Effect of brain shift on the creation of functional atlases for deep brain stimulation surgery
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Talairach J, Tournoux P (1988) Co-planar stereotaxic atlas of the human brain. Thieme Publishing Group, New York
Schaltenbrand G, Wahren W (1977) Atlas for stereotaxy of the human brain. Thieme Publishing Group, New York
Yelnik J, Bardinet E, Dormont D, Malandain G, Ourselin S, Tandé D, Karachi C, Ayache N, Cornu P, Agid Y (2007) A three-dimensional, histological and deformable atlas of the human basal ganglia. I. Atlas construction based on immunohistochemical and MRI data. Neuroimage 34: 618–638
Bardinet E, Bhattacharjee M, Dormont D, Pidoux B, Malandain G, Schüpbach M, Ayache N, Cornu P, Agid Y, Yelnik J (2009) A three-dimensional histological atlas of the human basal ganglia. II. Atlas deformation strategy and evaluation in deep brain stimulation for Parkinson disease. J Neurosurg 110: 208–219
Chakravarty MM, Bertrand G, Hodge CP, Sadikot AF, Collins DL (2006) The creation of a brain atlas for image guided neurosurgery using serial histological data. Neuroimage 30(2): 359–376
Chakravarty MM, Sadikot AF, Mongia S, Bertrand G, Collins DL (2006) Towards a multi-modal atlas for neurosurgical planning. Lecture notes in computer science (MICCAI), vol 4191, p 389–396
Plaha P, Ben-Shlomo Y, Patel NK, Gill SS (2006) Stimulation of the caudal zona incerta is superior to stimulation of the subthalamic nucleus in improving contralateral parkinsonism. Brain 129: 1732–1747
Maks CB, Butson CR, Walter BL, Vitek JL, McIntyre CC (2009) Deep brain stimulation activation volumes and their association with neurophysiological mapping and therapeutic outcomes. Neurol Neurosurg Psychiatry, Online: 16 Jan, 2009. doi: 10.1136/jnnp.2007.126219
Andrade-Souza YM, Schwalb JM, Hamani C, Eltahawy H, Hoque T, Saint-Cyr J, Lozano AM (2008) Comparison of three methods of targeting the subthalamic nucleus for chronic stimulation in Parkinson’s disease. Neurosurgery 62(2): 875–883
Hamani C, Richter EO, Andrade-Souza Y, Hutchison W, Saint-Cyr JA, Lozano AM (2005) Correspondence of microelectrode mapping with magnetic resonance imaging for subthalamic nucleus procedures. Surg Neurol 63(3): 249–253
Tasker RR, Organ LW, Hawrylyshyn PA (1982) The thalamus and midbrain of man. Charles C Thomas, Springfield
Finnis KW, Starreveld YP, Parrent AG, Sadikot AF, Peters TM (2003) Three dimensional database of subcortical dlectrophysiology for dmage-guided stereotactic functional neurosurgery. IEEE Trans Med Imaging 22(11): 93–104
Finnis KW, Starreveld YP, Parrent AG, Sadikot AF, Peters TM (2002) Application of a population based electrophysiological database to the planning and guidance of deep brain stereotactic neurosurgery. In: MICCAI
Nowinski WL, Belov D, Benabid AL (2003) An algorithm for rapid calculation of a probabilistic functional atlas of subcortical structures from electrophysiological data collected during functional neurosurgery procedures. Neuroimage 18: 143–155
Nowinski WL, Belov D, Pollak P, Benabid AL (2005) Statistical analysis of 168 bilateral subthalamic nucleus implantations by means of the probabilistic functional atlas. Neurosurgery 57(4): 319–330
Nowinski WL (2008) Towards construction of an ideal stereotactic brain atlas. Acta Neurochir (Wien) 150(1):1–13; discussion 13:14
Guo T, Finnis KW, Parrent AG, Peters TM (2005) Development and application of functional databases for planning deepbrain neurosurgical procedures. Lecture notes in computer science (MICCAI), vol 3749, pp 835–842
Guo T, Finnis KW, Parrent AG, Peters TM (2006) Visualization and navigation system development and application for stereotactic deep-brain neurosurgeries. Comput Aided Surg 11(5): 231–239
Toga AW, Thompson PM, Mori S, Amunts K, Zilles K (2006) Towards multimodal atlases of the human brain. Nat Rev Neurosci 7(12): 952–966
Castro FJ, Pollo C, Cuisenaire O, Villemure J-G, Thiran J-P (2006) Validation of experts versus atlas-based and automatic registration methods for subthalamic nucleus targeting on MRI. Int J Comput Assisted Radiol Surg 1(1): 5–12
Castro FJ, Pollo C, Meuli R, Maeder P, Cuisenaire O, Cuadra MB, Villemure J-G, Thiran J-P (2006) A cross validation study of deep brain stimulation targeting: from experts to atlas-based, segmentation-based and automatic registration algorithms. IEEE Trans Med Imaging 25(11): 1440–1450
D’Haese P-F, Cetinkaya E, Konrad PE, Kao C, Dawant BM (2005) Computer-aided placement of deep brain stimulators: from planning to intraoperative guidance. IEEE Trans Med Imaging 24(11): 1469–1478
D’Haese P-F, Pallavaram S, Niermann K, Spooner J, Kao C, Konrad PE, Dawant BM (2005) Automatic selection of DBS target points using multiple electrophysiological atlases. LNCS (MICCAI) 3750: 427–434
Dawant BM, D’Haese P-F, Pallavaram S, Li R, Yu H, Spooner J, Davis T, Kao C, Konrad PE (2007) The VU-DBS project: integrated and computer-assisted planning, intra-operative placement, and post-operative programming of deep-brain stimulators. In: SPIE medical imaging 2007: visualization and image-guided procedures, vol 6509, pp 650–907
Pallavaram S, D’Haese P-F, Kao C, Yu H, Remple M, Neimat JS, Konrad PE, Dawant BM (2008) A new method for creating electrophysiological maps for DBS surgery and their application to surgical guidance. Lecture notes in computer science (MICCAI), Part1, vol 5241, pp 670–677
Guo T, Finnis KW, Deoni SCL, Parrent AG, Peters TM (2006) Comparison of different targeting methods for subthalamic nucleus deep brain stimulation. Lecture notes in computer science (MICCAI), vol 4190, pp 768–775
Gerdes FU, Klein G, Nadjmi M, Schaltenbrand G (1975) X-ray studies of the brain as a basis for stereotaxy (author’s transl). J Neurol 210: 183–190
Hariz MI, Bergenheim AT, Fodstad H (1993) Air-ventriculography provokes an anterior displacement of the third ventricle during functional stereotactic procedures. Acta Neurochir (Wien) 123: 147–152
Winkler D, Tittgemeyer M, Schwarz J, Preul C, Strecker K, Meixensberger J (2005) The first evaluation of brain shift during functional neurosurgery by deformation field analysis. J Neurol Neurosurg Psychiatry 76: 1161–1163
Miyagi Y, Shima F, Sasaki T (2007) Brain shift: an error factor during implantation of deep brain stimulation electrodes. Neurosurgery 107: 989–997
Khan MF, Mewes K, Gross RE, Škrinjar O (2008) Assessment of brain shift related to deep brain stimulation surgery. Stereotact Funct Neurosurg 86: 44–53
Halpern CH, Danish SF, Baltuch GH, Jaggi JL (2008) Brain shift during deep brain stimulation surgery for Parkinson’s disease. Stereotact Funct Neurosurg 86: 37–43
Fitzpatrick JM, Konrad PE, Nickele C, Cetinkaya E (2005) Accuracy of customized miniature stereotactic platforms. Stereotact Funct Neurosurg 83: 25–31
Balachandran R, Mitchell JE, Dawant BM, Fitzpatrick JM (2009) Accuracy evaluation of MicroTargetingTM platforms for deep-brain stimulation using virtual targets. IEEE Trans Biomed Eng 56(1): 37–44
D’Haese P-F, Pallavaram S, Yu H, Spooner J, Konrad PE, Dawant BM (2006) Deformable physiological atlas-based programming of deep brain stimulators: a feasibility study. Lecture notes in computer science (WBIR), vol 4057. Utrecht, The Netherlands, pp 144–150
Rohde GK, Aldroubi A, Dawant BM (2003) The adaptive bases algorithm for intensity-based nonrigid image registration. IEEE Trans Med Imaging 22(11): 1470–1479
Maes F, Collignon A, Suetens P (1997) Multimodality image registration by maximization of mutual information. in IEEE Trans Med Imaging 16(2): 187–198
Wells WM, Viola P, Atsumi H, Nakajima S, Kikinis R (1996) Multi-modal volume registration by maximization of mutual information. Med Image Anal 1(1): 35–52
Pluim JP, Maintz JB, Viergever MA (2003) Mutual-information-based registration of medical images: a survey. IEEE Trans Med Imaging 22(8): 986–1004
Rosenbaum BP, D’Haese P-F, Yu H, Pallavaram S, Dawant BM, Neimat JS, Konrad PE (2008) Brain shift during deep brain stimulation surgery correlates directly to pneumocephalus and inversely to age. In: American Society of Sterotactic and Functional Neurosurgery (ASSFN) Biennial meeting Vancouver, BC, Canada
Butson CR, McIntyre CC (2008) Current steering to control the volume of tissue activated during deep brain stimulation. Brain Stimul 1(1): 7–15
Pallavaram S, Dawant BM, Koyama T, Yu H, Neimat JS, Konrad PE, D’Haese P-F (2009) Validation of a fully automatic method for the routine selection of the anterior and posterior commissures in MR images. J Stereotact Funct Neurosurg 87: 148–154