. Rince-ou-le-ces-;-o'connell, mais elles n'ont fait l'objet que de très rares publications, 2018.

V. Références,

W. C. Abraham, Metaplasticity: tuning synapses and networks for plasticity, Nat. Rev. Neurosci, vol.9, pp.387-387, 2008.

V. Abreu, R. Vaz, V. Rebelo, M. J. Rosas, C. Chamadoira et al., Thalamic Deep Brain Stimulation for Neuropathic Pain: Efficacy at Three Years' Follow-Up: TREATMENT OF NEUROPATHIC PAIN AFTER TRAUMATIC LIMB INJURY, Neuromodulation Technol. Neural Interface, vol.20, pp.504-513, 2017.

R. Ahdab, S. S. Ayache, P. Brugières, C. Goujon, and J. Lefaucheur, Comparison of "standard" and "navigated" procedures of TMS coil positioning over motor, premotor and prefrontal targets in patients with chronic pain and depression, Neurophysiol. Clin. Neurophysiol, vol.40, pp.27-36, 2010.

E. A. Allen, B. N. Pasley, T. Duong, F. , and D. , Transcranial Magnetic Stimulation Elicits Coupled Neural and Hemodynamic Consequences, Science, vol.317, pp.1916-1918, 2007.

S. R. Alles and P. A. Smith, Etiology and Pharmacology of Neuropathic Pain, Pharmacol. Rev, vol.70, pp.315-347, 2018.

T. F. Almeida, S. Roizenblatt, and S. Tufik, Afferent pain pathways: a neuroanatomical review, Brain Res, vol.1000, pp.40-56, 2004.

M. Amanzio and F. Benedetti, Neuropharmacological dissection of placebo analgesia: expectation-activated opioid systems versus conditioning-activated specific subsystems, J. Neurosci, vol.19, pp.484-494, 1999.

E. Andersen, Periaqueductal gray and cerebral cortex modulate responses of medial thalamic neurons to noxious stimulation, Brain Res, vol.375, pp.30-36, 1986.

G. Andersen, K. Vestergaard, M. Ingeman-nielsen, and T. S. Jensen, Incidence of central post-stroke pain, Pain, vol.61, pp.187-193, 1995.

D. C. De-andrade, A. Mhalla, F. Adam, M. J. Texeira, and D. Bouhassira, Neuropharmacological basis of rTMS-induced analgesia: The role of endogenous opioids: Pain, vol.152, pp.320-326, 2011.

N. André-obadia, R. Peyron, P. Mertens, F. Mauguière, B. Laurent et al., Transcranial magnetic stimulation for pain control. Double-blind study of different frequencies against placebo, and correlation with motor cortex stimulation efficacy, Clin. Neurophysiol, vol.117, pp.1536-1544, 2006.

N. André-obadia, R. Peyron, P. Mertens, F. Mauguière, B. Laurent et al., Transcranial magnetic stimulation for pain control. Double-blind study of different frequencies against placebo, and correlation with motor cortex stimulation efficacy, Clin. Neurophysiol, vol.117, pp.1536-1544, 2006.

N. Andre-obadia, P. Mertens, A. Gueguen, R. Peyron, and L. Garcia-larrea, Pain relief by rTMS Differential effect of current flow but no specific action on pain subtypes, Neurology, vol.71, pp.833-840, 2008.

N. André-obadia, M. Magnin, and L. Garcia-larrea, On the importance of placebo timing in rTMS studies for pain relief, PAIN, vol.152, pp.1233-1237, 2011.

N. Andre-obadia, P. Mertens, T. Lelekov-boissard, A. Afif, M. Magnin et al., Is Life better after motor cortex stimulation for pain control? Results at long-term and their prediction by preoperative rTMS, Pain Physician, vol.17, pp.53-62, 2014.

N. Andre-obadia, M. Magnin, E. Simon, and L. Garcia-larrea, Somatotopic effects of rTMS in neuropathic pain? A comparison between stimulation over hand and face motor areas, Eur. J. Pain, vol.22, pp.707-715, 2018.

A. Antal and W. Paulus, Effects of transcranial theta-burst stimulation on acute pain perception, Restor. Neurol. Neurosci, vol.28, pp.477-484, 2010.

V. A. Apkarian, J. A. Hashmi, and M. N. Baliki, Pain and the brain: Specificity and plasticity of the brain in clinical chronic pain, Pain, vol.152, pp.49-64, 2011.

K. Ashkan, P. Rogers, H. Bergman, and I. Ughratdar, Insights into the mechanisms of deep brain stimulation, Nat. Rev. Neurol, vol.13, pp.548-554, 2017.

N. Attal, G. Cruccu, M. Haanpää, P. Hansson, T. S. Jensen et al., EFNS guidelines on pharmacological treatment of neuropathic pain, Eur. J. Neurol, vol.13, pp.1153-1169, 2006.

N. Attal, C. Fermanian, J. Fermanian, M. Lanteri-minet, H. Alchaar et al., Neuropathic pain: Are there distinct subtypes depending on the aetiology or anatomical lesion?, Pain, vol.138, pp.343-353, 2008.
URL : https://hal.archives-ouvertes.fr/inserm-00292335

N. Attal, M. Lanteri-minet, B. Laurent, J. Fermanian, and D. Bouhassira, The specific disease burden of neuropathic pain: Results of a French nationwide survey, Pain, vol.152, pp.2836-2843, 2011.

N. Attal, S. S. Ayache, D. Ciampi-de-andrade, A. Mhalla, S. Baudic et al., Repetitive transcranial magnetic stimulation and transcranial direct-current stimulation in neuropathic pain due to radiculopathy: a randomized sham-controlled comparative study, PAIN, vol.157, pp.1224-1231, 2016.

S. S. Ayache, R. Ahdab, M. A. Chalah, W. H. Farhat, V. Mylius et al., Analgesic effects of navigated motor cortex rTMS in patients with chronic neuropathic pain, Eur. J. Pain, 2016.

S. Aydin-abidin, J. Trippe, K. Funke, U. T. Eysel, and A. Benali, High-and lowfrequency repetitive transcranial magnetic stimulation differentially activates c-Fos and zif268 protein expression in the rat brain, Exp. Brain Res, vol.188, pp.249-261, 2008.

J. Banerjee, M. E. Sorrell, P. A. Celnik, and G. Pelled, Immediate effects of repetitive magnetic stimulation on single cortical pyramidal neurons, PloS One, vol.12, 2017.

A. I. Basbaum, D. M. Bautista, G. Scherrer, J. , and D. , Cellular and Molecular Mechanisms of Pain, Cell, vol.139, pp.267-284, 2009.

P. J. Basser and B. J. Roth, Stimulation of a myelinated nerve axon by electromagnetic induction, Med. Biol. Eng. Comput, vol.29, pp.261-268, 1991.

H. Bastuji, M. Frot, S. Mazza, C. Perchet, M. Magnin et al., , 2016.

, Thalamic Responses to Nociceptive-Specific Input in Humans: Functional Dichotomies and Thalamo-Cortical Connectivity, vol.26, pp.2663-2676

H. Bastuji, M. Frot, C. Perchet, M. Magnin, and L. Garcia-larrea, Pain networks from the inside: Spatiotemporal analysis of brain responses leading from nociception to conscious perception: Pain Networks From the Inside, Hum. Brain Mapp, vol.37, pp.4301-4315, 2016.

F. Benedetti, Placebo Effects: From the Neurobiological Paradigm to Translational Implications, Neuron, vol.84, pp.623-637, 2014.

F. Benedetti and M. , Potentiation of placebo analgesia by proglumide, The Lancet, vol.8984, 1995.

F. Benedetti, A. Pollo, L. Lopiano, M. Lanotte, S. Vighetti et al., Conscious expectation and unconscious conditioning in analgesic, motor, and hormonal placebo/nocebo responses, J. Neurosci, vol.23, pp.4315-4323, 2003.

T. V. Bliss and A. R. Gardner-medwin, Long-lasting potentiation of synaptic transmission in the dentate area of the unanaesthetized rabbit following stimulation of the perforant path, J. Physiol, vol.232, pp.357-374, 1973.

D. Bouhassira, N. Attal, J. Fermanian, H. Alchaar, M. Gautron et al., Development and validation of the Neuropathic Pain Symptom Inventory: Pain, vol.108, pp.248-257, 2004.

D. Bowsher, J. Brooks, and P. Enevoldson, Central Representation of Somatic Sensations in the Parietal Operculum (SII) and Insula, Eur. Neurol, vol.52, pp.211-225, 2004.

C. Bradley, C. Perchet, T. Lelekov-boissard, M. Magnin, and L. Garcia-larrea, Not an Aspirin: No Evidence for Acute Anti-Nociception to Laser-Evoked Pain After Motor Cortex rTMS in Healthy Humans, Brain Stimulat, vol.9, pp.48-57, 2016.

J. A. Brown and N. M. Barbaro, Motor cortex stimulation for central and neuropathic pain: current status, Pain, vol.104, pp.431-435, 2003.

A. Buchmuller, M. Navez, M. Milletre-bernardin, S. Pouplin, E. Presles et al., Value of TENS for relief of chronic low back pain with or without radicular pain: Value of TENS for relief of chronic low back pain, Eur. J. Pain, vol.16, pp.656-665, 2012.

A. M. Carlsson, Assessment of chronic pain. I. Aspects of the reliability and validity of the visual analogue scale, Pain, vol.16, pp.87-101, 1983.

D. Carroll, C. Joint, N. Maartens, D. Shlugman, J. Stein et al., Motor cortex stimulation for chronic neuropathic pain: a preliminary study of 10 cases, Pain, vol.84, pp.431-437, 2000.

L. K. Case, C. M. Laubacher, E. A. Richards, P. A. Spagnolo, H. Olausson et al., Inhibitory rTMS of secondary somatosensory cortex reduces intensity but not pleasantness of gentle touch, Neurosci. Lett, vol.653, pp.84-91, 2017.

K. L. Casey, M. Geisser, J. Lorenz, T. J. Morrow, P. Paulson et al., , 2012.

, Psychophysical and cerebral responses to heat stimulation in patients with central pain, painless central sensory loss, and in healthy persons, Pain, vol.153, pp.331-341

A. Chitsaz, M. Janghorbani, V. Shaygannejad, F. Ashtari, M. Heshmatipour et al., Sensory complaints of the upper extremities in multiple sclerosis: relative efficacy of nortriptyline and transcutaneous electrical nerve stimulation, Clin. J. Pain, vol.25, pp.281-285, 2009.

D. Ciampi-de-andrade, R. Galhardoni, L. F. Pinto, R. Lancelotti, J. Rosi et al., Into the Island: A new technique of non-invasive cortical stimulation of the insula, Neurophysiol. Clin. Neurophysiol, vol.42, pp.363-368, 2012.

L. Colloca and F. Benedetti, Placebos and painkillers: is mind as real as matter?, Nat. Rev. Neurosci, vol.6, p.545, 2005.

L. Colloca and C. Grillon, Understanding Placebo and Nocebo Responses for Pain Management. Curr. Pain Headache Rep, vol.18, 2014.

S. Coretti, M. Ruggeri, and P. Mcnamee, The minimum clinically important difference for EQ-5D index: a critical review, Expert Rev. Pharmacoecon. Outcomes Res, vol.14, pp.221-233, 2014.

J. D. Coulter, R. A. Maunz, and W. D. Willis, Effects of stimulation of sensorimotor cortex on primate spinothalamic neurons, Brain Res, vol.65, pp.351-356, 1974.

J. L. Couturier, Efficacy of rapid-rate repetitive transcranial magnetic stimulation in the treatment of depression: a systematic review and meta-analysis, J. Psychiatry Neurosci. JPN, vol.30, pp.83-90, 2005.

S. W. Davis, B. Luber, D. L. Murphy, S. H. Lisanby, and R. Cabeza, Frequencyspecific neuromodulation of local and distant connectivity in aging and episodic memory function: Frequency-Specific Neuromodulation, Hum. Brain Mapp, vol.38, pp.5987-6004, 2017.

J. De-andres, V. Monsalve-dolz, G. Fabregat-cid, V. Villanueva-perez, A. Harutyunyan et al., Prospective, Randomized Blind Effecton-Outcome Study of Conventional vs High-Frequency Spinal Cord Stimulation in Patients with Pain and Disability Due to Failed Back Surgery Syndrome, Pain Med, vol.18, pp.2401-2421, 2017.

S. Demasles, R. Peyron, L. Garcia-larrea, L. , and B. , Les douleurs centrales post-AVC, Rev. Neurol, vol.164, pp.825-831, 2008.

Z. Deng, S. H. Lisanby, and A. V. Peterchev, Electric field depth-focality tradeoff in transcranial magnetic stimulation: Simulation comparison of 50 coil designs, Brain Stimulat, vol.6, pp.1-13, 2013.

D. J. Denis, R. Marouf, P. Rainville, A. Bouthillier, and D. K. Nguyen, Effects of insular stimulation on thermal nociception, Eur. J. Pain, vol.20, pp.800-810, 2016.

F. Denk, S. B. Mcmahon, T. , and I. , Pain vulnerability: a neurobiological perspective, Nat. Neurosci, vol.17, pp.192-200, 2014.

J. M. Desantana, L. F. Da-silva, M. A. De-resende, and K. A. Sluka, , 2009.

, Transcutaneous electrical nerve stimulation at both high and low frequencies activates ventrolateral periaqueductal grey to decrease mechanical hyperalgesia in arthritic rats, Neuroscience, vol.163, pp.1233-1241

J. J. De-waele, M. L. Cheatham, M. Malbrain, A. W. Kirkpatrick, M. Sugrue et al., Recommendations for research from the international conference of experts on intra-abdominal hypertension and abdominal compartment syndrome, Acta Clin. Belg, vol.64, pp.203-209, 2009.

D. Blazi, Z. Harkness, E. Ernst, E. Georgiou, A. Kleijnen et al., Influence of context effects on health outcomes-a systematic review, The Lancet, vol.357, 2001.

V. Di-lazzaro, M. Dileone, F. Pilato, P. Profice, A. Oliviero et al., Associative Motor Cortex Plasticity: Direct Evidence in Humans, Cereb. Cortex, vol.19, pp.2326-2330, 2009.

J. Du, L. Tian, W. Liu, J. Hu, G. Xu et al., Effects of repetitive transcranial magnetic stimulation on motor recovery and motor cortex excitability in patients with stroke: a randomized controlled trial, Eur. J. Neurol, vol.23, pp.1666-1672, 2016.

D. Ducreux, N. Attal, F. Parker, and D. Bouhassira, Mechanisms of central neuropathic pain: a combined psychophysical and fMRI study in syringomyelia, Brain, vol.129, pp.963-976, 2006.

G. H. Duncan, R. C. Kupers, S. Marchand, J. Villemure, J. M. Gybels et al., Stimulation of human thalamus for pain relief: possible modulatory circuits revealed by positron emission tomography, J. Neurophysiol, vol.80, pp.3326-3330, 1998.

F. Eippert, U. Bingel, E. D. Schoell, J. Yacubian, R. Klinger et al., Activation of the Opioidergic Descending Pain Control System Underlies Placebo Analgesia, Neuron, vol.63, pp.533-543, 2009.

G. J. Elias, A. A. Namasivayam, and A. M. Lozano, Deep brain stimulation for stroke: Current uses and future directions, Brain Stimulat, vol.11, pp.3-28, 2018.

S. K. Esser, S. L. Hill, and G. Tononi, Modeling the Effects of Transcranial Magnetic Stimulation on Cortical Circuits, J. Neurophysiol, vol.94, pp.622-639, 2005.

J. T. Farrar, R. C. Polomano, J. A. Berlin, and B. L. Strom, A Comparison of Change in the 0-10 Numeric Rating Scale to a Pain Relief Scale and Global Medication Performance Scale in a Short-term, Clinical Trial of Breakthrough Pain Intensity, 2010.

S. C. Ficarella and L. Battelli, The critical role of the dorsal fronto-median cortex in voluntary action inhibition: A TMS study, Brain Stimulat, 2016.

N. B. Finnerup, S. H. Sindrup, and T. S. Jensen, Recent advances in pharmacological treatment of neuropathic pain, F1000 Med. Rep, vol.2, 2010.

R. J. Fisher, Y. Nakamura, S. Bestmann, J. C. Rothwell, and H. Bostock, Two phases of intracortical inhibition revealed by transcranial magnetic threshold tracking, Exp. Brain Res, vol.143, pp.240-248, 2002.

P. B. Fitzgerald, K. Hoy, S. Mcqueen, J. J. Maller, S. Herring et al., A randomized trial of rTMS targeted with MRI based neuro-navigation in treatment-resistant depression, Neuropsychopharmacology, vol.34, pp.1255-1262, 2009.

E. T. Fonoff, C. S. Dale, R. L. Pagano, C. C. Paccola, G. Ballester et al., Antinociception induced by epidural motor cortex stimulation in naive conscious rats is mediated by the opioid system, Behav. Brain Res, vol.196, pp.63-70, 2009.

P. T. Fox, S. Narayana, N. Tandon, H. Sandoval, S. P. Fox et al., Column-based model of electric field excitation of cerebral cortex, Hum. Brain Mapp, vol.22, pp.1-14, 2004.

F. Fregni, K. Potvin, D. Silva, X. Wang, R. E. Lenkinski et al., Clinical effects and brain metabolic correlates in non-invasive cortical neuromodulation for visceral pain, Eur. J. Pain, vol.15, pp.53-60, 2011.

M. Frot, M. Magnin, F. Mauguiere, and L. Garcia-larrea, Human SII and Posterior Insula Differently Encode Thermal Laser Stimuli, Cereb. Cortex, vol.17, pp.610-620, 2006.

M. Frot, I. Faillenot, and F. Mauguière, Processing of nociceptive input from posterior to anterior insula in humans: Nociceptive Input Processing in the Insula, Hum. Brain Mapp, vol.35, pp.5486-5499, 2014.

T. Furmark, L. Appel, S. Henningsson, F. Ahs, V. Faria et al., A Link between Serotonin-Related Gene Polymorphisms, Amygdala Activity, and Placebo-Induced Relief from Social Anxiety, J. Neurosci, vol.28, pp.13066-13074, 2008.

R. Galhardoni, V. Silva, S. Siqueira, D. Fernandes, J. Rossi et al., Dissociation between Pain relief and Anti-nociceptive effects of deep rTMS for central neuropathic pain, 2018.

L. Garcia-larrea and R. Peyron, Motor cortex stimulation for neuropathic pain: From phenomenology to mechanisms, NeuroImage, vol.37, pp.71-79, 2007.

L. Garcia-larrea and R. Peyron, Pain matrices and neuropathic pain matrices: A review, Pain, vol.154, pp.29-43, 2013.
URL : https://hal.archives-ouvertes.fr/inserm-00877368

L. Garcia-larrea, J. Maarrawi, R. Peyron, N. Costes, P. Mertens et al., On the relation between sensory deafferentation, pain and thalamic activity in Wallenberg's syndrome: A PET-scan study before and after motor cortex stimulation, Eur. J. Pain, vol.10, pp.677-677, 2006.

L. Garcia-larrea, C. Perchet, C. Creac'h, P. Convers, R. Peyron et al., Operculo-insular pain (parasylvian pain): a distinct central pain syndrome, Brain, vol.133, pp.2528-2539, 2010.

C. Gauriau and J. Bernard, Pain pathways and parabrachial circuits in the rat, Exp. Physiol, vol.87, pp.251-258, 2002.

L. E. Gee, I. Walling, A. Ramirez-zamora, D. S. Shin, and J. G. Pilitsis, Subthalamic deep brain stimulation alters neuronal firing in canonical pain nuclei in a 6-hydroxydopamine lesioned rat model of Parkinson's disease, Exp. Neurol, vol.283, pp.298-307, 2016.

A. George, D. Fitzpatrick, W. Hall, A. Lamantia, D. Purves et al., Neurosciences (Deboeck), 2018.

R. Gersner, E. Kravetz, J. Feil, G. Pell, and A. Zangen, Long-Term Effects of Repetitive Transcranial Magnetic Stimulation on Markers for Neuroplasticity: Differential Outcomes in Anesthetized and Awake Animals, J. Neurosci, vol.31, pp.7521-7526, 2011.

W. Gibson, B. M. Wand, N. E. Connell, S. Van-gorp, A. G. Kessels et al., Pain prevalence and its determinants after spinal cord injury: A systematic review: Spinal cord injury pain determinants, Cochrane Database Syst. Rev, vol.19, pp.5-14, 2015.

Y. Guan, Spinal Cord Stimulation: Neurophysiological and Neurochemical Mechanisms of Action, Curr. Pain Headache Rep, vol.16, pp.217-225, 2012.

M. Haanpää, N. Attal, M. Backonja, R. Baron, M. Bennett et al., , vol.152, pp.14-27, 2011.

T. Hagenacker, V. Bude, S. Naegel, D. Holle, Z. Katsarava et al., Patient-conducted anodal transcranial direct current stimulation of the motor cortex alleviates pain in trigeminal neuralgia, J. Headache Pain, vol.15, p.78, 2014.

R. Hanajima, Y. Ugawa, Y. Terao, K. Sakai, T. Furubayashi et al.,

, Paired-pulse magnetic stimulation of the human motor cortex: differences among I waves, J. Physiol, vol.509, pp.607-618

Y. Hattori, A. Moriwaki, and Y. Hori, Biphasic effects of polarizing current on adenosine-sensitive generation of cyclic AMP in rat cerebral cortex, Neurosci. Lett, vol.116, pp.320-324, 1990.

W. He, P. Zhou, D. Lin, X. Zhao, W. et al., Study of the Electromagnetic Field of Transcranial Magnetic Stimulation Based on the Real Head Model, Biomedical Engineering and Informatics, 2009. BMEI'09. 2nd International Conference on, pp.1-5, 2009.

A. Hirayama, Y. Saitoh, H. Kishima, T. Shimokawa, S. Oshino et al., Reduction of intractable deafferentation pain by navigation-guided repetitive transcranial magnetic stimulation of the primary motor cortex, PAIN, vol.122, pp.22-27, 2006.

H. Hodaj, J. Alibeu, J. Payen, and J. Lefaucheur, Treatment of Chronic Facial Pain Including Cluster Headache by Repetitive Transcranial Magnetic Stimulation of the Motor Cortex With Maintenance Sessions: A Naturalistic Study, Brain Stimulat, vol.8, pp.801-807, 2015.

J. M. Hoogendam, G. M. Ramakers, D. Lazzaro, and V. , Physiology of repetitive transcranial magnetic stimulation of the human brain, Brain Stimulat, vol.3, pp.95-118, 2010.

A. Horn, A. A. Kühn, A. Merkl, L. Shih, R. Alterman et al., Probabilistic conversion of neurosurgical DBS electrode coordinates into MNI space, NeuroImage, vol.150, pp.395-404, 2017.

K. Hosomi, Y. Saitoh, H. Kishima, S. Oshino, M. Hirata et al., Electrical stimulation of primary motor cortex within the central sulcus for intractable neuropathic pain, Clin. Neurophysiol, vol.119, pp.993-1001, 2008.

K. Hosomi, T. Shimokawa, K. Ikoma, Y. Nakamura, K. Sugiyama et al., Daily repetitive transcranial magnetic stimulation of primary motor cortex for neuropathic pain: A randomized, multicenter, double-blind, crossover, sham-controlled trial, PAIN®, vol.154, pp.1065-1072, 2013.

K. Hosomi, B. Seymour, and Y. Saitoh, Modulating the pain networkneurostimulation for central poststroke pain, Nat. Rev. Neurol, vol.11, pp.290-299, 2015.

B. Houze, C. Bradley, M. Magnin, and L. Garcia-larrea, Changes in Sensory Hand Representation and Pain Thresholds Induced by Motor Cortex Stimulation in Humans, Cereb. Cortex, vol.23, pp.2667-2676, 2013.

K. Irlbacher, J. Kuhnert, S. Röricht, B. U. Meyer, and S. A. Brandt, Zentrale und periphere Deafferenzierungsschmerzen: Therapie mit der repetitiven transkraniellen Magnetstimulation?, Nervenarzt, vol.77, pp.1196-1203, 2006.

N. Islam, M. Aftabuddin, A. Moriwaki, Y. Hattori, and Y. Hori, Increase in the calcium level following anodal polarization in the rat brain, Brain Res, vol.684, pp.206-208, 1995.

M. Ito, S. Kuroda, T. Shiga, N. Tamaki, and Y. Iwasaki, Motor Cortex Stimulation Improves Local Cerebral Glucose Metabolism in the Ipsilateral Thalamus in Patients With Poststroke Pain: Case Report, Neurosurgery, vol.69, pp.462-469, 2011.

M. B. Iyer, N. Schleper, and E. M. Wassermann, Priming stimulation enhances the depressant effect of low-frequency repetitive transcranial magnetic stimulation, J. Neurosci, vol.23, pp.10867-10872, 2003.

M. A. Jacobs, Z. G. Zhang, R. A. Knight, H. Soltanian-zadeh, A. V. Goussev et al., A model for multiparametric MRI tissue characterization in experimental cerebral ischemia with histological validation in rat, Stroke, vol.32, issue.1, pp.943-949, 2001.

J. J. Lee, M. K. Lee, J. E. Kim, H. Z. Kim, S. H. Park et al., Pain Relief Scale Is More Highly Correlated with Numerical Rating Scale than with Visual Analogue Scale in Chronic Pain Patients, Pain Physician, vol.18, pp.195-200, 2015.

N. D. James, S. B. Mcmahon, and E. Field-fote, Neuromodulation in the restoration of function after spinal cord injury, Lancet Neurol, 2018.

F. Jetté, I. Côté, H. B. Meziane, and C. Mercier, Effect of single-session repetitive transcranial magnetic stimulation applied over the hand versus leg motor area on pain after spinal cord injury, Neurorehabil. Neural Repair, vol.27, pp.636-643, 2013.

S. Johnson, J. Summers, and S. Pridmore, Changes to somatosensory detection and pain thresholds following high frequency repetitive TMS of the motor cortex in individuals suffering from chronic pain, Pain, vol.123, pp.187-192, 2006.

A. Jonsson, Prevalence and intensity of pain after stroke: a population based study focusing on patients' perspectives, J. Neurol. Neurosurg. Psychiatry, vol.77, pp.590-595, 2006.

E. Kallioniemi, P. Savolainen, G. Järnefelt, P. Koskenkorva, J. Karhu et al., Transcranial magnetic stimulation modulation of corticospinal excitability by targeting cortical I-waves with biphasic paired-pulses, Brain Stimulat, vol.11, pp.322-326, 2018.

B. S. Kang, H. I. Shin, and M. S. Bang, Effect of Repetitive Transcranial Magnetic Stimulation Over the Hand Motor Cortical Area on Central Pain After Spinal Cord Injury, Arch. Phys. Med. Rehabil, vol.90, pp.1766-1771, 2009.

D. Kernell and W. U. Chien-ping, Responses of the pyramidal tract to stimulation of the baboon's motor cortex, J. Physiol, vol.191, pp.653-672, 1967.

A. Khadilkar, D. O. Odebiyi, L. Brosseau, and G. A. Wells, Transcutaneous electrical nerve stimulation (TENS) versus placebo for chronic low-back pain, Cochrane Database Syst. Rev, 2008.

E. M. Khedr, Longlasting antalgic effects of daily sessions of repetitive transcranial magnetic stimulation in central and peripheral neuropathic pain, J. Neurol. Neurosurg. Psychiatry, vol.76, pp.833-838, 2005.

D. Kim, C. Won, and G. E. Georghiou, Improved Prediction of the Fields Induced in the Brain During Transcranial Magnetic Stimulation by the Incorporation of more Realistic Head Models, Computational Electromagnetics (CEM), pp.1-2, 2006.

J. V. Kim, S. Megat, J. K. Moy, M. N. Asiedu, G. L. Mejia et al., Neuroligin 2 regulates spinal GABAergic plasticity in hyperalgesic priming, vol.157, pp.1314-1324, 2016.

M. M. Klein, R. Treister, T. Raij, A. Pascual-leone, L. Park et al., Transcranial magnetic stimulation of the brain: guidelines for pain treatment research, PAIN, vol.156, pp.1601-1614, 2015.

H. Klit, N. B. Finnerup, and T. S. Jensen, Central post-stroke pain: clinical characteristics, pathophysiology, and management, Lancet Neurol, vol.8, pp.857-868, 2009.

H. Klit, N. B. Finnerup, G. Andersen, and T. S. Jensen, Central poststroke pain: A population-based study, Pain, vol.152, pp.818-824, 2011.

W. Klomjai, R. Katz, and A. Lackmy-vallée, Basic principles of transcranial magnetic stimulation (TMS) and repetitive TMS (rTMS), Ann. Phys. Rehabil. Med, vol.58, pp.208-213, 2015.
URL : https://hal.archives-ouvertes.fr/hal-01202513

M. Kobayashi, T. Fujimaki, B. Mihara, and T. Ohira, Repetitive Transcranial Magnetic Stimulation Once a Week Induces Sustainable Long-Term Relief of Central Poststroke Pain: Relief of poststroke Pain by Weekly rTMS, Neuromodulation Technol. Neural Interface, vol.18, pp.249-254, 2015.

T. Krause, S. Asseyer, B. Taskin, A. Flöel, A. V. Witte et al., The Cortical Signature of Central Poststroke Pain: Gray Matter Decreases in Somatosensory, Insular, and Prefrontal Cortices, Cereb. Cortex, vol.26, pp.80-88, 2016.

S. Kunnumpurath, R. Srinivasagopalan, and N. Vadivelu, Spinal cord stimulation: principles of past, present and future practice: a review, J. Clin. Monit. Comput, vol.23, pp.333-339, 2009.

C. Lampl, K. Yazdi, and C. Roper, Amitriptyline in the Prophylaxis of Central Poststroke Pain: Preliminary Results of 39 Patients in a Placebo-Controlled, Long-Term Study, Stroke, vol.33, pp.3030-3032, 2002.

V. D. Lazzaro, A. Oliviero, E. Saturno, F. Pilato, A. Insola et al., The effect on corticospinal volleys of reversing the direction of current induced in the motor cortex by transcranial magnetic stimulation, Exp. Brain Res, vol.138, pp.268-273, 2001.

J. Lefaucheur, Motor cortex rTMS restores defective intracortical inhibition in chronic neuropathic pain, Neurol, vol.67, pp.1568-1574, 2006.

J. Lefaucheur, Neurogenic pain relief by repetitive transcranial magnetic cortical stimulation depends on the origin and the site of pain, J. Neurol. Neurosurg. Psychiatry, vol.75, pp.612-616, 2004.

J. P. Lefaucheur, The use of repetitive transcranial magnetic stimulation (rTMS) in chronic neuropathic pain, Neurophysiol. Clin. Neurophysiol, vol.36, pp.117-124, 2006.

J. Lefaucheur and D. C. De-andrade, Intraoperative neurophysiologic mapping of the central cortical region for epidural electrode placement in the treatment of neuropathic pain by motor cortex stimulation, Brain Stimulat, vol.2, pp.138-148, 2009.

J. P. Lefaucheur, X. Drouot, and J. P. Nguyen, Interventional neurophysiology for pain control: duration of pain relief following repetitive transcranial magnetic stimulation of the motor cortex, Neurophysiol. Clin. Neurophysiol, vol.31, pp.247-252, 2001.

J. Lefaucheur, X. Drouot, Y. Keravel, and J. Nguyen, Pain relief induced by repetitive transcranial magnetic stimulation of precentral cortex, Neuroreport, vol.12, pp.2963-2965, 2001.

J. Lefaucheur, X. Drouot, I. Ménard-lefaucheur, and J. Nguyen, , 2004.

J. Lefaucheur, X. Drouot, I. Ménard-lefaucheur, and J. Nguyen, Neuropathic pain controlled for more than a year by monthly sessions of repetitive transcranial magnetic stimulation of the motor cortex, Neurophysiol. Clin. Neurophysiol, vol.34, pp.91-95, 2004.

J. Lefaucheur, N. André-obadia, E. Poulet, H. Devanne, and L. Garcia-larrea, , 2011.

, Règles de sécurité concernant la pratique de la stimulation magnétique transcrânienne en clinique et en recherche. Texte de consensus, Neurophysiol. Clin. Neurophysiol

J. Lefaucheur, N. André-obadia, E. Poulet, H. Devanne, E. Haffen et al., Recommandations françaises sur l'utilisation de la stimulation magnétique transcrânienne répétitive (rTMS) : règles de sécurité et indications thérapeutiques, Neurophysiol. Clin. Neurophysiol, vol.41, pp.221-295, 2011.

J. Lefaucheur, N. André-obadia, A. Antal, S. S. Ayache, C. Baeken et al., Evidence-based guidelines on the therapeutic use of repetitive transcranial magnetic stimulation (rTMS), Clin. Neurophysiol, vol.125, pp.2150-2206, 2014.

C. Lenoir, M. Algoet, and A. Mouraux, Deep continuous theta burst stimulation of the operculo-insular cortex selectively affects A?-fibre heat pain: Deep continuous theta burst stimulation of the insula affects heat pain perception, J. Physiol, 2018.

C. Lenoir, M. Algoet, C. Vanderclausen, A. Peeters, S. F. Santos et al., Report of one confirmed generalized seizure and one suspected partial seizure induced by deep continuous theta burst stimulation of the right operculo-insular cortex, Brain Stimulat, vol.11, pp.1187-1188, 2018.

H. Lin, W. Li, J. Ni, W. , and Y. , Clinical study of repetitive transcranial magnetic stimulation of the motor cortex for thalamic pain: Medicine (Baltimore) 97, p.11235, 2018.

P. Lindholm, S. Lamusuo, T. Taiminen, U. Pesonen, A. Lahti et al., Right secondary somatosensory cortex -a promising novel target for the treatment of drug-resistant neuropathic orofacial pain with repetitive transcranial magnetic stimulation, 2015.

J. Maarrawi, R. Peyron, P. Mertens, N. Costes, M. Magnin et al., Motor cortex stimulation for pain control induces changes in the endogenous opioid system, pp.827-834, 2007.

J. Maarrawi, R. Peyron, P. Mertens, N. Costes, M. Magnin et al., Brain opioid receptor density predicts motor cortex stimulation efficacy for chronic pain, Pain, vol.154, pp.2563-2568, 2013.

F. Maeda, J. P. Keenan, J. M. Tormos, H. Topka, and A. Leone, , 2000.

, Interindividual variability of the modulatory effects of repetitive transcranial magnetic stimulation on cortical excitability, Exp. Brain Res, vol.133, pp.425-430

A. Malavera, F. A. Silva, F. Fregni, S. Carrillo, and R. G. García, Repetitive Transcranial Magnetic Stimulation for phantom limb pain in landmine victims: A doubleblinded, randomized, sham-controlled trial, J. Pain, 2016.

J. S. Maritz, A permutation paired test allowing for missing values, Aust. J. Stat, vol.37, pp.153-159, 1995.

D. J. Mayer, D. D. Price, D. P. Becker, Y. , and H. F. , Neurosurgery Threshold for pain from anterolateral quadrant stimulation as a predictor of success of percutaneous cordotomy for relief of pain, J. Neurosurg, vol.43, pp.89-90, 1975.

L. Mazzola, Somatosensory and Pain Responses to Stimulation of the Second Somatosensory Area (SII) in Humans. A Comparison with SI and Insular Responses, Cereb. Cortex, vol.16, pp.960-968, 2005.

L. Mazzola, J. Isnard, R. Peyron, M. Guénot, and F. Mauguière, Somatotopic organization of pain responses to direct electrical stimulation of the human insular cortex, Pain, vol.146, pp.99-104, 2009.

L. Mazzola, I. Faillenot, F. Barral, F. Mauguière, and R. Peyron, Spatial segregation of somato-sensory and pain activations in the human operculo-insular cortex, NeuroImage, vol.60, pp.409-418, 2012.
URL : https://hal.archives-ouvertes.fr/hal-00793572

L. Mazzola, J. Isnard, R. Peyron, and F. Mauguière, Stimulation of the human cortex and the experience of pain: Wilder Penfield's observations revisited, Brain, vol.135, pp.631-640, 2012.

L. F. Medeiros, W. Caumo, J. Dussán-sarria, A. Deitos, A. Brietzke et al., Effect of Deep Intramuscular Stimulation and Transcranial Magnetic Stimulation on Neurophysiological Biomarkers in Chronic Myofascial Pain Syndrome, Pain Med, 2015.

R. Melzack and P. D. Wall, Pain mechanisms: a new theory, Science, vol.150, pp.971-979, 1965.

A. Mhalla, S. Baudic, D. C. De-andrade, M. Gautron, S. Perrot et al., Long-term maintenance of the analgesic effects of transcranial magnetic stimulation in fibromyalgia, PAIN, vol.152, pp.1478-1485, 2011.

J. Micoulaud-franchi, C. Quiles, and J. Vion-dury, Éléments pour une histoire de l'électricité et du cerveau en psychiatrie. Naissance et développement de la stimulation et de l'enregistrement électrique en neurophysiologie (Partie I), Ann. Méd.-Psychol. Rev. Psychiatr, vol.171, pp.318-322, 2013.

Y. Min, J. W. Park, S. U. Jin, K. E. Jang, B. Lee et al., Neuromodulatory effects of offline low-frequency repetitive transcranial magnetic stimulation of the motor cortex: A functional magnetic resonance imaging study, Sci. Rep, vol.6, p.36058, 2016.

B. Mockett, C. Coussens, A. , and W. C. , NMDA receptor-mediated metaplasticity during the induction of long-term depression by low-frequency stimulation, Eur. J. Neurosci, vol.15, pp.1819-1826, 2002.

N. Modugno, Y. Nakamura, C. Mackinnon, S. Filipovic, S. Bestmann et al., Motor cortex excitability following short trains of repetitive magnetic stimuli, Exp. Brain Res, vol.140, pp.453-459, 2001.

X. Moisset, D. C. De-andrade, and D. Bouhassira, From pulses to pain relief: an update on the mechanisms of rTMS-induced analgesic effects, Eur. J. Pain, 2015.

X. Moisset, S. Goudeau, F. Poindessous-jazat, S. Baudic, P. Clavelou et al., Prolonged Continuous Theta-burst Stimulation is More Analgesic Than "Classical" High Frequency Repetitive Transcranial Magnetic Stimulation, Brain Stimulat, vol.8, pp.135-141, 2015.

T. M. Moloney and A. G. Witney, Transcranial direct current stimulation (tDCS) priming of 1Hz repetitive transcranial magnetic stimulation (rTMS) modulates experimental pain thresholds, Neurosci. Lett, vol.534, pp.289-294, 2013.

R. A. Moore, P. J. Wiffen, S. Derry, and A. S. Rice, Gabapentin for chronic neuropathic pain and fibromyalgia in adults, Cochrane Database of Systematic Reviews, 2014.

F. Moran, T. Leonard, S. Hawthorne, C. M. Hughes, E. Mccrum-gardner et al., Hypoalgesia in Response to Transcutaneous Electrical Nerve Stimulation (TENS) Depends on Stimulation Intensity, J. Pain, vol.12, pp.929-935, 2011.

J. K. Mueller, E. M. Grigsby, V. Prevosto, F. W. Petraglia, H. Rao et al., Simultaneous transcranial magnetic stimulation and single-neuron recording in alert non-human primates, Nat. Neurosci, vol.17, pp.1130-1136, 2014.

R. Mundry, Testing related samples with missing values-a permutation approach, pdf. Assoc. Study Anial Behav, vol.58, p.5, 1999.

S. C. Murphy, L. M. Palmer, T. Nyffeler, R. M. Müri, and M. E. Larkum, , 2016.

, Transcranial magnetic stimulation (TMS) inhibits cortical dendrites

A. Waszkielewicz, A. Gunia, K. Sloczynska, and H. Marona, Evaluation of anticonvulsants for possible use in neuropathic pain, Curr. Med. Chem, vol.18, pp.4344-4358, 2011.

S. S. Nagarajan, D. M. Durand, and E. N. Warman, Effects of induced electric fields on finite neuronal structures: a simulation study, IEEE Trans. Biomed. Eng, vol.40, pp.1175-1188, 1993.

S. S. Nagarajan, M. Durand, and E. N. Warman, Effects of induced electric fields on finite neuronal structures: a simulation study, Biomed. Eng. IEEE Trans. On, vol.40, pp.1175-1188, 1993.

N. Nagoshi, S. Kaneko, K. Fujiyoshi, M. Takemitsu, M. Yagi et al., Characteristics of neuropathic pain and its relationship with quality of life in 72 patients with spinal cord injury, Spinal Cord, vol.54, p.656, 2016.

F. Nahmias, C. Debes, D. C. De-andrade, A. Mhalla, and D. Bouhassira, Diffuse analgesic effects of unilateral repetitive transcranial magnetic stimulation (rTMS) in healthy volunteers, Pain, vol.147, pp.224-232, 2009.

B. D. Nicholson, Evaluation and treatment of central pain syndromes, Neurology, vol.62, pp.30-36, 2004.

M. A. Nitsche and W. Paulus, Excitability changes induced in the human motor cortex by weak transcranial direct current stimulation, J. Physiol, vol.527, pp.633-639, 2000.

M. A. Nitsche and W. Paulus, Sustained excitability elevations induced by transcranial DC motor cortex stimulation in humans, Neurology, vol.57, pp.1899-1901, 2001.

M. A. Nitsche, L. G. Cohen, E. M. Wassermann, A. Priori, N. Lang et al., Transcranial direct current stimulation: State of the art, Brain Stimulat, vol.1, pp.206-223, 2008.

C. Nuti, R. Peyron, L. Garcia-larrea, J. Brunon, B. Laurent et al., Motor cortex stimulation for refractory neuropathic pain: Four year outcome and predictors of efficacy, Pain, vol.118, pp.43-52, 2005.

N. E. O'connell, B. M. Wand, L. Marston, S. Spencer, and L. H. Desouza, Noninvasive brain stimulation techniques for chronic pain, Cochrane Database of Systematic Reviews, 2014.

N. E. O'connell, L. Marston, S. Spencer, L. H. Desouza, and B. M. Wand, Noninvasive brain stimulation techniques for chronic pain, Cochrane Database Syst. Rev, 2018.

M. J. O'donnell, H. Diener, R. L. Sacco, A. A. Panju, R. Vinisko et al., Chronic Pain Syndromes After Ischemic Stroke: PRoFESS Trial, PRoFESS Investigators, vol.44, pp.1238-1243, 2013.

S. H. Ohn, W. H. Chang, C. Park, S. T. Kim, J. I. Lee et al.,

, Neural Correlates of the Antinociceptive Effects of Repetitive Transcranial Magnetic Stimulation on Central Pain After Stroke, Neurorehabil. Neural Repair, vol.26, pp.344-352

E. Onesti, M. Gabriele, C. Cambieri, M. Ceccanti, R. Raccah et al., H-coil repetitive transcranial magnetic stimulation for pain relief in patients with diabetic neuropathy: H-coil rTMS for painful diabetic neuropathy, Eur. J. Pain, vol.17, pp.1347-1356, 2013.

B. N. Pasley, E. A. Allen, and R. D. Freeman, State-Dependent Variability of Neuronal Responses to Transcranial Magnetic Stimulation of the Visual Cortex, Neuron, vol.62, pp.291-303, 2009.

A. Passard, N. Attal, R. Benadhira, L. Brasseur, G. Saba et al., Effects of unilateral repetitive transcranial magnetic stimulation of the motor cortex on chronic widespread pain in fibromyalgia, Brain, vol.130, pp.2661-2670, 2007.

T. Paus, R. Jech, C. J. Thompson, R. Comeau, T. Peters et al., , 1997.

, Transcranial magnetic stimulation during positron emission tomography: a new method for studying connectivity of the human cerebral cortex, J. Neurosci, vol.17, pp.3178-3184

M. Peciña, A. S. Bohnert, M. Sikora, E. T. Avery, S. A. Langenecker et al., Association Between Placebo-Activated Neural Systems and Antidepressant Responses: Neurochemistry of Placebo Effects in Major Depression, JAMA Psychiatry, vol.72, p.1087, 2015.

M. Peciña, T. Love, C. Stohler, D. Goldman, and J. Zubieta, Effects of the Mu Opioid Receptor Polymorphism ( OPRM1 A118G) on Pain Regulation, Placebo Effects and Associated Personality Trait Measures, Am. Coll. Neuropsychopharmacol, 2015.

G. L. Petersen, N. B. Finnerup, K. Grosen, H. K. Pilegaard, I. Tracey et al., Expectations and positive emotional feelings accompany reductions in ongoing and evoked neuropathic pain following placebo interventions, Pain, vol.155, pp.2687-2698, 2014.

P. Petrovic, E. A. Kalso, K. Pertersson, and M. Ingvar, Placebo and Opioid Analgesia-Imaging a Shared Neuronal Network, Science, vol.295, 2002.

R. Peyron, I. Faillenot, P. Mertens, B. Laurent, and L. Garcia-larrea, Motor cortex stimulation in neuropathic pain. Correlations between analgesic effect and hemodynamic changes in the brain. A PET study, NeuroImage, vol.34, pp.310-321, 2007.

R. Peyron, I. Faillenot, and C. Créac'h, What can fMRI tell us on the brain of 35 patients with neuropathic pain, 2018.

F. B. Pomares, I. Faillenot, F. G. Barral, and R. Peyron, The "where"and the "when"of the BOLD response to pain in the insular cortex. Discussion on amplitudes and latencies, Neuroimage, vol.64, pp.466-475, 2013.
URL : https://hal.archives-ouvertes.fr/hal-00793562

B. Pommier, C. Créac'h, V. Beauvieux, C. Nuti, F. Vassal et al., Robotguided neuronavigated rTMS as an alternative therapy for central (neuropathic) pain: Clinical experience and long-term follow-up, Eur. J. Pain, vol.20, pp.907-916, 2016.

B. Pommier, F. Vassal, C. Boutet, S. Jeannin, R. Peyron et al., Easy methods to make the neuronavigated targeting of DLPFC accurate and routinely accessible for rTMS, Neurophysiol. Clin. Neurophysiol, vol.47, pp.35-46, 2017.
URL : https://hal.archives-ouvertes.fr/hal-02138815

B. Pommier, C. Quesada, C. Fauchon, C. Nuti, F. Vassal et al., Added value of multiple versus single sessions of repetitive transcranial magnetic stimulation in predicting motor cortex stimulation efficacy for refractory neuropathic pain, J. Neurosurg, pp.1-12, 2018.

C. Quesada, B. Pommier, C. Fauchon, C. Bradley, C. Créac'h et al., Robot-Guided Neuronavigated Repetitive Transcranial Magnetic Stimulation (rTMS) in Central Neuropathic Pain, Arch. Phys. Med. Rehabil, 2018.

C. Quesada, B. Pommier, C. Créac'h, M. Murat, F. Vassal et al., , 2018.

, Repetitive Transcranial Magnetic Stimulation (rTMS) for neuropathic pain A randomized controlled-placebo cross-over study

V. Radhakrishnan, J. Tsoukatos, K. D. Davis, R. R. Tasker, A. M. Lozano et al., A comparison of the burst activity of lateral thalamic neurons in chronic pain and non-pain patients, Pain, vol.80, pp.567-575, 1999.

T. Radman, A. Datta, R. L. Ramos, J. C. Brumberg, and M. Bikson, Onedimensional representation of a neuron in a uniform electric field, pp.6481-6484, 2009.

T. T. Raij, N. Forss, A. Stancák, H. , and R. , Modulation of motor-cortex oscillatory activity by painful A?-and C-fiber stimuli, NeuroImage, vol.23, pp.569-573, 2004.

B. J. Roth and P. J. Basser, A model of the stimulation of a nerve fiber by electromagnetic induction, IEEE Trans. Biomed. Eng, vol.37, pp.588-597, 1990.

B. J. Roth, J. M. Saypol, M. Hallett, and L. G. Cohen, A theoretical calculation of the electric field induced in the cortex during magnetic stimulation, Electroencephalogr. Clin. Neurophysiol. Potentials Sect, vol.81, pp.47-56, 1991.

Y. Saitoh, A. Hirayama, H. Kishima, T. Shimokawa, S. Oshino et al., Reduction of intractable deafferentation pain due to spinal cord or peripheral lesion by high-frequency repetitive transcranial magnetic stimulation of the primary motor cortex, 2007.

K. Sakai, Y. Ugawa, Y. Terao, R. Hanajima, T. Furubayashi et al., , 1997.

, Preferential activation of different I waves by transcranial magnetic stimulation with a figureof-eight-shaped coil, Exp. Brain Res, vol.113, pp.24-32

A. Samii, E. M. Wassermann, K. Ikoma, B. Mercuri, and M. Hallett, , 1996.

, Characterization of postexercise facilitation and depression of motor evoked potentials to transcranial magnetic stimulation, Neurology, vol.46, pp.1376-1376

V. Sankarasubramanian, A. G. Machado, A. B. Conforto, K. A. Potter-baker, D. A. Cunningham et al., Inhibition versus facilitation of contralesional motor cortices in stroke: Deriving a model to tailor brain stimulation, Clin. Neurophysiol, vol.128, pp.892-902, 2017.

C. M. Santos, J. N. Francischi, P. Lima-paiva, K. A. Sluka, and M. A. Resende, Effect of transcutaneous electrical stimulation on nociception and edema induced by peripheral serotonin, Int. J. Neurosci, vol.123, pp.507-515, 2013.

H. N. Schnitzlein, The Human Brain: An Introduction To Its Functional Anatomy, 1999.

R. J. Schwartzman and J. Maleki, Postinjury neuropathic pain syndromes, Med. Clin. North Am, vol.83, pp.597-626, 1999.

R. J. Schwartzman, J. Grothusen, T. R. Kiefer, and P. Rohr, Neuropathic central pain: epidemiology, etiology, and treatment options, Arch. Neurol, vol.58, pp.1547-1550, 2001.

B. J. Seewoo, K. W. Feindel, S. J. Etherington, R. , and J. , Resting-state fMRI study of brain activation using low-intensity repetitive transcranial magnetic stimulation in rats, Sci. Rep, vol.8, 2018.

F. Seifert, O. Fuchs, F. T. Nickel, M. Garcia, A. Dörfler et al., A functional magnetic resonance imaging navigated repetitive transcranial magnetic stimulation study of the posterior parietal cortex in normal pain and hyperalgesia, Neuroscience, vol.170, pp.670-677, 2010.

C. N. Shealy, J. T. Mortimer, and J. B. Reswick, Electrical inhibition of pain by stimulation of the dorsal columns, Anesth Analg, vol.46, pp.489-491, 1967.

B. E. Short, J. J. Borckardt, B. S. Anderson, H. Frohman, W. Beam et al., Ten sessions of adjunctive left prefrontal rTMS significantly reduces fibromyalgia pain: A randomized, vol.152, pp.2477-2484, 2011.

S. Zhang, T. Yin, Z. Liu, Y. Li, J. Jin et al., Experimental Study to Improve the Focalization of a Figure-Eight Coil of rTMS by Using a Highly Conductive and Highly Permeable Medium, IEEE Trans. Neural Syst. Rehabil. Eng, vol.21, pp.364-369, 2013.

S. Silva, P. J. Basser, and P. C. Miranda, The activation function of TMS on a finite element model of a cortical sulcus, EMBS 2007. 29th Annual International Conference of the IEEE, pp.6656-6659, 2007.

S. Silva, P. J. Basser, and P. C. Miranda, Elucidating the mechanisms and loci of neuronal excitation by transcranial magnetic stimulation using a finite element model of a cortical sulcus, Clin. Neurophysiol, vol.119, pp.2405-2413, 2008.

M. Simonetta-moreau, Non-invasive brain stimulation (NIBS) and motor recovery after stroke, Ann. Phys. Rehabil. Med, vol.57, pp.530-542, 2014.

K. V. Slavin, Spinal Stimulation for Pain: Future Applications, Neurotherapeutics, vol.11, pp.535-542, 2014.

B. Son, D. Kim, H. Kim, and S. Lee, Simultaneous Trial of Deep Brain and Motor Cortex Stimulation in Chronic Intractable Neuropathic Pain, Stereotact. Funct. Neurosurg, vol.92, pp.218-226, 2014.

C. J. Starr, L. Sawaki, G. F. Wittenberg, J. H. Burdette, Y. Oshiro et al., Roles of the Insular Cortex in the Modulation of Pain: Insights from Brain Lesions, J. Neurosci, vol.29, pp.2684-2694, 2009.

J. Talairach and P. Tournoux, Co-planar stereotaxic atlas of the human brain: 3-Dimensional proportional system: An approach to cerebral imaging, 1988.

G. Tay, M. Chilbert, J. Battocletti, A. Sances, T. Swiontek et al., Measurement of magnetically induced current density in saline in vivo, Proceedings of the Annual International Conference of the IEEE Engineering, pp.1167-1168, 1989.

J. L. Taylor and S. C. Gandevia, Noninvasive stimulation of the human corticospinal tract, J. Appl. Physiol, vol.96, pp.1496-1503, 2004.

T. Tazoe and M. A. Perez, Effects of Repetitive Transcranial Magnetic Stimulation on Recovery of Function After Spinal Cord Injury, Arch. Phys. Med. Rehabil, vol.96, pp.145-155, 2015.

A. Thielscher and T. Kammer, Linking Physics with Physiology in TMS: A Sphere Field Model to Determine the Cortical Stimulation Site in TMS, NeuroImage, vol.17, pp.1117-1130, 2002.

A. Thielscher and T. Kammer, Electric field properties of two commercial figure-8 coils in TMS: calculation of focality and efficiency, Clin. Neurophysiol, vol.115, pp.1697-1708, 2004.

M. Tilak, S. A. Isaac, J. Fletcher, L. T. Vasanthan, R. S. Subbaiah et al., Mirror Therapy and Transcutaneous Electrical Nerve Stimulation for Management of Phantom Limb Pain in Amputees -A Single Blinded Randomized Controlled Trial: Mirror Therapy Versus TENS for Phantom Limb Pain, Physiother. Res. Int, vol.21, pp.109-115, 2016.

I. Tracey and P. W. Mantyh, The Cerebral Signature for Pain Perception and Its Modulation, Neuron, vol.55, pp.377-391, 2007.

D. K. Tracy, O. O'daly, D. W. Joyce, P. G. Michalopoulou, B. B. Basit et al., An evoked auditory response fMRI study of the effects of rTMS on putative AVH pathways in healthy volunteers, Neuropsychologia, vol.48, pp.270-277, 2010.

T. Tsubokawa, T. Yamamoto, Y. Katayama, S. Miyazaki, H. Nishimoto et al., Deep Brain Stimulation for Relief of Intractable Pain, Neurol. Med. Chir. (Tokyo), vol.22, pp.211-218, 1982.

T. Tsubokawa, Y. Katayama, T. Yamamoto, T. Hirayama, K. et al., Treatment of thalamic pain by chronic motor cortex stimulation, Pacing Clin. Electrophysiol, vol.14, pp.131-134, 1991.

M. Valeriani, C. Pazzaglia, V. Rizzo, A. Quartarone, and C. Vollono, Laser evoked potential amplitude and laser-pain rating reduction during high-frequency non-noxious somatosensory stimulation, Clin. Neurophysiol, vol.129, pp.920-925, 2018.

A. Vlachos, F. Muller-dahlhaus, J. Rosskopp, M. Lenz, U. Ziemann et al., Repetitive Magnetic Stimulation Induces Functional and Structural Plasticity of Excitatory Postsynapses in Mouse Organotypic Hippocampal Slice Cultures, J. Neurosci, vol.32, pp.17514-17523, 2012.

C. A. Von-hehn, R. Baron, and C. J. Woolf, Deconstructing the Neuropathic Pain Phenotype to Reveal Neural Mechanisms, Neuron, vol.73, pp.638-652, 2012.

T. Wagner, M. Gangitano, R. Romero, H. Théoret, M. Kobayashi et al., Intracranial measurement of current densities induced by transcranial magnetic stimulation in the human brain, Neurosci. Lett, vol.354, pp.91-94, 2004.

T. Wagner, F. Fregni, U. Eden, C. Ramos-estebanez, A. Grodzinsky et al., Transcranial magnetic stimulation and stroke: A computer-based human model study, NeuroImage, vol.30, pp.857-870, 2006.

T. Wagner, J. Rushmore, U. Eden, and A. Valero-cabre, Biophysical foundations underlying TMS: Setting the stage for an effective use of neurostimulation in the cognitive neurosciences, Cortex, vol.45, pp.1025-1034, 2009.

T. A. Wagner, M. Zahn, A. J. Grodzinsky, and A. Leone, ThreeDimensional Head Model Simulation of Transcranial Magnetic Stimulation, IEEE Trans. Biomed. Eng, vol.51, pp.1586-1598, 2004.

G. Wang and S. M. Thompson, Maladaptive Homeostatic Plasticity in a Rodent Model of Central Pain Syndrome: Thalamic Hyperexcitability after Spinothalamic Tract Lesions, J. Neurosci, vol.28, pp.11959-11969, 2008.

T. Wang, Z. Chen, G. Zhao, G. Hitchman, C. Liu et al., Linking inter-individual differences in the conflict adaptation effect to spontaneous brain activity, NeuroImage, vol.90, pp.146-152, 2014.

L. Werhagen, C. N. Budh, C. Hultling, and C. Molander, Neuropathic pain after traumatic spinal cord injury-relations to gender, spinal level, completeness, and age at the time of injury, Spinal Cord, vol.42, p.665, 2004.

K. Wiech, Deconstructing the sensation of pain: The influence of cognitive processes on pain perception, Science, vol.354, pp.584-587, 2016.

A. Williamson and B. Hoggart, Pain: a review of three commonly used pain rating scales, J. Clin. Nurs, vol.14, pp.798-804, 2005.

W. D. Willis, Supraspinal control of ascending pathways, Progress in Brain Research, pp.163-174, 1979.

R. P. Yezierski, K. D. Gerhart, B. J. Schrock, and W. D. Willis, A further examination of effects of cortical stimulation on primate spinothalamic tract cells, J. Neurophysiol, vol.49, pp.424-441, 1983.

A. Zangen and K. Hyodo, Transcranial magnetic stimulation induces increases in extracellular levels of dopamine and glutamate in the nucleus accumbens, Neuroreport, vol.13, pp.2401-2405, 2002.

X. Zhang, Y. Mei, C. Liu, Y. , and S. , Effect of transcranial magnetic stimulation on the expression of c-Fos and brain-derived neurotrophic factor of the cerebral cortex in rats with cerebral infarct, J. Huazhong Univ. Sci. Technol, vol.27, pp.415-418, 2007.

M. Zhuo, Contribution of synaptic plasticity in the insular cortex to chronic pain, Neuroscience, vol.338, pp.220-229, 2016.

U. Ziemann, S. Lönnecker, B. J. Steinhoff, and W. Paulus, Effects of antiepileptic drugs on motor cortex excitability in humans: a transcranial magnetic stimulation study, Ann. Neurol, vol.40, pp.367-378, 1996.

M. Zunhammer, U. Bingel, and T. D. Wager, and for the Placebo Imaging Consortium, 2018.

, Placebo Effects on the Neurologic Pain Signature: A Meta-analysis of Individual Participant Functional Magnetic Resonance Imaging Data, JAMA Neurol