Intracranial hemorrhage detected through a craniotomy site with point of care ultrasound.

A 60-year-old male presented to the emergency department with acute change in mental status while recovering from a recent hemicraniectomy. During evaluation by the emergency physician, a point-of-care ultrasound (POCUS) was performed using the patient's existing craniectomy site as a sonographic window. Multiple areas of intracranial hemorrhage were visualized on POCUS and head computed tomography scan ultimately requiring urgent neurosurgical intervention. Our case report demonstrates an innovative application of POCUS in the emergency department- setting that has potential to expedite diagnosis and management of life-threatening neurosurgical etiologies, such as hemorrhage and midline shift, in a unique patient population.

Does acute kidney injury affect survival in adults with acute respiratory distress syndrome requiring extracorporeal membrane oxygenation?

INTRODUCTION: Patients who develop severe acute respiratory distress syndrome (ARDS) despite full medical management may require veno-venous extracorporeal membrane oxygenation (VV ECMO) to support respiratory function. Survival outcomes remain unclear in those who develop acute kidney injury (AKI) requiring continuous renal replacement therapy (CRRT) during VV ECMO for isolated severe respiratory failure in adult populations. METHODS: A retrospective chart review (2010-2016) of patients who underwent VV ECMO for ARDS was conducted with university institutional review board (IRB) approval. Patients supported by veno-arterial ECMO were excluded. AKI was defined by acute renal failure receiving CRRT and the outcomes of patients on VV ECMO were compared between the AKI and non-AKI groups. RESULTS: We identified 54 ARDS patients supported by VV ECMO (mean ECMO days 12 ± 6.7) with 16 (30%) in the AKI group and 38 (70%) in the non-AKI group. No patient had previous renal failure and the serum creatinine was not significantly different between the two groups at the time of ECMO initiation. The AKI group showed a greater incidence of complications during ECMO, including liver failure (38% vs. 5%, p=0.002) and hemorrhage (94% vs. 45%, p=0.0008). ECMO survival of the AKI group (56% [9/16]) was inferior to the non-AKI group (87% [33/38], p=0.014). CONCLUSIONS: Our study demonstrated that VV ECMO successfully manages patients with severe isolated lung injury. However, once patients develop AKI during VV ECMO, they are likely to further develop multi-organ dysfunction, including hepatic and hematological complications, leading to inferior survival.

An analysis of surgical and nonsurgical operating room times in high-volume shoulder arthroplasty.

BACKGROUND: A significant portion of operating room time in shoulder arthroplasty is devoted to nonsurgical tasks. To maximize efficiency and to increase access to care, it is important to accurately quantify surgical and nonsurgical time for shoulder arthroplasty. This study aimed to evaluate surgical vs. nonsurgical time and to assess the viability of using a 1-surgeon, 2-operating room model. METHODS: An institutional database was used to identify all primary and revision shoulder arthroplasty cases from February 2011 through December 2013. Time intervals were analyzed, including anesthesia and positioning time, surgical time, conclusion time, and turnover time. RESULTS: We identified 1062 shoulder arthroplasties. The average anesthesia and positioning time was 48.2 ± 11.7 minutes, surgical time was 122.7 ± 36.4 minutes, and conclusion time was 10.5 ± 7.0 minutes. Average turnover time at our institution was 40 minutes. An average of 58.8 ± 13.8 minutes (33.2%) of the patient's time in the operating room was not surgical. A 1-room surgical model, with each case following the next, would allow 3 arthroplasties to be performed in a 10-hour surgical day. A 2-room model would allow 4 cases to be performed in a 9-hour surgical day or 5 in an 11-hour day. In this 2-room model, there would be no time in which the surgeon is absent for any surgical portion of the case. CONCLUSION: For a high-volume shoulder arthroplasty practice, a 2-room model leads to greater efficiency and patient access to care without sacrificing the surgeon's presence during surgical portions of the case.