Pediatric intracranial arteriovenous malformations: Examining rehabilitation outcomes.

PURPOSE: Arteriovenous malformation (AVM) rupture in children can cause debilitating neurological injury. Rehabilitation is key to recovery, though literature details little regarding rehabilitation outcomes. We examined a single-center experience with pediatric AVMs as related to acute inpatient rehabilitation outcomes. METHODS: At our institution, a retrospective chart review was completed examining all cases of intracranial AVMs in patients age 18 and younger who completed our acute inpatient rehabilitation program between 2012-2018. Patient characteristics, clinical data, treatment modality, and functional outcomes were reviewed. RESULTS: 14 patients with AVMs underwent acute inpatient rehabilitation; nine (64.3%) treated surgically at our institution, two (14.3%) non-surgically at our institution, and three (21.4%) surgically at an outside facility prior to transitioning care at our institution. Eight (57.1%) were male, seven (50.0%) Caucasian, and seven (50.0%) Hispanic. Seven (50.0%) presented with AVM rupture; six (42.9%) were found incidentally on imaging. Clinical courses, treatment outcomes, and post-treatment complications varied. Several patients underwent repeat treatment or additional procedures. Neurological deficits identified included hemiparesis, dystonia, spasticity, epilepsy, hydrocephalus, and ataxia. Inpatient rehabilitation unit length of stay was on average 21 days (SD 9.02, range 9-41). Functional Independence Measure for Children (WeeFIM®) scores, including self-care, mobility, and cognition, demonstrated improvement upon discharge. The mean total change was 36.7 points in those treated surgically, 16.5 in those treated non-surgically, and 25.7 in those treated surgically at another facility. CONCLUSION: We found that all pediatric patients with intracranial AVMs, across all treatment modalities, demonstrated improved outcomes across all functional domains after an acute inpatient rehabilitation program.

Indirect revascularization with the dural inversion technique for pediatric moyamoya disease: 20-year experience.

OBJECTIVENumerous surgical procedures facilitate revascularization of the ischemic brain in patients with moyamoya disease. Dural inversion is a technique in which flaps of dura mater centered around the middle meningeal artery are inverted, encouraging the formation of a rich collateral blood supply. This procedure has been used in combination with encephaloduroarteriosynangiosis for more than 20 years at the authors' institution for the treatment of pediatric moyamoya disease. The objective of this study was to describe the clinical and radiographic outcomes for a cohort of consecutive pediatric moyamoya patients undergoing dural inversion.METHODSClinical and radiographic data on patients who had undergone dural inversion in the period from 1997 to 2016 were reviewed. Univariate and multivariate logistic regression and Kaplan-Meier analyses were performed to assess the risk of postoperative stroke, functional outcome, and the angiographic degree of revascularization.RESULTSDural inversion was performed on 169 hemispheres in 102 patients. Median follow-up was 4.3 years. Six patients (3.6% of hemispheres) suffered postoperative ischemic or hemorrhagic stroke. Overall mortality was 1.0%. Good postoperative neurological status (modified Rankin Scale [mRS] score ≤ 2) was observed in 90 patients (88%); preoperative and postoperative mRS scores showed significant improvement (p < 0.001). Eighty-six percent of hemispheres had Matsushima grade A or B revascularization. Younger age was associated with postoperative stroke and poor functional outcome. Patients with secondary moyamoya syndrome had a significantly worse radiographic outcome. The cumulative 5-year Kaplan-Meier risk for stroke was 6.4%.CONCLUSIONSDural inversion is a useful technique of cerebral revascularization in pediatric moyamoya disease. A 20-year experience demonstrates the safety and efficacy of this technique with a relatively low rate of postoperative stroke, good functional outcomes, and favorable angiographic results.

Effects of extracellular calcium and surgical techniques on restoration of axonal continuity by polyethylene glycol fusion following complete cut or crush severance of rat sciatic nerves.

Complete crush or cut severance of sciatic nerve axons in rats and other mammals produces immediate loss of axonal continuity. Loss of locomotor functions subserved by those axons is restored only after months, if ever, by outgrowths regenerating at ∼1 mm/day from the proximal stumps of severed axonal segments. The distal stump of a severed axon typically begins to degenerate in 1-3 days. We recently developed a polyethylene glycol (PEG) fusion technology, consisting of sequential exposure of severed axonal ends to hypotonic Ca(2+) -free saline, methylene blue, PEG in distilled water, and finally Ca(2+) -containing isotonic saline. This study examines factors that affect the PEG fusion restoration of axonal continuity within minutes, as measured by conduction of action potentials and diffusion of an intracellular fluorescent dye across the lesion site of rat sciatic nerves completely cut or crush severed in the midthigh. Also examined are factors that affect the longer-term PEG fusion restoration of lost behavioral functions within days to weeks, as measured by the sciatic functional index. We report that exposure of cut-severed axonal ends to Ca(2+) -containing saline prior to PEG fusion and stretch/tension of proximal or distal axonal segments of cut-severed axons decrease PEG fusion success. Conversely, trimming cut-severed ends in Ca(2+) -free saline just prior to PEG fusion increases PEG fusion success. PEG fusion prevents or retards the Wallerian degeneration of cut-severed axons, as assessed by measures of axon diameter and G ratio. PEG fusion may produce a paradigm shift in the treatment of peripheral nerve injuries. © 2016 Wiley Periodicals, Inc.