RESUMO
BACKGROUND: Cerebral vasospasm is commonly associated with adult aneurysmal subarachnoid hemorrhage but can develop in children. The standard vasospasm treatment includes induced hypertension, avoidance of hypovolemia, systemic use of the calcium channel blocker (CCB) nimodipine, and cerebral angiography for intraarterial therapy. Emerging treatments in adults, such as intraventricular CCB administration, have not been investigated in children. This study demonstrates the successful use of an intraventricular CCB in a pediatric patient with refractory vasospasm secondary to meningitis. OBSERVATIONS: A 12-year-old female presented with Streptococcus pneumoniae meningitis and ventriculitis with refractory symptomatic cerebral vasospasm. She received a 5-day course of intrathecal nicardipine through an existing external ventricular drain. Her clinical status, transcranial Doppler studies, and radiography improved. Treatment was well tolerated. LESSONS: Pediatric vasospasm is uncommon and potentially devastating. The management of vasospasm in adults occurs frequently. Principles of this management are adapted to pediatric care given the rarity of vasospasm in children. The use of intraventricular nicardipine has been reported in the care of adults with level 3 evidence. It has not been adequately reported in children with refractory vasospasm. Here, the first use of intraventricular nicardipine in treating pediatric cerebral vasospasm in the setting of meningitis is described and highlighted.
RESUMO
BACKGROUND: Implantable devices are increasingly more common for management of movement disorders, pain, and epilepsy. These devices are often complex and constructed of nonbiodegradable or hazardous materials. Therefore, proper postmortem handling of these devices is exceedingly important. Unfortunately, there is no consolidated resource available for postmortem neuromodulation device protocols. Thus, we surveyed and catalogued the protocols for implantable devices to summarize proper postmortem device protocols for implantable neurosurgical devices currently on the market. METHODS: We performed a cross-sectional study of companies producing commonly implanted neurosurgical devices. Using information from company websites, user manuals, and catalogs we categorized devices into 3 groups: A (formal recommendation for explantation), B (recommendation for explantation without formal company protocol), and C (explantation is not necessary). We then compiled the data into a stoplight diagram, providing a clear postmortem disposal algorithm for each device category. RESULTS: Twelve companies were queried regarding 46 devices. Postmortem protocols were available for 50% (23/46) of devices; the remaining devices did not have formal recommendations. Overall, 50% of devices were classified as category A "red light" on the stoplight diagram based on recommendations, 10.9% as category B "yellow light," and the remaining 39.1% were classified as category C "green light" indicating they are safe to bury or cremate. CONCLUSIONS: Evolution in therapies and growth in functional neurosurgery has expanded the range of implantable neurosurgical devices. We provide an educational document summarizing their postmortem protocols. This resource aims to aid health-care providers and encourage proper disposal practices during burial or cremation.