Patients benefit from neuromonitoring during certain surgical procedures, namely any surgery where there is risk to the
nervous system. Most neuromonitoring is utilized by spine surgeons, but neurosurgeons, vascular, orthopedic, otolaryngologists, and urology surgeons have all utilized neuromonitoring as well. The most common applications are in spinal surgery; selected brain surgeries;
carotid endarterectomy;
ENT procedures such as
acoustic neuroma (vestibular schwannoma) resection, parotidectomy; and
nerve surgery. Motor evoked potentials have also been used in surgery for
thoracic aortic aneurysm. Intraoperative monitoring is used to : • to localize neural structures, for example to locate
cranial nerves during skull base surgery; • to test function of these structures; and • for early detection of intraoperative neural injury, allowing for immediate corrective measures. For example, during any surgery on the
thoracic or
cervical spinal column, there is some risk to the spinal cord. Since the 1970s, SSEP (
somatosensory evoked potentials) have been used to monitor spinal cord function by stimulating a nerve
distal to the surgery, and recording from the cerebral cortex or other locations
rostral to the surgery. A baseline is obtained, and if there are no significant changes, the assumption is that the spinal cord has not been injured. If there is a significant change, corrective measures can be taken; for example, the hardware can be removed. More recently, transcranial electric
motor evoked potentials (TCeMEP) have also been used for spinal cord monitoring. This is the reverse of SSEP; the motor cortex is stimulated transcranially, and recordings made from muscles in the limbs, or from spinal cord
caudal to the surgery. This allows direct monitoring of motor tracts in the spinal cord. EEG
electroencephalography is used for monitoring of cerebral function in neurovascular cases (cerebral aneurysms, carotid
endarterectomy) and for defining tumor margins in
epilepsy surgery and some cerebral tumors. EEG measures taken during anesthesia exhibit stereotypic changes as
anesthetic depth increases. These changes include complex patterns of waves with
frequency slowing accompanied by
amplitude increases which typically peak when
loss of consciousness occurs (loss of responses to verbal commands; loss of righting reflex). As anesthetic depth increases from light surgical levels to deep anesthesia, the EEG exhibits disrupted rhythmic waveforms, high amplitude burst suppression activity, and finally, very low amplitude isoelectric or 'flat line' activity. Various
signal analysis approaches have been used to quantify these pattern changes and can provide an indication of loss of recall, loss of consciousness and
anesthetic depth. Monitors have been developed using various
algorithms for signal analysis and are commercially available, but none have as yet proven 100% accurate. This is a difficult problem and an active area of medical research. EMG is used for cranial nerve monitoring in skull base cases and for nerve root monitoring and testing in spinal surgery. ABR (a.k.a. BSEP, BSER, BAEP, etc.) is used for monitoring of the acoustic nerve during acoustic neuroma and brainstem tumor resections. ==Licensure, certification, credentialing, and evidence==