Articles: neuronavigation.
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Precise intraoperative surgical localization of small distal aneurysms, arteriovenous malformations (AVMs), and cranial base dural arteriovenous fistulae may be challenging. Current neuronavigational techniques are based on imaging techniques with limited sensitivity to detect vascular lesions that are small. We introduce the technique of intraoperative computed tomography angiography (iCTA) with an intra-arterial injection for surgical navigation. ⋯ AVM, arteriovenous malformationCTA, computed tomography angiographyDAVF, dural arteriovenous fistulaDSA, digital subtraction angiographyiCTA, intraoperative computed tomography angiographyMCA, middle cerebral arteryMSCT, multislice computed tomographyMRA, magnetic resonance angiography.
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Increased frameless stereotactic accuracy with high-field intraoperative magnetic resonance imaging.
Frameless stereotaxy commonly registers preoperative magnetic resonance imaging (MRI) to patients by using surface scalp anatomy or adhesive fiducial scalp markers. Patients' scalps may shift slightly between preoperative imaging and final surgical positioning with pinion placement, introducing error. This might be reduced when frameless stereotaxy is performed in a high-field intraoperative MRI (iMRI), as patients are positioned before imaging. This could potentially improve accuracy. ⋯ Frameless stereotactic accuracy is increased by using high-field iMRI compared with standard preoperative imaging.
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Precise lesion localization is necessary for neurosurgical procedures not only during the operative approach, but also during the preoperative planning phase. ⋯ The proposed method of 3-D brain surface visualization is fast, clinically reliable for preoperative anatomic lesion localization and patient-specific planning, and, together with navigation, improves intraoperative orientation in brain tumor surgery and is relatively independent of brain shift.
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Letter Case Reports
BrainLAB interference with pulse oximetry during stereotactic brain biopsy.
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J Neurosurg Pediatr · Oct 2012
Case ReportsElectromagnetic-guided neuronavigation for safe placement of intraventricular catheters in pediatric neurosurgery.
Ventricular catheter shunt malfunction is the most common reason for shunt revision. Optimal ventricular catheter placement can be exceedingly difficult in patients with small ventricles or abnormal ventricular anatomy. Particularly in children and in premature infants with small head size, satisfactory positioning of the ventricular catheter can be a challenge. Navigation with electromagnetic tracking technology is an attractive and innovative therapeutic option. In this study, the authors demonstrate the advantages of using this technology for shunt placement in children. ⋯ The electromagnetic-guided neuronavigation system enables safe and optimal catheter placement, especially in children and premature infants, alleviating the need for repeated cannulation attempts for ventricular puncture. In contrast to stereotactic techniques and conventional neuronavigation, there is no need for sharp head fixation using a Mayfield clamp. This technique may present the possibility of reducing proximal shunt failure rates and costs for hydrocephalus treatment in this age cohort.