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ویرایش: 2 نویسندگان: Vedran Deletis (editor), Jay L. Shils (editor), Kathleen Seidel (editor), Francesco Sala (editor) سری: ISBN (شابک) : 9780128150016, 0128150017 ناشر: سال نشر: 2020 تعداد صفحات: 645 زبان: English فرمت فایل : PDF (درصورت درخواست کاربر به PDF، EPUB یا AZW3 تبدیل می شود) حجم فایل: 29 مگابایت
در صورت تبدیل فایل کتاب Neurophysiology in neurosurgery : a modern approach به فرمت های PDF، EPUB، AZW3، MOBI و یا DJVU می توانید به پشتیبان اطلاع دهید تا فایل مورد نظر را تبدیل نمایند.
توجه داشته باشید کتاب نوروفیزیولوژی در جراحی مغز و اعصاب: یک رویکرد مدرن نسخه زبان اصلی می باشد و کتاب ترجمه شده به فارسی نمی باشد. وبسایت اینترنشنال لایبرری ارائه دهنده کتاب های زبان اصلی می باشد و هیچ گونه کتاب ترجمه شده یا نوشته شده به فارسی را ارائه نمی دهد.
Cover Neurophysiology in Neurosurgery Copyright Dedication Reference Contents List of contributors Preface Intraoperative neurophysiological monitoring—why we need it and a personal perspective of its development 1 Introduction 2 Theoretical background 3 Detection of developing neural damage and avoidance of permanent deficits 4 Intraoperative neurophysiological monitoring as a teaching tool 5 Detection of adverse systemic or nonsurgical influences 6 Reassurance to surgeon about lack of damaging effect of specific risky maneuvers 7 Value of intraoperative neurophysiological monitoring in today’s world 8 Conclusion on why we need intraoperative neurophysiological monitoring 9 A personal perspective on the development of intraoperative neurophysiological monitoring 9.1 An early period of evoked potential applications 9.2 From diagnostics to intraoperative neurophysiological monitoring 9.3 Further clinical development 9.4 The problem of motor-evoked potentials monitoring 10 Conclusion References Part I: Introduction to intraoperative neurophysiology 1 Animal and human motor system neurophysiology related to intraoperative monitoring 1.1 Introduction 1.2 Corticospinal responses 1.2.1 Configuration of corticospinal tract waves 1.2.1.1 Conducted impulses 1.2.1.2 Blocked impulses 1.2.2 Eliciting D waves 1.2.3 Eliciting I waves 1.2.3.1 Extrinsic inputs 1.2.3.2 Intrinsic inputs 1.3 Muscle responses References 2 Intraoperative neurophysiology and methodologies used to monitor the functional integrity of the motor system 2.1 Intraoperative monitoring of the motor system: a brief history 2.1.1 Penfield’s time 2.1.2 Spinal cord to spinal cord 2.1.3 Spinal cord to peripheral nerve (muscle) 2.2 New methodologies 2.2.1 Single-pulse stimulation technique 2.2.2 Multipulse stimulation technique 2.3 Methodological aspects of transcranial electrical stimulation during general anesthesia 2.3.1 Electrode montage over the scalp for eliciting motor-evoked potentials (for single and multipulse stimulation techniques) 2.4 Recording of MEPs over the spinal cord (epidural and subdural spaces) using single-pulse stimulation technique 2.4.1 D-wave recording technique through an epidurally or subdurally inserted electrode 2.4.1.1 Choice of electrode 2.4.2 Proper placement of epidural electrodes 2.4.2.1 Percutaneous placement of catheter electrode 2.4.2.2 Placement of electrode after laminectomy/laminotomy or flavectomy/flavotomy 2.4.3 Factors influencing D- and I-wave recordings 2.4.4 Neurophysiological mechanisms leading to the desynchronization of the D-wave 2.5 Recording of motor-evoked potentials in limb muscles elicited by a multipulse stimulating technique 2.5.1 Selection of optimal muscles in upper and lower extremities for motor-evoked potential recordings 2.5.2 Neurophysiological mechanisms for eliciting muscle motor-evoked potentials using a multipulse stimulation technique 2.5.2.1 Recovery of amplitude and latency of the D-wave 2.5.2.2 Facilitation of I-wave 2.5.2.3 Total number of D- and I-waves 2.5.2.4 Generation of muscle MEPs depends on two systems: the CST and the supportive system of the spinal cord 2.5.3 Surgically induced transient paraplegia 2.5.3.1 Neurophysiological basis for surgically induced transient paraplegia 2.6 Conclusion References 3 Monitoring somatosensory evoked potentials 3.1 Introduction 3.2 History 3.3 Methodology 3.3.1 Basic techniques 3.3.1.1 Electrodes 3.3.1.2 Stimulation 3.3.1.3 Recording 3.3.1.4 Potentials and sites 3.3.1.4.1 Peripheral controls 3.3.1.4.2 Cortical monitors 3.3.1.4.3 Other potentials 3.3.1.5 Averaging 3.3.2 Traditional methods 3.3.3 Optimal methods 3.3.3.1 Lower limbs 3.3.3.2 Upper limbs 3.3.3.3 Optional derivations 3.3.3.4 Fallback derivations 3.3.3.5 Benefits 3.4 Warning criteria 3.4.1 Traditional criteria pitfalls 3.4.2 Recommended adaptive criterion 3.5 Cortical somatosensory evoked potential mapping 3.5.1 Median nerve 3.5.2 Tibial and trigeminal nerves 3.6 Future directions 3.7 Conclusion References 4 Neurophysiology of the visual system: basics and intraoperative neurophysiology techniques 4.1 Introduction 4.2 Historical review 4.3 Neurophysiology of the visual pathway 4.4 Recording of intraoperative flash visual evoked potentials 4.4.1 Indication for intraoperative visual evoked potential monitoring 4.4.2 Anesthesia 4.4.3 Stimulation 4.4.4 Recording 4.4.5 Waveform acquisition 4.4.6 Intraoperative assessment of visual evoked potentials and warning criteria 4.5 Results 4.5.1 Case examples 4.6 Optic nerve action potentials and evoked potentials 4.7 Monitoring and mapping the posterior visual pathway 4.8 Conclusion References 5 Neurophysiology of the auditory system: basics and ION techniques 5.1 The auditory nerve 5.2 History of recordings of the auditory brainstem response 5.3 Generation of far-field-evoked potentials 5.4 Intraoperative neurophysiological monitoring of the auditory brainstem response 5.4.1 Techniques for recording the auditory brainstem response 5.4.2 Getting interpretable responses in the shortest possible time 5.4.3 Optimal stimulus rate and intensity 5.4.4 Reduction of electrical and magnetic interference 5.4.5 Optimal placement of the recording electrodes for auditory brainstem response for intraoperative monitoring 5.4.6 Filtering of the auditory brainstem response 5.4.7 Practical ways of recording auditory brainstem responses intraoperatively 5.5 Detection of signs of hearing loss from manipulations of the auditory nerve 5.6 Recording directly from the exposed auditory nerve 5.7 Recording of the response from the cochlear nucleus 5.8 What to report to the surgeon? 5.9 The neural generators of the auditory brainstem response 5.9.1 Generators of peak I and II of the auditory brainstem response 5.9.2 Contribution to the auditory brainstem response from nuclei 5.9.2.1 The cochlear nucleus 5.9.2.2 Superior olivary complex 5.9.2.3 Lateral lemniscus 5.9.2.4 Inferior colliculus 5.9.3 Lateralization of auditory-evoked potentials 5.9.4 The absence of contributions from some ascending auditory pathways 5.9.5 Summary of the neural generators of the auditory brainstem response 5.10 Use of auditory brainstem response in monitoring to detect changes in the function of the brainstem References 6 Intraoperative neurophysiological monitoring of the sacral nervous system 6.1 Introduction 6.2 Functional anatomy 6.2.1 Neural control of the lower urinary tract 6.2.2 Anorectum 6.2.3 Sexual organs 6.3 Clinical neurophysiological tests in diagnostics 6.4 Intraoperative clinical neurophysiology 6.4.1 Basic technical aspects of stimulation for intraoperative sacral monitoring 6.4.2 Basic technical aspects of recording for intraoperative sacral monitoring 6.4.3 Specific sacral neuromuscular system monitoring procedures 6.4.3.1 Pudendal dorsal root action potentials 6.4.3.2 Pudendal spinal somatosensory evoked responses 6.4.3.3 Pudendal cerebral somatosensory evoked potentials 6.4.3.4 Anal sphincter motor response monitoring 6.4.3.5 Bulbocavernosus reflex monitoring 6.5 Discussion and Conclusion References Further reading 7 Neurophysiology of language and cognitive mapping 7.1 Introduction 7.2 Language mapping 7.2.1 Current model of language organization 7.2.2 Language mapping workup 7.2.2.1 Preoperative workup 7.2.2.2 Neuropsychological evaluation 7.2.2.3 Language examination 7.2.2.4 Training to the awake phase 7.2.2.5 Intraoperative workup 7.2.2.6 Postoperative workup 7.2.3 Neurophysiological approach 7.2.4 Defining eloquent sites in language mapping 7.2.5 How to perform the mapping? 7.2.6 Besides standard language mapping 7.2.6.1 Reading and writing 7.2.6.2 Language mapping in multilingual patients 7.3 Advanced mapping: cognitive mapping 7.3.1 Brain mapping of visual system and visuospatial cognition 7.3.2 Cognitive control 7.4 Conclusion References 8 Effects of subthreshold stimuli on the excitability of axonal membrane 8.1 Introduction 8.2 Methodology 8.2.1 Test subjects 8.2.2 Stimulation 8.2.2.1 Median nerve 8.2.2.2 Facial nerve 8.2.3 Recording 8.2.3.1 Median nerve 8.2.3.2 Facial nerve 8.2.4 Testing protocol 8.3 Results 8.4 Discussion 8.5 Conclusion References Part II: Intraoperative neurophysiology: neurophysiologic perspective 9 Cortical and subcortical brain mapping 9.1 Introduction 9.2 Brain mapping and anesthesia 9.3 Recording and documentation 9.4 Physical background 9.5 Choice of stimulation paradigm 9.6 Choice of stimulation probe 9.7 Subcortical mapping and distance to the corticospinal tract 9.8 Continuous subcortical mapping 9.9 Possible pitfalls 9.10 Case illustrations 9.10.1 Case no 1, video 9.1 – Intraoperative DCS MEP monitoring, cortical mapping and continuous subcortical mapping in a c... 9.10.2 Case no 2, video 9.2 – Continuous subcortical mapping and intraoperative DCS MEP and SEP monitoring in a right insul... 9.11 Summary and conclusion Acknowledgment References 10 Corticobulbar motor evoked potentials in skull base surgery 10.1 Introduction 10.2 Methodology 10.2.1 Stimulation 10.2.2 Recording parameters 10.3 Anesthesia regime 10.4 Facial corticobulbar motor evoked potentials 10.4.1 Methodological improvement 10.4.1.1 Increase the number of monitored muscles 10.4.1.2 Localization of the best position for recording electrodes 10.4.1.3 Optimization of stimulation parameters through the surgical procedure 10.4.1.4 Double-stimulation technique 10.4.1.5 Hook wire electrodes for recording 10.4.1.6 Filtering 10.4.2 Facial corticobulbar motor evoked potentials interpretation and correlation with clinical outcome 10.4.3 Pitfalls in facial corticobulbar motor evoked potentials methodology 10.4.3.1 Blink versus facial corticobulbar motor evoked potentials 10.4.3.2 Confounding peripheral activation of the facial nerve during corticobulbar tract monitoring 10.5 Vagal corticobulbar motor evoked potentials 10.5.1 The origin of laryngeal response after transcranial electrical stimulus 10.5.2 Vagal corticobulbar motor evoked potentials recorded from vocalis muscles 10.5.3 Vagal corticobulbar motor evoked potentials recorded from cricothyroid muscle 10.6 Limitations of corticobulbar motor evoked potentials 10.7 Conclusion References 11 Brain stem mapping 11.1 Introduction 11.1.1 What is brain stem mapping? 11.1.2 Anatomical background for brain stem mapping 11.1.3 Corticobulbar tracts 11.2 Methodology of brain stem mapping 11.2.1 Anesthesia regimen 11.3 Results of brain stem mapping 11.4 Surgical implications of brain stem mapping 11.5 Clinical limitations of brain stem mapping 11.6 Representative case of brain stem mapping 11.7 Clinical application of brain stem mapping 11.8 Conclusion References 12 Neurophysiological identification of long sensory and motor tracts within the spinal cord 12.1 Introduction 12.2 Dorsal column mapping 12.2.1 Neurophysiological generators of somatosensory evoked potentials in the spinal cord 12.2.2 Measuring the amplitude gradient of spinal SEP via miniature multielectrode grid electrodes 12.2.3 Phase-reversal somatosensory evoked potentials over the scalp 12.2.4 Antidromic responses over peripheral nerves 12.3 Corticospinal tract mapping 12.3.1 D-wave collision technique 12.3.2 Direct stimulation of the spinal cord 12.3.2.1 What are we really stimulating? 12.3.3 Mapping the DC and CST with a double-train stimulation paradigm 12.4 Conclusion References 13 Electromyographic monitoring for pedicle screw placements 13.1 Introduction 13.2 Monitoring pedicle screw placements 13.2.1 Electromyographic techniques 13.2.1.1 Spontaneous or free-running electromyography 13.2.1.2 Triggered electromyography 13.2.2 Nerve root excitation 13.2.3 False-positive findings 13.2.4 False-negative findings 13.2.4.1 Degree of muscle relaxation 13.2.4.2 Current shunting 13.2.4.3 Physiologic factors 13.2.4.4 Technical factors 13.2.5 Efficacy of electromyographic monitoring 13.2.6 Minimally invasive applications 13.3 Conclusion References 14 Clinical and neurophysiologic features of the pure motor deficit syndrome caused by selective upper motor neuron lesion:... 14.1 Introduction 14.2 Underlying pathology of pure motor deficit 14.3 Diagnosis 14.3.1 Clinical and neurological examination 14.3.2 Use of neuroimaging techniques 14.3.3 Neurophysiological markers obtained peri- and intraoperatively 14.3.4 Postmortem pathology 14.4 Methodologies 14.5 Topography of the corticospinal tract and corticobulbar tract lesions producing pure motor deficit 14.5.1 Typical lesion within brain, brainstem, and spinal cord producing pure motor deficit 14.5.2 Cortical, subcortical, and capsular lesion producing pure motor deficit 14.5.3 Brainstem lesion producing pure motor deficit 14.5.4 Spinal cord lesion producing pure motor deficit 14.6 Prognosis 14.7 Conclusion References Further reading Part III: Neurophysiology of brainstem and spinal cord reflexes 15 Intraoperative monitoring of the vagus and laryngeal nerves with the laryngeal adductor reflex 15.1 Introduction 15.2 History 15.3 Methodology 15.3.1 Far-field muscle contamination 15.3.2 Impact on surgical strategy 15.4 Examples 15.4.1 Example 1 15.4.2 Example 2 15.5 Conclusion References 16 Bringing the masseter reflex into the operating room 16.1 Introduction 16.2 History 16.3 Methodology 16.4 Examples 16.5 Conclusion References 17 Blink reflex 17.1 Introduction 17.2 Methodology 17.2.1 Stimulation parameters 17.2.2 Recording parameters 17.3 Anesthetic considerations 17.4 Clinical assessment/results 17.5 Practical applications 17.5.1 Feasibility and practicality of monitoring 17.5.2 Interpretation of blink reflex 17.5.3 Combined interpretation of blink reflex and corticobulbar motor evoked potentials 17.5.4 Pitfall of interpretation of facial corticobulbar motor evoked potentials in relation to blink reflex: “upper facial... 17.6 Summary References 18 The posterior root-muscle reflex 18.1 Introduction 18.2 History 18.3 Anatomy of the posterior roots 18.4 Methodologies for evoking posterior root-muscle reflexes 18.4.1 Epidural spinal cord stimulation 18.4.2 Transcutaneous spinal cord stimulation 18.5 Physiology and electromyographic characteristics of posterior root-muscle reflexes 18.5.1 Characteristics of posterior root-muscle reflexes evoked by stimulation over the lumbar and upper sacral spinal cord 18.5.2 Posterior root-muscle reflexes and the H-reflex 18.5.3 Characteristics of evoked responses to stimulation over the cauda equina 18.5.4 Body-position dependence of the evoked responses 18.6 Examples of intraoperative monitoring applications 18.6.1 Intraoperative neurophysiological monitoring of epidural lead placement 18.6.2 Intraoperative monitoring of peripheral nerve function during complex hip surgeries 18.7 Conclusion References Part IV: Intraoperative Neurophysiology: Surgical Perspective 19 Functional approach to brain tumor surgery: awake setting 19.1 Introduction 19.2 Rationale of surgical treatment 19.3 The concept of functional neuro-oncology: resection according to functional boundaries 19.4 Preoperative workup 19.4.1 Patient interview 19.4.2 Neuropsychological evaluation and psycho-oncological interview 19.4.3 Imaging workup 19.4.3.1 Basic methods: magnetic resonance imaging standard evaluation 19.4.3.2 Advanced magnetic resonance imaging evaluation 19.5 Decision for surgery 19.6 Intraoperative setup 19.6.1 Intraoperative anesthesia 19.6.2 Intraoperative neurophysiology 19.6.2.1 Mapping techniques 19.6.2.2 Monitoring techniques 19.7 Surgical time 19.7.1 Cortical time 19.7.2 Subcortical time 19.8 How to manage intraoperative complications 19.9 Functional results of surgery 19.10 Conclusion References Further reading 20 Surgery of brain tumors asleep 20.1 Introduction 20.2 Cortical mapping 20.3 Monitoring 20.4 Subcortical mapping 20.5 Conclusion References 21 Surgery and intraoperative neurophysiological monitoring for aneurysm clipping 21.1 Introduction 21.2 Somatosensory-evoked potentials 21.3 Motor-evoked potentials 21.4 Early auditory-evoked potentials 21.5 Visual-evoked potentials 21.6 General remarks for safety considerations and anesthesia 21.6.1 Auditory-evoked potential and somatosensory-evoked potential 21.6.2 Motor-evoked potential 21.6.3 Visual-evoked potential 21.6.4 Anesthesia 21.7 Intraoperative Neuromonitoring (ION) and surgical workflow 21.8 Surgical aspects in cerebrovascular surgery 21.9 Vascular territories and recommended recordings 21.9.1 Anterior circulation aneurysms 21.9.2 Posterior circulation aneurysms and arteriovenous malformations 21.9.3 Perforating arteries 21.10 Temporary vessel occlusion 21.11 Permanent vessel occlusion 21.12 Special remarks on arteriovenous malformation surgery 21.13 Surgical reaction on ION alteration and duration of monitoring 21.14 Conclusion References 22 Surgery of brainstem lesions 22.1 Introduction 22.2 Patient selection and rationale for surgery 22.3 General principle of the surgical strategy 22.3.1 Midbrain 22.3.2 Pons 22.3.3 Medulla and cervicomedullary junction 22.4 Postoperative care 22.5 Neurophysiological monitoring 22.6 Conclusion References 23 Continuous dynamic mapping during surgery of large vestibular schwannoma Abbreviations 23.1 Introduction 23.2 Neurophysiological setup 23.2.1 Continuous dynamic mapping suction probe 23.2.2 Software adaptations 23.2.3 Surgical technique using continuous monopolar mapping 23.3 Anatomy in the cerebellopontine angle 23.4 What current neurophysiological methods provide? 23.5 Continuous dynamic mapping as an adjunct 23.6 What might be the best strategy to protect the facial nerve? 23.6.1 Illustrative case example 23.7 Limitations 23.8 Further applications in skull base surgery 23.9 Summary References 24 Surgery of the face 24.1 Introduction 24.2 Anatomy, physiology, and surgery of the facial nerve 24.3 Methodology 24.3.1 Instruments and electrodes 24.3.2 Preoperative mapping 24.4 Continuous compound muscle action potential monitoring 24.5 Intraoperative mapping 24.6 Warning criteria and correlation with outcome 24.7 Our experience on facial nerve monitoring and comparison with other studies 24.8 Conclusion References 25 Carotid endarterectomy 25.1 Introduction 25.1.1 Carotid endarterectomy and shunt application 25.1.2 Cerebral blood supply and clamping-related ischemia 25.1.3 Monitoring neuronal function to detect critical cerebral perfusion 25.2 Intraoperative neurophysiologic monitoring for carotid endarterectomy 25.2.1 Electroencephalogram 25.2.2 Somatosensory evoked potentials 25.2.3 Transcranial electrical motor evoked potentials 25.3 Conclusion References 26 Surgery for intramedullary spinal cord tumors and syringomyelia 26.1 Introduction 26.2 Neurophysiology 26.3 Anesthesia 26.4 Clinical assessment and correlation 26.5 Feasibility and practicality of monitoring 26.5.1 Interpretation of D-wave 26.5.2 Interpretation of muscle motor-evoked potential 26.5.3 Combined muscle motor-evoked potential and D-wave monitoring 26.5.4 Influence of D-wave and MEP monitoring on extent of resection and neurologic outcome 26.6 Observations on the behavior of MEPs during spinal cord tumor surgery and their practical consequences 26.6.1 Muscle motor-evoked potential build-up effect 26.6.2 Behavior of motor-evoked potential disappearance and how to react to them 26.7 Mapping of individual pathways in the spinal cord 26.8 Illustrative cases 26.8.1 Case 1 26.8.2 Case 2 26.8.3 Case 3 26.8.4 Case 4 26.8.5 Case 5 26.8.6 Case 6 26.9 Conclusion References 27 Intraoperative neurophysiological monitoring in tethered cord surgery 27.1 Introduction 27.2 Tethered cord etiopathogenesis 27.3 Anesthesia 27.4 Intraoperative neurophysiology techniques during tethered cord surgery 27.5 Monitoring techniques 27.5.1 Somatosensory evoked potentials 27.5.2 Motor-evoked potentials 27.5.3 Free-running (spontaneous) electromyography 27.5.4 Bulbocavernosus reflex 27.6 Mapping techniques 27.6.1 Triggered EMG: direct nerve stimulation 27.7 Surgical use of intraoperative neurophysiology in lipomas exertion 27.8 Conclusion References 28 Intraoperative neuromonitoring and complex spine surgery 28.1 Introduction 28.2 Complex spine instrumentation and deformity surgery 28.3 Spinal instability 28.4 Monitoring loss protocol 28.4.1 Case example 1 28.4.2 Case example 2 28.5 Conclusion References 29 Neurophysiological monitoring during endovascular procedures on the spine and the spinal cord* 29.1 Spinal cord vascularization and ischemia 29.1.1 Vascular anatomy of the human spinal cord 29.1.2 Primers on pathophysiology of spinal cord ischemia secondary to spinal cord vascular malformations 29.2 Neurophysiological monitoring 29.2.1 Evoked potentials in spinal cord ischemia: experimental and clinical studies 29.2.2 Clinical application of neurophysiological monitoring for endovascular treatment of spine and spinal cord vascular l... 29.2.2.1 Patient setup and anesthesiological management 29.2.2.2 Endovascular procedure and provocative tests 29.3 Endovascular treatment of vascular malformations and tumors of the spine and the spinal cord 29.3.1 Indications 29.3.2 Angiographic vascular anatomy of the spine and spinal cord 29.3.3 Spinal angiography 29.3.4 Angiographic evaluation, endovascular treatment, and clinical aspect of neurophysiological monitoring 29.3.4.1 Tumors 29.3.4.2 Vascular malformations 29.3.4.2.1 Dural/extradural lesions 29.3.4.2.2 Intradural vascular malformations 29.4 Conclusion References 30 Intraoperative neurophysiology of the peripheral nervous system 30.1 Background 30.2 Nerve regeneration 30.3 Equipment for intraoperative recordings 30.4 Electrodes for intraoperative recording and stimulation 30.5 Anesthetic considerations 30.6 Recording compound nerve action potentials intraoperatively 30.7 Criteria for appraising a compound nerve action potentials 30.8 Operative results 30.9 Troubleshooting 30.10 Conclusion References 31 An intraoperative neurophysiological monitoring method for testing functional integrity of the low extremity peripheral ... 31.1 Introduction 31.2 Material and methods 31.2.1 Subjects 31.2.2 Anesthesia 31.2.3 Multimodal neuromonitoring methodologies 31.2.3.1 Somatosensory-evoked potential 31.2.3.2 Motor-evoked potential 31.2.3.3 Free-running electromyography 31.2.3.4 Anterior root muscle response and posterior root muscle reflex 31.2.3.5 Electroencephalography 31.2.4 Recordings 31.2.5 Specific attention for placement of nerve-stimulating and muscle recording electrodes 31.3 Results 31.4 Discussion 31.5 Conclusion References Further reading Part V: Functional neurosurgery 32 Surgery for epilepsy 32.1 Introduction 32.2 Preoperative evaluation 32.3 Surgical options 32.3.1 Temporal lobectomy (with or without removal of amygdala, hippocampus, and parahippocampal tissue) 32.3.2 Other extratemporal resection 32.3.3 Callosotomy 32.3.4 Multiple subpial transections 32.4 Electrocorticography 32.4.1 History of cortical recordings 32.4.2 Current status of classical electrocorticography during epilepsy surgery 32.4.3 Newer intraoperative neurophysiologic techniques during epilepsy surgery 32.4.4 Clinical interpretation of electrocorticography 32.5 Anesthetic considerations 32.6 Electrodes References 33 Intraoperative neurophysiological monitoring during microvascular decompression of cranial nerves 33.1 History 33.2 Pathologies 33.2.1 Trigeminal neuralgia 33.2.2 Hemifacial spasm 33.2.3 Glossopharyngeal neuralgia 33.2.4 Others syndromes related to neurovascular compression (NVC) 33.3 Radiologic considerations 33.4 Pathogenic mechanisms underlying vascular compression 33.5 Surgical treatment 33.5.1 Microvascular decompression surgical procedure 33.5.1.1 Patient positioning and preparation 33.5.1.2 Surgical technique 33.6 Monitoring modalities for microvascular decompression 33.6.1 Achieving the therapeutic goal 33.6.1.1 Abnormal muscle response: (lateral spread) 33.6.1.2 Other abnormal responses 33.6.2 Avoiding complications 33.6.2.1 Brainstem auditory response 33.6.2.2 Auditory nerve compound action potentials 33.6.2.3 Free-running and triggered electromyography 33.6.2.4 Somatosensory-evoked potentials and transcranial motor-evoked potentials 33.7 Microvascular decompression and intraoperative neurophysiology: practical implementation and pearls 33.8 Conclusion References Further reading 34 Neurophysiological monitoring during neurosurgery for movement disorders 34.1 Introduction 34.2 History and theory 34.2.1 Historical notes 34.2.1.1 Surgery for movement disorders 34.2.2 Neurophysiology and movement disorder surgery 34.2.3 Theoretical basis for surgery in the basal ganglia 34.2.4 Modern movement disorder surgery: general overview 34.2.4.1 Anatomical targeting techniques 34.2.4.2 Physiological targeting: recording techniques 34.2.4.2.1 Impedance techniques 34.2.4.2.2 Macroelectrode recording 34.2.4.2.3 Semimicroelectrode technique 34.2.4.2.4 Microelectrode techniques 34.2.4.2.5 Local field potentials 34.3 Operating room environment and basic equipment 34.3.1 Operating room 34.3.1.1 Electrical noise (recording only) 34.3.1.2 Electrical noise (internal system influences) 34.3.2 Recording electrodes 34.3.3 Amplification 34.3.4 Stimulation 34.4 Technique for movement disorder surgery 34.4.1 General stereotactic technique 34.4.1.1 GPi procedures 34.4.1.2 Ventral intermediate procedures 34.4.1.3 Subthalamic nucleus procedures 34.5 Conclusion References 35 Neurosurgical lesioning-procedures for spasticity and focal dystonia 35.1 Introduction 35.2 Lesioning procedures 35.2.1 Peripheral neurotomies 35.2.2 Dorsal rhizotomies 35.2.3 Surgery in the dorsal root entry zone 35.2.3.1 Microsurgical DREZotomy at the cervical level 35.2.3.2 Microsurgical DREZotomy at the lumbosacral level 35.2.4 Longitudinal myelotomies 35.3 Intraoperative neurophysiology as an aid to surgery 35.4 Indications for surgery 35.4.1 Decision-making in adults 35.4.2 Decision-making in children 35.5 Conclusion References 36 Deep brain stimulation for treatment patients in vegetative state and minimally conscious state 36.1 Introduction 36.2 A short history of deep brain stimulation for vegetative state and minimally conscious state 36.3 Patients and methods 36.4 Neurological evaluation 36.5 Selection criteria for deep brain stimulation unit implantation 36.6 Surgical targeting and procedure 36.7 Results 36.8 Discussion 36.9 Conclusion References 37 Neuromonitoring for spinal cord stimulation placement under general anesthesia 37.1 Introduction 37.2 Methods 37.2.1 Compound muscle action potential system–based technique 37.2.1.1 Recording 37.2.1.2 Stimulation 37.2.2 Collision-based technique 37.2.2.1 Stimulation 37.2.2.2 Recording 37.2.2.3 Testing 37.2.3 Stimulation intraoperative neurophysiology placement techniques 37.3 Reliability of the techniques 37.4 Conclusion References 38 Neurosurgical lesioning procedures in spinal cord and dorsal root entry zone for pain 38.1 Introduction 38.2 The surgical lesioning procedures directed to the spinal cord 38.3 The procedures for dorsal root entry zone–lesioning 38.3.1 The microsurgical DREZotomy 38.3.1.1 Operative procedure at the cervical level and for brachial plexus avulsion 38.3.1.2 Operative procedure at the lumbosacral level and for conus medullaris injury 38.3.1.3 Microsurgical DREZotomy for pain resulting from peripheral nerve pathologies or as herpes zoster sequela 38.3.1.4 Microsurgical DREZotomy pain in malignancies 38.3.2 The dorsal root entry zone procedures with other lesion makers 38.3.2.1 Radiofrequency thermocoagulation 38.3.2.2 Dorsal root entry zone–lesioning with the laser beam 38.3.2.3 Ultrasonic dorsal root entry zone–lesioning 38.4 Intraoperative neurophysiology 38.4.1 Neurophysiology as an aid to surgery 38.4.2 Research methods 38.4.2.1 Microelectrophysiology 38.4.2.2 Microdialysis 38.5 Conclusion References 39 Selective dorsal rhizotomy 39.1 History 39.2 Patient selection 39.3 Surgery 39.4 Physiotherapy 39.5 Follow-up 39.6 Results 39.7 Complications 39.8 Conclusion References Further reading Part VI: Other Important Aspects of Intraoperative Neurophysiology 40 Principles of anesthesia 40.1 Anesthesia: safety, comfort, and facilitation of the procedure 40.2 Medical and physiological management 40.3 Patient positioning 40.4 Pharmacologic management 40.4.1 Initial choice of anesthetic agents 40.4.2 Choice of agents: behavioral goals 40.4.2.1 Amnesia 40.4.2.2 Unconsciousness 40.4.2.3 Antinociception 40.4.2.4 Immobility 40.5 Conclusion: summary of anesthesia choice and management References 41 Safety 41.1 Introduction 41.2 Electrical safety 41.2.1 Electric shock 41.2.1.1 Risk of cardiac failure 41.2.1.2 Leakage currents 41.2.1.3 Means of protection against electric shock 41.2.1.3.1 Single fault safe 41.2.1.3.2 Leakage current limits 41.2.1.3.3 Periodic inspection 41.2.1.3.4 Power cords and lead connectors 41.2.2 Hazardous output 41.2.2.1 Parameters of electrical stimulation 41.2.2.2 Strength–duration properties 41.2.2.3 Protection against thermal injury 41.2.2.4 Protection against excitotoxicity 41.2.2.5 Protection against electrochemical toxicity 41.2.3 Electrode burns 41.2.3.1 Protection against stray electrosurgery current burns 41.2.3.2 Protection against intraoperative magnetic resonance imaging burns 41.2.3.3 Protection against direct current burns 41.2.4 Fire 41.3 Procedure-specific safety 41.3.1 Invasive techniques 41.3.2 Direct cortical stimulation 41.3.2.1 Traditional 50–60Hz cortical stimulation 41.3.2.2 Direct cortical stimulation for eliciting motor evoked potentials 41.3.3 Direct subcortical stimulation 41.3.4 Direct brainstem stimulation 41.3.5 Direct spinal cord stimulation 41.3.6 Transcranial electric stimulation for eliciting motor-evoked potentials 41.3.6.1 Bite injuries 41.3.6.2 Seizures 41.3.6.3 Movement 41.3.6.4 Other adverse effects 41.3.6.5 Relative contraindications 41.3.7 Somatosensory evoked potentials 41.3.8 Brainstem auditory and visual evoked potentials 41.3.9 Electromyography 41.4 Infection control 41.4.1 Standard precautions 41.4.2 Needlestick 41.4.3 Additional precautions 41.5 Essential performance 41.5.1 Monitoring device essential performance 41.5.2 Monitoring practice essential performance 41.5.2.1 Excessively slow feedback 41.5.2.2 Incorrect interpretation 41.5.2.3 Means of protection 41.6 Conclusion References 42 Costs and benefits of intraoperative neurophysiological monitoring in spinal surgeries 42.1 Introduction 42.2 General considerations for cost-effectiveness analysis 42.3 Cost-effectiveness analysis in spine ION 42.4 Cost and outcomes research using “big data” 42.5 Future directions in cost and outcomes research in ION for spine surgeries References 43 Evidence-based medicine and intraoperative neurophysiology 43.1 Introduction 43.2 Principles of evidence-based medicine 43.2.1 All evidence is not created equal 43.2.2 The totality of evidence is considered 43.2.3 Patient values and quality of evidence determine the value of a treatment or practice 43.3 Intraoperative neurophysiological monitoring and outcomes: back to basics for causal links 43.3.1 Intraoperative neurophysiological monitoring has an indirect effect on outcomes 43.3.2 Surgeons use intraoperative neurophysiological monitoring as surrogate endpoints 43.3.3 Estimates of intraoperative neurophysiological monitoring treatment effects from comparative observational studies m... 43.4 Evidence for improved outcomes with intraoperative neurophysiological monitoring 43.5 How accurate are my SEPs and MEPs? 43.5.1 The alert criterion and contingency results 43.5.2 Positive prediction and likelihood 43.5.3 Reversible signal change: approaches toward proper categorization 43.5.4 Illustrative case series 43.5.5 Diagnostic test accuracy and evidence-based medicine 43.5.6 Diagnostic test accuracy and clinical efficacy 43.6 Moving forward with the evidence base of intraoperative neurophysiological monitoring 43.7 Glossary of contingency terms for intraoperative neurophysiological monitoring tests References 44 The intraoperative neurophysiological monitoring team 44.1 Introduction: airliners and operating rooms 44.2 ION teamwork and models of care 44.3 Injury prediction versus injury prevention 44.4 Systematic review of intraoperative teamwork 44.5 Medical error avoidance 44.5.1 Bias among peers 44.5.2 Bias mitigation 44.5.3 The ION interventional cascade and team-based communication cycle 44.6 Optimizing current models of ION care 44.6.1 Ideal model 44.6.2 Challenged models 44.6.3 Other (possibly acceptable) options 44.6.3.1 Remote telepresence 44.6.3.2 Advanced technologist training/credentials 44.6.3.3 Surgeon supervised ION 44.6.3.4 Semiautomated ION devices 44.7 Conclusion References Conclusion Index Back Cover