Incidence of Postoperative Cerebral Aneurysm Clip Slippage: Review of a Consecutive Case Series of 115 Clipped Aneurysms.

OBJECTIVE: Although delayed postoperative clip slippage has been reported in previous case reports and case series, its true incidence with high rate of follow-up imaging has not been reported. We attempted to determine the incidence of clip slippage in a cohort of consecutive aneurysm clippings. METHODS: We performed a retrospective review of a prospectively maintained database of 115 consecutive saccular aneurysm clippings at a single institution. Postoperative imaging was reviewed for clip slippage within 24 hours and at 3-12 months. Eighty-six aneurysms (75.8%) were exclusively clipped with Sugitaclip (Mizuho Medical, Tokyo, Japan) Titanium II clips, 16 aneurysms were exclusively clipped with Yasargil (Aesculap, Center Valley, PA) titanium clips (13.9%), 5 aneurysms were only clipped with Sugita aneurysm clips (4.3%), and 3 aneurysms were only clipped with Peter Lazic (Peter Lazic Microsurgical Innovations, Tuttlingen, Germany) clips (2.6%). RESULTS: In this cohort, 94.7% of clipped aneurysms had follow-up imaging within 24 hours, and 51.3% had delayed follow-up imaging within 3-12 months. We identified 3 cases of clip slippage in 115 consecutive aneurysm clippings, resulting in an incidence of 2.6%. The average cumulative closing force of clips per aneurysm across the study was 2.32 N, and the median number of clips placed was 1. Two of the 3 cases of clip slippage had a closing force <2.32 N and only placement of a single clip. CONCLUSIONS: Because our series showed a 2.6% incidence of clip slippage, clipped aneurysms should be monitored with early and delayed vascular follow-up imaging. Lower cumulative clip closing force, single clip placement, and oversized clip blade length may be risk factors for postoperative aneurysmal clip slippage.

Continuous Electroencephalographic Training for Neuroscience Intensive Care Unit Nurses: A Feasibility Study.

BACKGROUND: Use of continuous electroencephalographic (cEEG) monitoring has more than doubled at our institution for the last 4 years. Although intensive care unit cEEG is reviewed remotely by board-certified epileptologists every 4 to 6 hours, there are inherent delays between occurrence, recognition, and treatment of epileptiform activity. Neuroscience intensive care unit (NSICU) nurses are uniquely positioned to monitor cEEG in real time yet do not receive formal training. The purpose of this study was to evaluate the effectiveness of an education program to teach nurses to monitor cEEG, identify a burst suppression pattern, and measure the duration of suppression. METHODS: We performed a retrospective analysis of pretest and posttest data. All NSICU nurses (40) were invited to complete the pretest (PT-0), with 25 participating. Learning style/preference, demographics, comfort with cEEG, and knowledge of EEG fundamentals were assessed. A convenience cohort of NSICU nurses (13) were selected to undergo EEG training. Posttests evaluating EEG fundamental knowledge were completed immediately after training (PT-1), at 3 months (PT-3), and at 6 months (PT-6). The cohort also completed a burst suppression module after the training, which assessed ability to quantify the duration of suppression. RESULTS: Mean cohort test scores significantly improved after the training (P < .001). All nurses showed improvement in test scores, and 76.9% passed PT-1 (a score of 80% or higher). Reported mean comfort level with EEG also significantly improved after the training (P = .001). There was no significant difference between mean cohort scores between PT-1, PT-3, and PT-6 (all 88.6%; P = 1.000). Mean cohort score from the bust suppression module was 73%, with test scores ranging from 31% to 93%. CONCLUSIONS: NSICU nurses can be taught fundamentals of cEEG, to identify a burst suppression pattern, and to quantify the duration of suppression. Further research is needed to determine whether this knowledge can be translated into clinical competency and affect patient care.

Activation to Arrival: Transition and Handoff from Emergency Medical Services to Emergency Departments.

The burden of neurologic disease in the United States continues to increase due to a growing older population, increased life expectancy, and improved mortality after cancer and cardiac disease. Emergency medical services (EMS) providers are responding to more patients with stroke, traumatic neurologic injury, neuromuscular weakness, seizure, and spontaneous cardiac arrest. Efficient prehospital care and triage to facilities with specialized services improve outcomes. Effective handoff from EMS to an emergency department ensures continuity of care and patient safety. Although advancements in prehospital cardiopulmonary resuscitation have increased rates of return to spontaneous circulation, a large proportion of patients sustain neurologic injury.