - [c4]Ehsan Kazemivalipour, Jasmine Vu, Stella Lin, Bhumi Bhusal, Bach Thanh Nguyen, John E. Kirsch, Behzad Elahi, Joshua M. Rosenow, Ergin Atalar, Laleh Golestanirad:
RF heating of deep brain stimulation implants during MRI in 1.2 T vertical scanners versus 1.5 T horizontal systems: A simulation study with realistic lead configurations. EMBC 2020: 6143-6146
2010 – 2019
- 2019
- [j3]Laleh Golestanirad, John E. Kirsch, Giorgio Bonmassar, Sean Downs, Behzad Elahi, Alastair J. Martin, Maria Ida Iacono, Leonardo M. Angelone, Boris Keil, Lawrence L. Wald, Julie Pilitsis:
RF-induced heating in tissue near bilateral DBS implants during MRI at 1.5 T and 3T: The role of surgical lead management. NeuroImage 184: 566-576 (2019) - [j2]Ehsan Kazemivalipour, Boris Keil, Alireza Vali, Sunder Rajan, Behzad Elahi, Ergin Atalar, Lawrence L. Wald, Joshua M. Rosenow, Julie Pilitsis, Laleh Golestanirad:
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. NeuroImage 199: 18-29 (2019) - 2018
- [c3]Lucia I. Navarro de Lara, Laleh Golestanirad, Sergey N. Makarov, Jason P. Stockmann, Lawrence L. Wald, Aapo Nummenmaa:
Simulations of a birdcage coil B1+ field on a human body model for designing a 3T multichannel TMS/MRI head coil array. EMBC 2018: 4752-4755 - 2017
- [j1]Laleh Golestanirad, Maria Ida Iacono, Boris Keil, Leonardo M. Angelone, Giorgio Bonmassar, Michael D. Fox, Todd M. Herrington, Elfar Adalsteinsson, Cristen LaPierre, Azma Mareyam, Lawrence L. Wald:
Construction and modeling of a reconfigurable MRI coil for lowering SAR in patients with deep brain stimulation implants. NeuroImage 147: 577-588 (2017) - [c2]Giorgio Bonmassar, Laleh Golestanirad:
EM fields comparison between planar vs. solenoidal μMS coil designs for nerve stimulation. EMBC 2017: 3576-3579 - 2013
- [c1]Laleh Golestanirad, Claudio Pollo, Simon J. Graham:
Analysis of fractal electrodes for efficient neural stimulation. EMBC 2013: 791-794
Coauthor Index
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last updated on 2024-09-09 01:18 CEST by the dblp team
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