OBJECTIVE: Intraoperative localisation of the sensorimotor cortex using the phase reversal of somatosensory evoked potentials (SEPs) is an essential tool for surgery in and around the perirolandic gyri, but unsuccessful and perplexing results have been reported. This study examines the effect of tumour masses on the waveform characteristics and feasibility of SEP compared with functional neuronavigation and electrical motor cortex mapping. METHODS: In 230 patients with tumours of the sensorimotor region the SEP phase reversal of N20-P20 was recorded from the exposed cortex using a subdural grid or strip electrode. In one subgroup of 80 patients functional neuronavigation was performed with motor and sensory magnetic source imaging and in one subgroup of 40 patients the motor cortex hand area was localised by electrical stimulation mapping. RESULTS: The intraoperative SEP method was successful in 92% of all patients, it could be shown that the success rate rather depended on the location of the lesion than on preoperative neurological deficits. In 13% of the patients with postcentral tumours no N20-P20 phase reversal was recorded but characteristic polyphasic and high amplitude waves at 25 ms and later made the identification of the postcentral gyrus possible nevertheless. Electrical mapping of the motor cortex took up to 30 minutes until a clear result was obtained. It was successful in 37 patients, but failed in three patients with precentral and central lesions. Functional neuronavigation indicating the tumour margins and the motor and sensory evoked fields was possible in all patients. CONCLUSION: The SEP phase reversal of N20-P20 is a simple and reliable technique, but the success rate is much lower in large central and postcentral tumours. With the use of polyphasic late waveforms the sensorimotor cortex may be localised. By contrast with motor electrical mapping it is less time consuming. Functional neuronavigation is a desirable tool for both preoperative surgical planning and intraoperative use during surgery on perirolandic tumours, but compensation for brain shift, accuracy, and cost effectiveness are still a matter for discussion.
OBJECTIVE: Intraoperative localisation of the sensorimotor cortex using the phase reversal of somatosensory evoked potentials (SEPs) is an essential tool for surgery in and around the perirolandic gyri, but unsuccessful and perplexing results have been reported. This study examines the effect of tumour masses on the waveform characteristics and feasibility of SEP compared with functional neuronavigation and electrical motor cortex mapping. METHODS: In 230 patients with tumours of the sensorimotor region the SEP phase reversal of N20-P20 was recorded from the exposed cortex using a subdural grid or strip electrode. In one subgroup of 80 patients functional neuronavigation was performed with motor and sensory magnetic source imaging and in one subgroup of 40 patients the motor cortex hand area was localised by electrical stimulation mapping. RESULTS: The intraoperative SEP method was successful in 92% of all patients, it could be shown that the success rate rather depended on the location of the lesion than on preoperative neurological deficits. In 13% of the patients with postcentral tumours no N20-P20 phase reversal was recorded but characteristic polyphasic and high amplitude waves at 25 ms and later made the identification of the postcentral gyrus possible nevertheless. Electrical mapping of the motor cortex took up to 30 minutes until a clear result was obtained. It was successful in 37 patients, but failed in three patients with precentral and central lesions. Functional neuronavigation indicating the tumour margins and the motor and sensory evoked fields was possible in all patients. CONCLUSION: The SEP phase reversal of N20-P20 is a simple and reliable technique, but the success rate is much lower in large central and postcentral tumours. With the use of polyphasic late waveforms the sensorimotor cortex may be localised. By contrast with motor electrical mapping it is less time consuming. Functional neuronavigation is a desirable tool for both preoperative surgical planning and intraoperative use during surgery on perirolandic tumours, but compensation for brain shift, accuracy, and cost effectiveness are still a matter for discussion.
Authors: Francesco Sala; Paolo Manganotti; Stefan Grossauer; Vincenzo Tramontanto; Carlo Mazza; Massimo Gerosa Journal: Childs Nerv Syst Date: 2010-02-10 Impact factor: 1.475
Authors: Giancarlo D'Andrea; Albina Angelini; Andrea Romano; Antonio Di Lauro; Giovanni Sessa; Alessandro Bozzao; Luigi Ferrante Journal: Neurosurg Rev Date: 2012-02-28 Impact factor: 3.042
Authors: Giannantonio Spena; Philippe Schucht; Kathleen Seidel; Geert-Jan Rutten; Christian Franz Freyschlag; Federico D'Agata; Emanule Costi; Francesca Zappa; Marco Fontanella; Denys Fontaine; Fabien Almairac; Michele Cavallo; Pasquale De Bonis; Gerardo Conesa; Nicholas Foroglou; Santiago Gil-Robles; Emanuel Mandonnet; Juan Martino; Thomas Picht; Catarina Viegas; Michel Wager; Johan Pallud Journal: Neurosurg Rev Date: 2016-08-01 Impact factor: 3.042
Authors: Phiroz E Tarapore; Matthew C Tate; Anne M Findlay; Susanne M Honma; Danielle Mizuiri; Mitchel S Berger; Srikantan S Nagarajan Journal: J Neurosurg Date: 2012-06-15 Impact factor: 5.115
Authors: Francesco Signorelli; J Guyotat; C Mottolese; F Schneider; G D'Acunzi; J Isnard Journal: Childs Nerv Syst Date: 2004-05-07 Impact factor: 1.475