Book contents
- Treatment of Dystonia
- Treatment of Dystonia
- Copyright page
- Contents
- Contributors
- Preface
- 1 Development of the Concept of Dystonia as a Disease, a Syndrome and a Movement Phenomenology
- Section I Basics
- Section II Botulinum Toxin Therapy
- Section III Musician’s Dystonia
- Section IV Psychogenic Dystonia
- Section V Treatment of Paediatric Dystonia
- Section VI Rehabilitation of Dystonia
- Section VII Pharmacotherapy for Dystonia
- Section VIII Surgical Treatment of Dystonia
- Section IX Deep Brain Stimulation for Dystonia
- 62 Functional Mechanisms of Deep Brain Stimulation in Dystonia
- 63 Deep Brain Stimulation for Isolated Generalised Dystonia
- 64 Deep Brain Stimulation for Isolated Focal and Segmental Dystonia
- 65 Deep Brain Stimulation for Meige Syndrome
- 66 Contemporary Thalamotomy for Dystonia
- 67 Deep Brain Stimulation for Myoclonus-Dystonia
- 68 Deep Brain Stimulation for Tardive Dystonia
- 69 Deep Brain Stimulation for Choreoathetosis in Cerebral Palsy
- 70 Deep Brain Stimulation for Other Secondary Dystonias
- 71 The Subthalamic Nucleus as a Deep Brain Stimulation Target for Dystonia
- 72 The Thalamus as a Target for Deep Brain Stimulation in Dystonia
- 73 Dystonia Patients Non-Responsive to Deep Brain Stimulation
- 74 Akinesia Induced by Deep Brain Stimulation
- 75 Programing Deep Brain Stimulation for Treatment of Dystonia
- 76 Complications of Deep Brain Stimulation for Dystonia
- Section X Emerging Therapies for Dystonia
- Section XI Future Trends in Dystonia Therapy
- Book part
- Index
- References
62 - Functional Mechanisms of Deep Brain Stimulation in Dystonia
from Section IX - Deep Brain Stimulation for Dystonia
Published online by Cambridge University Press: 31 May 2018
Book contents
- Treatment of Dystonia
- Treatment of Dystonia
- Copyright page
- Contents
- Contributors
- Preface
- 1 Development of the Concept of Dystonia as a Disease, a Syndrome and a Movement Phenomenology
- Section I Basics
- Section II Botulinum Toxin Therapy
- Section III Musician’s Dystonia
- Section IV Psychogenic Dystonia
- Section V Treatment of Paediatric Dystonia
- Section VI Rehabilitation of Dystonia
- Section VII Pharmacotherapy for Dystonia
- Section VIII Surgical Treatment of Dystonia
- Section IX Deep Brain Stimulation for Dystonia
- 62 Functional Mechanisms of Deep Brain Stimulation in Dystonia
- 63 Deep Brain Stimulation for Isolated Generalised Dystonia
- 64 Deep Brain Stimulation for Isolated Focal and Segmental Dystonia
- 65 Deep Brain Stimulation for Meige Syndrome
- 66 Contemporary Thalamotomy for Dystonia
- 67 Deep Brain Stimulation for Myoclonus-Dystonia
- 68 Deep Brain Stimulation for Tardive Dystonia
- 69 Deep Brain Stimulation for Choreoathetosis in Cerebral Palsy
- 70 Deep Brain Stimulation for Other Secondary Dystonias
- 71 The Subthalamic Nucleus as a Deep Brain Stimulation Target for Dystonia
- 72 The Thalamus as a Target for Deep Brain Stimulation in Dystonia
- 73 Dystonia Patients Non-Responsive to Deep Brain Stimulation
- 74 Akinesia Induced by Deep Brain Stimulation
- 75 Programing Deep Brain Stimulation for Treatment of Dystonia
- 76 Complications of Deep Brain Stimulation for Dystonia
- Section X Emerging Therapies for Dystonia
- Section XI Future Trends in Dystonia Therapy
- Book part
- Index
- References
Summary
A summary is not available for this content so a preview has been provided. Please use the Get access link above for information on how to access this content.
- Type
- Chapter
- Information
- Treatment of Dystonia , pp. 345 - 351Publisher: Cambridge University PressPrint publication year: 2018
References
Alam, M, Sanghera, MK, Schwabe, K, Lutjens, G, Jin, X, Song, J, von Wrangel, C, Stewart, RM, Jankovic, J, Grossman, RG, Darbin, O, Krauss, JK. 2016. Globus pallidus internus neuronal activity: a comparative study of linear and non-linear features in patients with dystonia or Parkinson’s disease. J Neural Transm (Vienna) 123(3):231–240.Google Scholar
Alonso-Frech, F, Zamarbide, I, Alegre, M, Rodriguez-Oroz, MC, Guridi, J, Manrique, M, Valencia, M, Artieda, J, Obeso, JA. 2006. Slow oscillatory activity and levodopa-induced dyskinesias in Parkinson’s disease. Brain 129(Pt 7):1748–1757.Google Scholar
Barow, E, Neumann, WJ, Brucke, C, Huebl, J, Horn, A, Brown, P, Krauss, JK, Schneider, GH, Kuhn, AA. 2014. Deep brain stimulation suppresses pallidal low frequency activity in patients with phasic dystonic movements. Brain 137(Pt 11):3012–3024.CrossRefGoogle ScholarPubMed
Berardelli, A, Rothwell, JC, Day, BL, Marsden, CD. 1985. Pathophysiology of blepharospasm and oromandibular dystonia. Brain 108(Pt 3):593–608.Google Scholar
Brown, P. 2003. Oscillatory nature of human basal ganglia activity: relationship to the pathophysiology of Parkinson’s disease. Mov Disord 18(4):357–363.Google Scholar
Brown, P, Eusebio, A. 2008. Paradoxes of functional neurosurgery: clues from basal ganglia recordings. Mov Disord 23(1):12–20.Google Scholar
Capelle, HH, Blahak, C, Schrader, C, Baezner, H, Kinfe, TM, Herzog, J, Dengler, R, Krauss, JK. 2010. Chronic deep brain stimulation in patients with tardive dystonia without a history of major psychosis. Mov Disord 25(10):1477–1481.Google Scholar
Chen, CC, Kuhn, AA, Trottenberg, T, Kupsch, A, Schneider, GH, Brown, P. 2006a. Neuronal activity in globus pallidus interna can be synchronized to local field potential activity over 3–12 Hz in patients with dystonia. Exp Neurol 202(2):480–486.CrossRefGoogle ScholarPubMed
Chen, CC, Kuhn, AA, Hoffmann, KT, Kupsch, A, Schneider, GH, Trottenberg, T, Krauss, JK, Wohrle, JC, Bardinet, E, Yelnik, J, Brown, P. 2006b. Oscillatory pallidal local field potential activity correlates with involuntary EMG in dystonia. Neurology 66(3):418–420.Google Scholar
Chen, R, Udupa, K. 2009. Measurement and modulation of plasticity of the motor system in humans using transcranial magnetic stimulation. Motor Control 13(4):442–453.Google Scholar
Coubes, P, Roubertie, A, Vayssiere, N, Hemm, S, Echenne, B. 2000. Treatment of DYT1-generalised dystonia by stimulation of the internal globus pallidus. Lancet 355(9222):2220–2221.Google Scholar
Coubes, P, Cif, L, El Fertit, H, Hemm, S, Vayssiere, N, Serrat, S, Picot, MC, Tuffery, S, Claustres, M, Echenne, B, Frerebeau, P. 2004. Electrical stimulation of the globus pallidus internus in patients with primary generalized dystonia: long-term results. J Neurosurg 101(2):189–194.CrossRefGoogle ScholarPubMed
Crowell, AL, Ryapolova-Webb, ES, Ostrem, JL, Galifianakis, NB, Shimamoto, S, Lim, DA, Starr, PA. 2012. Oscillations in sensorimotor cortex in movement disorders: an electrocorticography study. Brain 135(Pt 2):615–630.CrossRefGoogle ScholarPubMed
Edwards, MJ, Huang, YZ, Mir, P, Rothwell, JC, Bhatia, KP. 2006. Abnormalities in motor cortical plasticity differentiate manifesting and nonmanifesting DYT1 carriers. Mov Disord 21(12):2181–2186.CrossRefGoogle ScholarPubMed
Eusebio, A, Pogosyan, A, Wang, S, Averbeck, B, Gaynor, LD, Cantiniaux, S, Witjas, T, Limousin, P, Azulay, JP, Brown, P. 2009. Resonance in subthalamo-cortical circuits in Parkinson’s disease. Brain 132(Pt 8):2139–2150.Google Scholar
Foncke, EM, Bour, LJ, Speelman, JD, Koelman, JH, Tijssen, MA. 2007a. Local field potentials and oscillatory activity of the internal globus pallidus in myoclonus-dystonia. Mov Disord 22(3):369–376.Google Scholar
Foncke, EM, Bour, LJ, van der Meer, JN, Koelman, JH, Tijssen, MA. 2007b. Abnormal low frequency drive in myoclonus-dystonia patients correlates with presence of dystonia. Mov Disord 22(9):1299–1307.Google Scholar
Grips, E, Blahak, C, Capelle, HH, Bazner, H, Weigel, R, Sedlaczek, O, Krauss, JK, Wohrle, JC. 2007. Patterns of reoccurrence of segmental dystonia after discontinuation of deep brain stimulation. J Neurol Neurosurg Psychiatry 78(3):318–320.CrossRefGoogle ScholarPubMed
Groiss, SJ, Elben, S, Reck, C, Voges, J, Wojtecki, L, Schnitzler, A. 2011. Local field potential oscillations of the globus pallidus in Huntington’s disease. Mov Disord 26(14):2577–2578.Google Scholar
Gruber, D, Trottenberg, T, Kivi, A, Schoenecker, T, Kopp, UA, Hoffmann, KT, Schneider, GH, Kuhn, AA, Kupsch, A. 2009. Long-term effects of pallidal deep brain stimulation in tardive dystonia. Neurology 73(1):53–58.Google Scholar
Gruber, D, Kuhn, AA, Schoenecker, T, Kivi, A, Trottenberg, T, Hoffmann, KT, Gharabaghi, A, Kopp, UA, Schneider, GH, Klein, C, Asmus, F, Kupsch, A. 2010. Pallidal and thalamic deep brain stimulation in myoclonus-dystonia. Mov Disord 25(11):1733–1743.Google Scholar
Hammond, C, Bergman, H, Brown, P. 2007. Pathological synchronization in Parkinson’s disease: networks, models and treatments. Trends Neurosci 30(7):357–364.CrossRefGoogle ScholarPubMed
Hung, SW, Hamani, C, Lozano, AM, Poon, YY, Piboolnurak, P, Miyasaki, JM, Lang, AE, Dostrovsky, JO, Hutchison, WD, Moro, E. 2007. Long-term outcome of bilateral pallidal deep brain stimulation for primary cervical dystonia. Neurology 68(6):457–459.Google Scholar
Hutchinson, WD, Levy, R, Dostrovsky, JO, Lozano, AM, Lang, AE. 1997. Effects of apomorphine on globus pallidus neurons in parkinsonian patients. Ann Neurol 42(5):767–775.CrossRefGoogle ScholarPubMed
Hutchison, WD, Lang, AE, Dostrovsky, JO, Lozano, AM. 2003. Pallidal neuronal activity: implications for models of dystonia. Ann Neurol 53(4):480–488.Google Scholar
Ikoma, K, Samii, A, Mercuri, B, Wassermann, EM, Hallett, M. 1996. Abnormal cortical motor excitability in dystonia. Neurology 46(5):1371–1376.Google Scholar
Johnson, MD, Miocinovic, S, McIntyre, CC, Vitek, JL. 2008. Mechanisms and targets of deep brain stimulation in movement disorders. Neurotherapeutics 5(2):294–308.Google Scholar
Krauss, JK. 2002. Deep brain stimulation for dystonia in adults: overview and developments. Stereotact Funct Neurosurg 78(3–4):168–182.Google Scholar
Krauss, JK, Yianni, J, Loher, TJ, Aziz, TZ. 2004. Deep brain stimulation for dystonia. J Clin Neurophysiol 21(1):18–30.CrossRefGoogle ScholarPubMed
Kuhn, AA, Meyer, BU, Trottenberg, T, Brandt, SA, Schneider, GH, Kupsch, A. 2003. Modulation of motor cortex excitability by pallidal stimulation in patients with severe dystonia. Neurology 60(5):768–774.CrossRefGoogle ScholarPubMed
Kuhn, AA, Kupsch, A, Schneider, GH, Brown, P. 2006. Reduction in subthalamic 8–35 Hz oscillatory activity correlates with clinical improvement in Parkinson’s disease. Eur J Neurosci 23(7):1956–1960.Google Scholar
Kuhn, AA, Brucke, C, Schneider, GH, Trottenberg, T, Kivi, A, Kupsch, A, Capelle, HH, Krauss, JK, Brown, P. 2008a. Increased beta activity in dystonia patients after drug-induced dopamine deficiency. Exp Neurol 214(1):140–143.CrossRefGoogle ScholarPubMed
Kuhn, AA, Kempf, F, Brucke, C, Gaynor Doyle, L, Martinez-Torres, I, Pogosyan, A, Trottenberg, T, Kupsch, A, Schneider, GH, Hariz, MI, Vandenberghe, W, Nuttin, B, Brown, P. 2008b. High-frequency stimulation of the subthalamic nucleus suppresses oscillatory beta activity in patients with Parkinson’s disease in parallel with improvement in motor performance. J Neurosci 28(24):6165–6173.CrossRefGoogle ScholarPubMed
Kuncel, AM, Grill, WM. 2004. Selection of stimulus parameters for deep brain stimulation. Clin Neurophysiol 115(11):2431–2441.Google Scholar
Kupsch, A, Benecke, R, Muller, J, Trottenberg, T, Schneider, GH, Poewe, W, Eisner, W, Wolters, A, Muller, JU, Deuschl, G, Pinsker, MO, Skogseid, IM, Roeste, GK, Vollmer-Haase, J, Brentrup, A, Krause, M, Tronnier, V, Schnitzler, A, Voges, J, Nikkhah, G, Vesper, J, Naumann, M, Volkmann, J, Deep-Brain Stimulation for Dystonia Study Group. 2006. Pallidal deep-brain stimulation in primary generalized or segmental dystonia. N Engl J Med 355(19):1978–1990.Google Scholar
Lenz, FA, Byl, NN. 1999. Reorganization in the cutaneous core of the human thalamic principal somatic sensory nucleus (ventral caudal) in patients with dystonia. J Neurophysiol 82(6):3204–3212.Google Scholar
Lenz, FA, Suarez, JI, Metman, LV, Reich, SG, Karp, BI, Hallett, M, Rowland, LH, Dougherty, PM. 1998. Pallidal activity during dystonia: somatosensory reorganisation and changes with severity. J Neurol Neurosurg Psychiatry 65(5):767–770.Google Scholar
Liu, X, Wang, S, Yianni, J, Nandi, D, Bain, PG, Gregory, R, Stein, JF, Aziz, TZ. 2008. The sensory and motor representation of synchronized oscillations in the globus pallidus in patients with primary dystonia. Brain 131(Pt 6):1562–1573.Google Scholar
Marceglia, S, Servello, D, Foffani, G, Porta, M, Sassi, M, Mrakic-Sposta, S, Rosa, M, Barbieri, S, Priori, A. 2010. Thalamic single-unit and local field potential activity in tourette syndrome. Mov Disord 25(3):300–308.Google Scholar
Martella, G, Tassone, A, Sciamanna, G, Platania, P, Cuomo, D, Viscomi, MT, Bonsi, P, Cacci, E, Biagioni, S, Usiello, A, Bernardi, G, Sharma, N, Standaert, DG, Pisani, A. 2009. Impairment of bidirectional synaptic plasticity in the striatum of a mouse model of DYT1 dystonia: role of endogenous acetylcholine. Brain 132(Pt 9):2336–2349.CrossRefGoogle ScholarPubMed
McIntyre, CC, Hahn, PJ. 2010. Network perspectives on the mechanisms of deep brain stimulation. Neurobiol Dis 38(3):329–337.Google Scholar
Merello, M, Balej, J, Delfino, M, Cammarota, A, Betti, O, Leiguarda, R. 1999. Apomorphine induces changes in GPi spontaneous outflow in patients with Parkinson’s disease. Mov Disord 14(1):45–49.Google Scholar
Merello, M, Cerquetti, D, Cammarota, A, Tenca, E, Artes, C, Antico, J, Leiguarda, R. 2004. Neuronal globus pallidus activity in patients with generalised dystonia. Mov Disord 19(5):548–554.Google Scholar
Milardi, D, Gaeta, M, Marino, S, Arrigo, A, Vaccarino, G, Mormina, E, Rizzo, G, Milazzo, C, Finocchio, G, Baglieri, A, Anastasi, G, Quartarone, A. 2015. Basal ganglia network by constrained spherical deconvolution: a possible cortico-pallidal pathway? Mov Disord 30(3):342–349.CrossRefGoogle ScholarPubMed
Nakashima, K, Rothwell, JC, Day, BL, Thompson, PD, Shannon, K, Marsden, CD. 1989. Reciprocal inhibition between forearm muscles in patients with writer’s cramp and other occupational cramps, symptomatic hemidystonia and hemiparesis due to stroke. Brain 112 (Pt 3):681–697.Google Scholar
Nakashima, K, Rothwell, JC, Thompson, PD, Day, BL, Berardelli, A, Agostino, R, Artieda, J, Papas, SM, Obeso, JA, Marsden, CD. 1990. The blink reflex in patients with idiopathic torsion dystonia. Arch Neurol 47(4):413–416.CrossRefGoogle ScholarPubMed
Napolitano, F, Pasqualetti, M, Usiello, A, Santini, E, Pacini, G, Sciamanna, G, Errico, F, Tassone, A, Di Dato, V, Martella, G, Cuomo, D, Fisone, G, Bernardi, G, Mandolesi, G, Mercuri, NB, Standaert, DG, Pisani, A. 2010. Dopamine D2 receptor dysfunction is rescued by adenosine A2A receptor antagonism in a model of DYT1 dystonia. Neurobiol Dis 38(3):434–445.Google Scholar
Neumann, WJ, Kuhn, AA. 2016. Reply: role of cortico-pallidal connectivity in the pathophysiology of dystonia. Brain 139(Pt 9):e49.CrossRefGoogle ScholarPubMed
Neumann, WJ, Huebl, J, Brucke, C, Ruiz, MH, Kupsch, A, Schneider, GH, Kuhn, AA. 2012. Enhanced low-frequency oscillatory activity of the subthalamic nucleus in a patient with dystonia. Mov Disord 27(8):1063–1066.CrossRefGoogle Scholar
Neumann, WJ, Jha, A, Bock, A, Huebl, J, Horn, A, Schneider, GH, Sander, TH, Litvak, V, Kuhn, AA. 2015. Cortico-pallidal oscillatory connectivity in patients with dystonia. Brain 138(Pt 7):1894–1906.Google Scholar
Neumann, WJ, Degen, K, Schneider, GH, Brucke, C, Huebl, J, Brown, P, Kuhn, AA. 2016. Subthalamic synchronized oscillatory activity correlates with motor impairment in patients with Parkinson’s disease. Mov Disord 31(11):1748–1751.Google Scholar
Panizza, ME, Hallett, M, Nilsson, J. 1989. Reciprocal inhibition in patients with hand cramps. Neurology 39(1):85–89.Google Scholar
Papa, SM, Desimone, R, Fiorani, M, Oldfield, EH. 1999. Internal globus pallidus discharge is nearly suppressed during levodopa-induced dyskinesias. Ann Neurol 46(5):732–738.Google Scholar
Peterson, DA, Sejnowski, TJ, Poizner, H. 2010. Convergent evidence for abnormal striatal synaptic plasticity in dystonia. Neurobiol Dis 37(3):558–573.Google Scholar
Priori, A, Foffani, G, Pesenti, A, Bianchi, A, Chiesa, V, Baselli, G, Caputo, E, Tamma, F, Rampini, P, Egidi, M, Locatelli, M, Barbieri, S, Scarlato, G. 2002. Movement-related modulation of neural activity in human basal ganglia and its L-DOPA dependency: recordings from deep brain stimulation electrodes in patients with Parkinson’s disease. Neurol Sci 23 (Suppl. 2):S101–S102.Google Scholar
Quartarone, A, Hallett, M. 2013. Emerging concepts in the physiological basis of dystonia. Mov Disord 28(7):958–967.Google Scholar
Quartarone, A, Bagnato, S, Rizzo, V, Siebner, HR, Dattola, V, Scalfari, A, Morgante, F, Battaglia, F, Romano, M, Girlanda, P. 2003. Abnormal associative plasticity of the human motor cortex in writer’s cramp. Brain 126(Pt 12):2586–2596.Google Scholar
Quartarone, A, Siebner, HR, Rothwell, JC. 2006. Task-specific hand dystonia: can too much plasticity be bad for you? Trends Neurosci 29(4):192–199.Google Scholar
Ridding, MC, Sheean, G, Rothwell, JC, Inzelberg, R, Kujirai, T. 1995. Changes in the balance between motor cortical excitation and inhibition in focal, task specific dystonia. J Neurol Neurosurg Psychiatry 59(5):493–498.Google Scholar
Ruge, D, Cif, L, Limousin, P, Gonzalez, V, Vasques, X, Hariz, MI, Coubes, P, Rothwell, JC. 2011. Shaping reversibility? Long-term deep brain stimulation in dystonia. The relationship between effects on electrophysiology and clinical symptoms. Brain 134(Pt 7):2106–2115.CrossRefGoogle ScholarPubMed
Silberstein, P, Kuhn, AA, Kupsch, A, Trottenberg, T, Krauss, JK, Wohrle, JC, Mazzone, P, Insola, A, Di Lazzaro, V, Oliviero, A, Aziz, T, Brown, P. 2003. Patterning of globus pallidus local field potentials differs between Parkinson’s disease and dystonia. Brain 126(Pt 12):2597–2608.Google Scholar
Starr, PA, Turner, RS, Rau, G, Lindsey, N, Heath, S, Volz, M, Ostrem, JL, Marks, WJ. 2006. Microelectrode-guided implantation of deep brain stimulators into the globus pallidus internus for dystonia: techniques, electrode locations, and outcomes. J Neurosurg 104(4):488–501.Google Scholar
Steigerwald, F, Hinz, L, Pinsker, MO, Herzog, J, Stiller, RU, Kopper, F, Mehdorn, HM, Deuschl, G, Volkmann, J. 2005. Effect of propofol anesthesia on pallidal neuronal discharges in generalized dystonia. Neurosci Lett 386(3):156–159.Google Scholar
Tang, JK, Moro, E, Mahant, N, Hutchison, WD, Lang, AE, Lozano, AM, Dostrovsky, JO. 2007. Neuronal firing rates and patterns in the globus pallidus internus of patients with cervical dystonia differ from those with Parkinson’s disease. J Neurophysiol 98(2):720–729.Google Scholar
Tisch, S, Limousin, P, Rothwell, JC, Asselman, P, Quinn, N, Jahanshahi, M, Bhatia, KP, Hariz, M. 2006a. Changes in blink reflex excitability after globus pallidus internus stimulation for dystonia. Mov Disord 21(10):1650–1655.Google Scholar
Tisch, S, Limousin, P, Rothwell, JC, Asselman, P, Zrinzo, L, Jahanshahi, M, Bhatia, KP, Hariz, MI. 2006b. Changes in forearm reciprocal inhibition following pallidal stimulation for dystonia. Neurology 66(7):1091–1093.Google Scholar
van Wijk, BC, Beudel, M, Jha, A, Oswal, A, Foltynie, T, Hariz, MI, Limousin, P, Zrinzo, L, Aziz, TZ, Green, AL, Brown, P, Litvak, V. 2016. Subthalamic nucleus phase-amplitude coupling correlates with motor impairment in Parkinson’s disease. Clin Neurophysiol 127(4):2010–2019.Google Scholar
Vidailhet, M, Vercueil, L, Houeto, JL, Krystkowiak, P, Benabid, AL, Cornu, P, Lagrange, C, Tezenas du Montcel, S, Dormont, D, Grand, S, Blond, S, Detante, O, Pillon, B, Ardouin, C, Agid, Y, Destee, A, Pollak, P, French Stimulation du Pallidum Interne dans la Dystonie (SPIDY) Study Group. 2005. Bilateral deep-brain stimulation of the globus pallidus in primary generalized dystonia. N Engl J Med 352(5):459–467.Google Scholar
Vidailhet, M, Yelnik, J, Lagrange, C, Fraix, V, Grabli, D, Thobois, S, Burbaud, P, Welter, ML, Xie-Brustolin, J, Braga, MC, Ardouin, C, Czernecki, V, Klinger, H, Chabardes, S, Seigneuret, E, Mertens, P, Cuny, E, Navarro, S, Cornu, P, Benabid, AL, Le Bas, JF, Dormont, D, Hermier, M, Dujardin, K, Blond, S, Krystkowiak, P, Destee, A, Bardinet, E, Agid, Y, Krack, P, Broussolle, E, Pollak, P, French SPIDY-2 Study Group. 2009. Bilateral pallidal deep brain stimulation for the treatment of patients with dystonia-choreoathetosis cerebral palsy: a prospective pilot study. Lancet Neurol 8(8):709–717.Google Scholar
Vidailhet, M, Jutras, MF, Grabli, D, Roze, E. 2013. Deep brain stimulation for dystonia. J Neurol Neurosurg Psychiatry 84(9):1029–1042.Google Scholar
Vitek, JL, Chockkan, V, Zhang, JY, Kaneoke, Y, Evatt, M, DeLong, MR, Triche, S, Mewes, K, Hashimoto, T, Bakay, RA. 1999. Neuronal activity in the basal ganglia in patients with generalized dystonia and hemiballismus. Ann Neurol 46(1):22–35.Google Scholar
Vitek, JL, Zhang, J, Hashimoto, T, Russo, GS, Baker, KB. 2012. External pallidal stimulation improves parkinsonian motor signs and modulates neuronal activity throughout the basal ganglia thalamic network. Exp Neurol 233(1):581–586.Google Scholar
Volkmann, J, Benecke, R. 2002. Deep brain stimulation for dystonia: patient selection and evaluation. Mov Disord 17 (Suppl. 3):S112–S115.Google Scholar
Volkmann, J, Wolters, A, Kupsch, A, Muller, J, Kuhn, AA, Schneider, GH, Poewe, W, Hering, S, Eisner, W, Muller, JU, Deuschl, G, Pinsker, MO, Skogseid, IM, Roeste, GK, Krause, M, Tronnier, V, Schnitzler, A, Voges, J, Nikkhah, G, Vesper, J, Classen, J, Naumann, M, Benecke, R, DBS Study Group for Dystonia. 2012. Pallidal deep brain stimulation in patients with primary generalised or segmental dystonia: 5-year follow-up of a randomised trial. Lancet Neurol 11(12):1029–1038.Google Scholar
Volkmann, J, Mueller, J, Deuschl, G, Kuhn, AA, Krauss, JK, Poewe, W, Timmermann, L, Falk, D, Kupsch, A, Kivi, A, Schneider, GH, Schnitzler, A, Sudmeyer, M, Voges, J, Wolters, A, Wittstock, M, Muller, JU, Hering, S, Eisner, W, Vesper, J, Prokop, T, Pinsker, M, Schrader, C, Kloss, M, Kiening, K, Boetzel, K, Mehrkens, J, Skogseid, IM, Ramm-Pettersen, J, Kemmler, G, Bhatia, KP, Vitek, JL, Benecke, R, DBS Study Group for Dystonia. 2014. Pallidal neurostimulation in patients with medication-refractory cervical dystonia: a randomised, sham-controlled trial. Lancet Neurol 13(9):875–884.Google Scholar
Wang, DD, de Hemptinne, C, Miocinovic, S, Qasim, SE, Miller, AM, Ostrem, JL, Galifianakis, NB, San Luciano, M, Starr, PA. 2016. Subthalamic local field potentials in Parkinson’s disease and isolated dystonia: an evaluation of potential biomarkers. Neurobiol Dis 89:213–222.CrossRefGoogle ScholarPubMed
Wang, S, Liu, X, Yianni, J, Green, AL, Joint, C, Stein, JF, Bain, PG, Gregory, R, Aziz, TZ. 2006. Use of surface electromyography to assess and select patients with idiopathic dystonia for bilateral pallidal stimulation. J Neurosurg 105(1):21–25.CrossRefGoogle ScholarPubMed
Weise, D, Schramm, A, Stefan, K, Wolters, A, Reiners, K, Naumann, M, Classen, J. 2006. The two sides of associative plasticity in writer’s cramp. Brain 129(Pt 10):2709–2721.Google Scholar
Welter, ML, Grabli, D, Vidailhet, M. 2010. Deep brain stimulation for hyperkinetics disorders: dystonia, tardive dyskinesia, and tics. Curr Opin Neurol 23(4):420–425.Google Scholar
Yianni, J, Wang, SY, Liu, X, Bain, PG, Nandi, D, Gregory, R, Joint, C, Stein, JF, Aziz, TZ. 2006. A dominant bursting electromyograph pattern in dystonic conditions predicts an early response to pallidal stimulation. J Clin Neurosci 13(7):738–746.Google Scholar
Yoshida, M, Nagatsuka, Y, Muramatsu, S, Niijima, K. 1991. Differential roles of the caudate nucleus and putamen in motor behavior of the cat as investigated by local injection of GABA antagonists. Neurosci Res 10(1):34–51.Google Scholar
- 1
- Cited by