Andrianjafy, C., L. Luciano, A. Loundou, M. Bouvier, and V. Vitton. Three-dimensional high-resolution anorectal manometry can predict response to biofeedback therapy in defecation disorders. Int. J. Colorectal Dis. 34:1131–1140, 2019.
Aziz, I., O. S. Palsson, H. Törnblom, and A. D. Sperber. The prevalence and impact of overlapping Rome IV-diagnosed functional gastrointestinal disorders on somatization, quality of life, and healthcare utilization : a cross-sectional general population study in three countries. Am. J. Gastroenterol. 113:86–96, 2018.
Bartolo, D. C., J. A. Jarratt, and N. W. Read. The use of conventional electromyography to assess external sphincter neuropathy in man. J. Neurol. Neurosurg. Psychiatry 46:1115–1118, 1983.
Carrington, E. V., C. H. Knowles, U. Grossi, and S. M. Scott. High-resolution anorectal manometry measures are more accurate than conventional measures in detecting anal hypocontractility in women with fecal incontinence. Clin. Gastroenterol. Hepatol. 17:477–485, 2019.
Carrington, E. V., S. M. Scott, A. Bharucha, F. Mion, J. M. Remes, A. Malcolm, H. Heinrich, M. Fox, and S. S. Rao. Advances in the evaluation of anorectal function. Nat. Rev. Gastroenterol. Hepatol. 15:309–323, 2018.
Cescon, C., L. Mesin, M. Nowakowski, and R. Merletti. Geometry assessment of anal sphincter muscle based on monopolar multichannel surface EMG signals. J. Electromyogr. Kinesiol. 21:394–401, 2011.
Cescon, C., D. Riva, V. Za, K. Drusany-stari, K. Martsidis, O. Protsepko, K. Baessler, and R. Merletti. Effect of vaginal delivery on the external anal sphincter muscle innervation pattern evaluated by multichannel surface EMG: results of the multicentre study TASI-2. Int. Urogynecol. J. 25:1491–1499, 2014.
Chen, P.-J., M.-C. Lin, M.-J. Lai, J.-C. Lin, H. H.-S. Lu, and V. S. Tseng. Accurate classification of diminutive colorectal polyps using computer-aided analysis. Gastroenterology 154:568–575, 2018.
Cheong, D. M. O., C. A. Vaccaro, S. D. Waxner, V. D. Salanga, R. C. Phillips, and M. R. Hanson. Electrodiagnostic evaluation of fecal incontinence. Muscle Nerve 18:612–619, 1995.
Enck, P., H. Franz, F. Azpiroz, X. Fernandez-Fraga, H. Hinninghofen, K. Kaske-Bretag, A. Bottin, S. Martina, and R. Merletti. Innervation zones of the external anal sphincter in healthy male and female subjects. Digestion 69:123–130, 2004.
Gardiner, A., G. Kaur, J. Cundall, and G. S. Duthie. Neural network analysis of anal sphincter repair. Dis. Colon Rectum 47:192–197, 2004.
Hagiwara, Y., H. Fujita, S. L. Oh, J. H. Tan, R. San Tan, E. J. Ciaccio, and U. R. Acharya. Computer-aided diagnosis of atrial fibrillation based on ECG signals: a review. Inf. Sci. 467:99–114, 2018.
Hallett, M. Transcranial magnetic stimulation: a primer. Neuron 55:187–199, 2007.
Holobar, A., D. Farina, M. Gazzoni, R. Merletti, and D. Zazula. Estimating motor unit discharge patterns from high-density surface electromyogram. Clin. Neurophysiol. 120:551–562, 2009.
Holobar, A., and D. Zazula. Multichannel blind source separation using convolution kernel compensation. IEEE Trans. Signal Process. 55:4487–4496, 2007.
Kasius, K. M., F. Claes, J. Meulstee, H. C. Weinstein, and W. I. M. Verhagen. Comparison of peak versus onset latency measurements in electrodiagnostic tests for carpal tunnel syndrome. J. Clin. Neurophysiol. 31:382–386, 2014.
Kiff, E. S., F. S. Mark, and T. L. Hospital. Normal proximal and delayed distal conduction in the pudendal nerves of patients with idiopathic (neurogenic) faecal incontinence. J. Neurol. Neurosurg. Psychiatry 47:820–823, 1984.
Kiff, E. S., and M. Swash. Slowed conduction in the pudendal nerves in idiopathic (neurogenic) faecal incontinence. Br. J. Surg. 71:614–616, 1984.
Lacima, G., M. Pera, X. González-Argenté, A. Torrents, J. Valls-Solé, and M. Espuña-Pons. Is electromyography a predictive test of patient response to biofeedback in the treatment of fecal incontinence? Neurourol. Urodyn. 35:390–394, 2016.
Lefaucheur, J. P. Intrarectal ground electrode improves the reliability of motor evoked potentials recorded in the anal sphincter. Muscle Nerve 32:110–112, 2005.
Ludwig, K. A., R. M. Miriani, N. B. Langhals, M. D. Joseph, D. J. Anderson, and D. R. Kipke. Using a Common Average Reference To Improve Cortical Neuron Recordings From Microelectrode Arrays. J. Neurophysiol. 101:1679–1689, 2009.
Merletti, R., A. Bottin, C. Cescon, D. Farina, M. Gazzoni, S. Martina, L. Mesin, M. Pozzo, A. Rainoldi, and P. Enck. Multichannel surface EMG for the non-invasive assessment of the anal sphincter muscle. Digestion 69:112–122, 2004.
Meurette, G., C. Blanchard, E. Duchalais-Dassonneville, S. Coquenlorge, P. Aubert, M. Wong, P. A. Lehur, and M. Neunlist. Sacral nerve stimulation enhances epithelial barrier of the rectum: Results from a porcine model. Neurogastroenterol. Motil. 24:267-e110, 2012.
Nardone, R., Y. Höller, F. Brigo, A. Orioli, F. Tezzon, K. Schwenker, M. Christova, S. Golaszewski, and E. Trinka. Descending motor pathways and cortical physiology after spinal cord injury assessed by transcranial magnetic stimulation: a systematic review. Brain Res. 1619:139–154, 2015.
Nowakowski, M., K. A. Tomaszewski, R. M. Herman, J. Sałówka, M. Romaniszyn, M. Rubinkiewicz, and J. A. Walocha. Developing a new electromyography-based algorithm to diagnose the etiology of fecal incontinence. Int. J. Colorectal Dis. 29:747–754, 2014.
O’Grady, G., T. R. Angeli, N. Paskaranandavadivel, J. C. Erickson, C. I. Wells, A. A. Gharibans, L. K. Cheng, and P. Du. Methods for high-resolution electrical mapping in the gastrointestinal tract. IEEE Rev. Biomed. Eng. 12:287–302, 2018.
O’Grady, G., N. Paskaranandavadivel, T. R. Angeli, P. Du, J. A. Windsor, L. K. Cheng, and A. J. Pullan. A comparison of gold versus silver electrode contacts for high-resolution gastric electrical mapping using flexible printed circuit board arrays. Physiol. Meas. 32:N13–N22, 2011.
Paris, G., N. Chastan, G. Gourcerol, E. Verin, J. F. Menard, F. Michot, J. Weber, and A. M. Leroi. Evoked pressure curves from the external anal sphincter following transcranial magnetic stimulation in healthy volunteers and patients with faecal incontinence. Colorectal Dis. 15:e732–e740, 2013.
Paskaranandavadivel, N., L. K. Cheng, P. Du, G. O’Grady, and A. J. Pullan. Improved signal processing techniques for the analysis of high resolution serosal slow wave activity in the stomach. Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society, 2011, pp. 1737–1740.
Pelliccioni, G., O. Scarpino, and V. Piloni. Motor evoked potentials recorded from external anal sphincter by cortical and lumbo-sacral magnetic stimulation: normative data. J. Neurol. Sci. 149:69–72, 1997.
Peng, Y., J. He, R. Khavari, T. B. Boone, and Y. Zhang. Functional mapping of the pelvic floor and sphincter muscles from high-density surface EMG recordings. Int. Urogynecol. J. 27:1689–1696, 2016.
Rao, S. S. C., E. Coss-Adame, K. Tantiphlachiva, A. Attaluri, and J. Remes-Troche. Translumbar and transsacral magnetic neurostimulation for the assessment of neuropathy in fecal incontinence. Dis. Colon Rectum 57:645–652, 2014.
Rogers, J., M. M. Henry, and J. J. Misiewicz. Disposable pudendal nerve stimulator: evaluation of the standard instrument and new device. Gut 29:1131–1133, 1988.
Scott, S. M., and M. A. Gladman. Manometric, sensorimotor, and neurophysiologic evaluation of anorectal function. Gastroenterol. Clin. North Am. 37:511–538, 2008.
Shafik, A. Magnetic pudendal neurostimulation: a novel method for measuring pudendal nerve terminal motor latency. Clin. Neurophysiol. 112:1049–1052, 2001.
Sharma, A., L. Yuan, R. J. Marshall, A. E. H. Merrie, and I. P. Bissett. Systematic review of the prevalence of faecal incontinence. Br. J. Surg. 103:1589–1597, 2016.
Simpson, M., and R. Macdonell. The use of transcranial magnetic stimulation in diagnosis, prognostication and treatment evaluation in multiple sclerosis. Multiple Scler. Relat. Disord. 4:430–436, 2015.
Stinear, C. Prediction of recovery of motor function after stroke. Lancet Neurol. 9:1228–1232, 2010.
Tetzschner, T., M. Sørensen, O. Ø. Rasmussen, G. Lose, and J. Christiansen. Reliability of pudendal nerve terminal motor latency. Int. J. Colorectal Dis. 12:280–284, 1997.
Thomas, C., J.-P. Lefaucheur, G. Galula, V. de Parades, J. Bourguignon, and P. Atienza. Respective value of pudendal nerve terminal motor latency and anal sphincter electromyography in neurogenic fecal incontinence. Clin. Neurophysiol. 32:85–90, 2002.
Turnbull, G. K., S. Hamdy, Q. Aziz, K. D. Singh, and D. G. Thompson. The cortical topography of human anorectal musculature. Gastroenterology 117:32–39, 1999.
Weber, M., and A. A. Eisen. Magnetic stimulation of the central and peripheral nervous systems. Muscle Nerve 25:160–175, 2002.
Whitehead, W. E., L. Borrud, P. S. Goode, S. Meikle, E. R. Mueller, A. Tuteja, A. Weidner, M. Weinstein, and W. Ye. Fecal incontinence in US adults: epidemiology and risk factors. Gastroenterology 137:512–517.e2, 2009.
Whitehead, W. E., A. Wald, N. E. Diamant, P. Enck, J. H. Pemberton, and S. S. C. Rao. Functional disorders of the anus and rectum. Gut II45:II55–59, 1999.
Xiang, X., T. Patcharatrakul, A. Sharma, R. Parr, S. Hamdy, and S. S. C. Rao. Cortico-anorectal, spino-anorectal, and cortico-spinal nerve conduction and locus of neuronal injury in patients with fecal incontinence. Clin. Gastroenterol. Hepatol. 17:1130–1137.e2, 2019.
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