OBJECTIVE: This work evaluated the clinical feasibility of transcranial magnetic resonance imaging-guided focused ultrasound surgery. METHODS: Transcranial magnetic resonance imaging-guided focused ultrasound surgery offers a potential noninvasive alternative to surgical resection. The method combines a hemispherical phased-array transducer and patient-specific treatment planning based on acoustic models with feedback control based on magnetic resonance temperature imaging to overcome the effects of the cranium and allow for controlled and precise thermal ablation in the brain. In initial trials in 3 glioblastoma patients, multiple focused ultrasound exposures were applied up to the maximum acoustic power available. Offline analysis of the magnetic resonance temperature images evaluated the temperature changes at the focus and brain surface. RESULTS: We found that it was possible to focus an ultrasound beam transcranially into the brain and to visualize the heating with magnetic resonance temperature imaging. Although we were limited by the device power available at the time and thus seemed to not achieve thermal coagulation, extrapolation of the temperature measurements at the focus and on the brain surface suggests that thermal ablation will be possible with this device without overheating the brain surface, with some possible limitation on the treatment envelope. CONCLUSION: Although significant hurdles remain, these findings are a major step forward in producing a completely noninvasive alternative to surgical resection for brain disorders.
OBJECTIVE: This work evaluated the clinical feasibility of transcranial magnetic resonance imaging-guided focused ultrasound surgery. METHODS: Transcranial magnetic resonance imaging-guided focused ultrasound surgery offers a potential noninvasive alternative to surgical resection. The method combines a hemispherical phased-array transducer and patient-specific treatment planning based on acoustic models with feedback control based on magnetic resonance temperature imaging to overcome the effects of the cranium and allow for controlled and precise thermal ablation in the brain. In initial trials in 3 glioblastomapatients, multiple focused ultrasound exposures were applied up to the maximum acoustic power available. Offline analysis of the magnetic resonance temperature images evaluated the temperature changes at the focus and brain surface. RESULTS: We found that it was possible to focus an ultrasound beam transcranially into the brain and to visualize the heating with magnetic resonance temperature imaging. Although we were limited by the device power available at the time and thus seemed to not achieve thermal coagulation, extrapolation of the temperature measurements at the focus and on the brain surface suggests that thermal ablation will be possible with this device without overheating the brain surface, with some possible limitation on the treatment envelope. CONCLUSION: Although significant hurdles remain, these findings are a major step forward in producing a completely noninvasive alternative to surgical resection for brain disorders.
Authors: Elena A Kaye; Yoni Hertzberg; Michael Marx; Beat Werner; Gil Navon; Marc Levoy; Kim Butts Pauly Journal: Med Phys Date: 2012-10 Impact factor: 4.071
Authors: Jonathan R Sukovich; Charles A Cain; Aditya S Pandey; Neeraj Chaudhary; Sandra Camelo-Piragua; Steven P Allen; Timothy L Hall; John Snell; Zhiyuan Xu; Jonathan M Cannata; Dejan Teofilovic; James A Bertolina; Neal Kassell; Zhen Xu Journal: J Neurosurg Date: 2018-10-01 Impact factor: 5.115