OBJECTIVE: Deep brain stimulation (DBS) is an effective treatment for movement disorders and a promising therapy for treating epilepsy and psychiatric disorders. Despite its clinical success, the efficiency and selectivity of DBS can be improved. Our objective was to design electrode geometries that increased the efficiency and selectivity of DBS. APPROACH: We coupled computational models of electrodes in brain tissue with cable models of axons of passage (AOPs), terminating axons (TAs), and local neurons (LNs); we used engineering optimization to design electrodes for stimulating these neural elements; and the model predictions were tested in vivo. MAIN RESULTS: Compared with the standard electrode used in the Medtronic Model 3387 and 3389 arrays, model-optimized electrodes consumed 45-84% less power. Similar gains in selectivity were evident with the optimized electrodes: 50% of parallel AOPs could be activated while reducing activation of perpendicular AOPs from 44 to 48% with the standard electrode to 0-14% with bipolar designs; 50% of perpendicular AOPs could be activated while reducing activation of parallel AOPs from 53 to 55% with the standard electrode to 1-5% with an array of cathodes; and, 50% of TAs could be activated while reducing activation of AOPs from 43 to 100% with the standard electrode to 2-15% with a distal anode. In vivo, both the geometry and polarity of the electrode had a profound impact on the efficiency and selectivity of stimulation. SIGNIFICANCE: Model-based design is a powerful tool that can be used to improve the efficiency and selectivity of DBS electrodes.
OBJECTIVE: Deep brain stimulation (DBS) is an effective treatment for movement disorders and a promising therapy for treating epilepsy and psychiatric disorders. Despite its clinical success, the efficiency and selectivity of DBS can be improved. Our objective was to design electrode geometries that increased the efficiency and selectivity of DBS. APPROACH: We coupled computational models of electrodes in brain tissue with cable models of axons of passage (AOPs), terminating axons (TAs), and local neurons (LNs); we used engineering optimization to design electrodes for stimulating these neural elements; and the model predictions were tested in vivo. MAIN RESULTS: Compared with the standard electrode used in the Medtronic Model 3387 and 3389 arrays, model-optimized electrodes consumed 45-84% less power. Similar gains in selectivity were evident with the optimized electrodes: 50% of parallel AOPs could be activated while reducing activation of perpendicular AOPs from 44 to 48% with the standard electrode to 0-14% with bipolar designs; 50% of perpendicular AOPs could be activated while reducing activation of parallel AOPs from 53 to 55% with the standard electrode to 1-5% with an array of cathodes; and, 50% of TAs could be activated while reducing activation of AOPs from 43 to 100% with the standard electrode to 2-15% with a distal anode. In vivo, both the geometry and polarity of the electrode had a profound impact on the efficiency and selectivity of stimulation. SIGNIFICANCE: Model-based design is a powerful tool that can be used to improve the efficiency and selectivity of DBS electrodes.
Authors: C Haberler; F Alesch; P R Mazal; P Pilz; K Jellinger; M M Pinter; J A Hainfellner; H Budka Journal: Ann Neurol Date: 2000-09 Impact factor: 10.422
Authors: H C F Martens; E Toader; M M J Decré; D J Anderson; R Vetter; D R Kipke; Kenneth B Baker; Matthew D Johnson; Jerrold L Vitek Journal: Clin Neurophysiol Date: 2010-08-21 Impact factor: 3.708
Authors: Michael S Okun; Michele Tagliati; Michael Pourfar; Hubert H Fernandez; Ramon L Rodriguez; Ron L Alterman; Kelly D Foote Journal: Arch Neurol Date: 2005-06-13
Authors: Jens Kuhn; Theo O J Gründler; Doris Lenartz; Volker Sturm; Joachim Klosterkötter; Wolfgang Huff Journal: Dtsch Arztebl Int Date: 2010-02-19 Impact factor: 5.594
Authors: Ashutosh Chaturvedi; Christopher R Butson; Scott F Lempka; Scott E Cooper; Cameron C McIntyre Journal: Brain Stimul Date: 2010-04 Impact factor: 8.955
Authors: Lars Timmermann; Michael Schüpbach; Frank Hertel; Elisabeth Wolf; Roberto Eleopra; Angelo Franzini; Domenico Servello; Inger-Marie Skogseid; Jordi Rumia; Antonio Salvador Aliaga; Michael T Barbe; K Amande M Pauls; Jean-Pierre Lin; Elena Moro; Andrew Lloyd; Mohammad Maarouf Journal: Eur Neurol Date: 2013-01-10 Impact factor: 1.710
Authors: Jonathan Viventi; Dae-Hyeong Kim; Leif Vigeland; Eric S Frechette; Justin A Blanco; Yun-Soung Kim; Andrew E Avrin; Vineet R Tiruvadi; Suk-Won Hwang; Ann C Vanleer; Drausin F Wulsin; Kathryn Davis; Casey E Gelber; Larry Palmer; Jan Van der Spiegel; Jian Wu; Jianliang Xiao; Yonggang Huang; Diego Contreras; John A Rogers; Brian Litt Journal: Nat Neurosci Date: 2011-11-13 Impact factor: 24.884
Authors: A Antal; I Alekseichuk; M Bikson; J Brockmöller; A R Brunoni; R Chen; L G Cohen; G Dowthwaite; J Ellrich; A Flöel; F Fregni; M S George; R Hamilton; J Haueisen; C S Herrmann; F C Hummel; J P Lefaucheur; D Liebetanz; C K Loo; C D McCaig; C Miniussi; P C Miranda; V Moliadze; M A Nitsche; R Nowak; F Padberg; A Pascual-Leone; W Poppendieck; A Priori; S Rossi; P M Rossini; J Rothwell; M A Rueger; G Ruffini; K Schellhorn; H R Siebner; Y Ugawa; A Wexler; U Ziemann; M Hallett; W Paulus Journal: Clin Neurophysiol Date: 2017-06-19 Impact factor: 3.708
Authors: James K Trevathan; Ali Yousefi; Hyung Ook Park; John J Bartoletta; Kip A Ludwig; Kendall H Lee; J Luis Lujan Journal: ACS Chem Neurosci Date: 2017-02-06 Impact factor: 4.418
Authors: Lauri J Lehto; Julia P Slopsema; Matthew D Johnson; Artem Shatillo; Benjamin A Teplitzky; Lynn Utecht; Gregor Adriany; Silvia Mangia; Alejandra Sierra; Walter C Low; Olli Gröhn; Shalom Michaeli Journal: J Neural Eng Date: 2017-01-09 Impact factor: 5.379
Authors: Julia P Slopsema; Edgar Peña; Remi Patriat; Lauri J Lehto; Olli Gröhn; Silvia Mangia; Noam Harel; Shalom Michaeli; Matthew D Johnson Journal: J Neural Eng Date: 2018-08-10 Impact factor: 5.379
Authors: Lauri J Lehto; Antonietta Canna; Lin Wu; Alejandra Sierra; Ekaterina Zhurakovskaya; Jun Ma; Clairice Pearce; Maple Shaio; Pavel Filip; Matthew D Johnson; Walter C Low; Olli Gröhn; Heikki Tanila; Silvia Mangia; Shalom Michaeli Journal: Neuroimage Date: 2020-03-18 Impact factor: 6.556
Authors: Chet Preston; Alexander M Alvarez; Andres Barragan; Jennifer Becker; Willard S Kasoff; Russell S Witte Journal: J Neural Eng Date: 2020-02-27 Impact factor: 5.379