Summary
The last decade has seen a rapid growth in surgical techniques directed at resection of skull base tumors. Lesions that were previously inoperable can now be resected either partially or in some cases completely. The morbidity in these procedures has diminished with increased surgical experience. Additional aids to successful surgical resection include intraoperative neurophysiologic monitoring techniques. The following text out-lines methods of monitoring cranial nerve and brain function in a manner that is directly relevant to cranial base surgery in which so many structures are potentially at risk. These techniques permit the identification of nerves obscured by tumor before they may be inadvertently damaged, the repeated confirmation during tumor resection that a nerve is still functional, and infer the state of brain and brainstem function during the course of long surgical procedures to help signal vascular compromise, or the effects of brain retraction. These techniques can only help to enhance the safety of the long and complex procedures required for successful resection of tumors of the cranial base.
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References
Jewett DL, Romano MN, Williston JS: Human auditory evoked potentials: Possible brain stem components detected at the scalp. Science 167: 1517–1518, 1970
Moller AR, Jannetta PJ, Moller MB: Neural generators of brainstem evoked potentials. Results from human intracranial recordings. Ann Otol 90: 591–596, 1981
Moller AR: Evoked Potentials in Intraoperative Monitoring. Williams and Wilkins, Baltimore 52, 1988
Moller AR, Moller MB: Does intraoperative monitoring of auditory evoked potentials reduce incidence of hearing loss as a complication of microvascular decompression of cranial nerves? Neurosurgery 24: 257–263, 1989
Friedman WA, Kaplan BJ, Gravenstein D, Rhoton AL: Intraoperative brain-stem auditory evoked potentials during posterior fossa microvascular decompression. J Neurosurg 62: 552–557, 1985
Sekiya T, Iwabuchi T, Hatayama T, Shinozaki N: Vestibular nerve injury as a complication of microvascular decompression. Neurosurg 29: 773–776, 1991
Piatt JH, Radtke RA, Erwin CW: Limitations of brain stem auditory evoked potentials for intraoperative monitoring during a posterior fossa operation: case report and technical note. Neurosurgery 16: 818–821, 1985
Momma F, Wang AD, Symon L: Effects of temporary arterial occlusion on somatosensory evoked responses in aneurysm surgery. Surg Neurol 27: 343–352, 1987
Perlik SJ, VanEgeren R, Fisher MA: Somatosensory evoked potential surgical monitoring. Observations during combined isoflurane-nitrous oxide anesthesia. Spine 17: 273, 1982
Brown RH, Nash CL: Intra-operative spinal cord monitoring. In: Frymoywer JW (ed) The Adult Spine: Principles and Practice, Raven Press, New York 549–562, 1991
Stechison MT, Kralick FJ: The trigeminal evoked potential: Part I. Long-latency responses in awake or anesthetized subjects. Neurosurg 33: 633–638, 1993
Stechison MT: The trigeminal evoked potential: Part II: Intraoperative recording of short-latency responses. Neurosurg 33: 639–644, 1993
Cedzich C, Schramm J, Fahlbusch R: Are flash-evoked visual potentials useful for intraoperative monitoring of visual pathway function? Neurosurgery 21: 709–715, 1987
Cedzich C, Schramm J, Mengedoht CF, Fahlbusch R: Factors that limit the use of flash visual evoked potentials for surgical monitoring. Electroencephalog and Clinical Neurophys 71: 142–145, 1988
Albright AL, Sclabassi RJ: Cavitron ultrasonic surgical aspirator and visual evoked potential monitoring for chiasmal gliomas in children. J Neurosurg 63: 138–140, 1985
Moller AR: Neuromonitoring in operations in the skull base. Keio J Med 40: 151–159, 1991
Delgado TE, Buchheit WA, Rosenholtz HR, Chrissian S: Intraoperative monitoring of facial muscle evoked responses obtained by intracranial stimulation of the facial nerve: A more accurate technique for facial nerve dissection. J Neurosurg 4: 418–421, 1979
Prass R, Luders H: Acoustic (loud-speaker) facial electro-myographic activity during acoustic neuroma resection. Neurosurgery 19: 392–400, 1986
Kartush JM: Electroneurography and intraoperative facial monitoring in contemporary neurotology. Otolaryngol Head and Neck Surg 101: 496–503, 1989
Bergmans J: Neurophysiological features of experimental and human neuropathies. In: Battistin L, Hashim G, Lajitha A (eds) Clinical and Biological Aspects of Peripheral Nerve Diseases. AR Liss, New York 73–100, 1983
Richmond IL, Mahla M: Use of antidromic recording to monitor facial nerve function intraoperatively. Neurosurgery 16: 458–462, 1985
Niparko JK, Kileny PR, Kemink JL, Lee HM, Graham MD: Neurophysiologic intraoperative monitoring: II. Facial Nerve Function. Am J Otol 10: 55–61, 1989
Harner SG, Daube JR, Ebersold MJ: Electrophysiologic monitoring of facial nerve during temporal bone surgery. Laryngoscope 96: 65–69, 1986
Hammond EJ, Uthman BM, Reid SA, Wilder BJ, Emay EW: Vagus nerve stimulation in humans. Neurophysiological Studies and Electrophysiological Monitoring. Epilepsia 31 (Suppl 2): 551–550, 1990
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Stechison, M.T. Neurophysiologic monitoring during cranial base surgery. J Neuro-Oncol 20, 313–325 (1994). https://doi.org/10.1007/BF01053046
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DOI: https://doi.org/10.1007/BF01053046