End-Tidal Control Versus Manual Control of Inhalational Anesthesia Delivery: A Randomized Controlled Noninferiority Trial.

BACKGROUND: Precise anesthesia delivery helps ensure amnesia, analgesia, and immobility. Conventionally, the end-tidal anesthetic concentration is maintained through manual adjustment of the fresh gas flow and anesthetic vaporizer output. Some anesthesia delivery systems can deliver and maintain clinician-selected end-tidal anesthetic agent (EtAA) concentration using a modified closed-loop system. We evaluated the performance of an End-tidal Control (EtC) system on the Aisys CS2 anesthesia machine (GE HealthCare). We hypothesized EtC anesthetic delivery would be noninferior to manually controlled anesthetic delivery. METHODS: The Multi-site Anesthesia randomized controlled STudy of End-tidal control compared to conventional Results (MASTER) Trial evaluated anesthetic delivery in 210 adult patients receiving inhaled anesthesia. Patients were randomized to either EtC or manual control (MC) anesthetic delivery. The primary objective was to determine whether, compared to conventional anesthesia practice, EtC achieves and maintains clinician-specified EtAA and end-tidal oxygen (Eto2) concentrations within defined noninferiority limits. Noninferiority was concluded if the lower limit of the 95% confidence interval (CI) of the difference between the percent duration within the acceptable range (5% of steady state or a margin of ~10% of each agent's minimum alveolar concentration) for EtC and MC was ≥ -5% for both EtAA and Eto2. Secondary objectives included performance measures: response time: time required to attain 90% of the first desired EtAA, overshoot: amount the controller (or vaporizer delivery) exceeded the desired EtAA, and accuracy: average deviation from the desired EtAA. RESULTS: EtC achieved and sustained targeted EtAA and Eto2 concentrations within the noninferiority threshold. The EtAA was within 5% of the desired value 98% ± 2.05% of the time with EtC compared to 45.7% ± 31.7% of the time with MC (difference 52.3% [95% CI, 45.9%-58.6%], P < .0001). For Eto2, EtC was within the noninferiority limit 86.3% ± 22.8% of the time compared with MC at 41% ± 33.3% (P < .0001, difference 45.3% [95% CI, 36.1%-54.5%]). The median response time for achieving 90% of the initial EtAA desired value was 75 seconds with EtC and 158 seconds with MC (P = .0013). EtC exhibited a median overshoot of 6.64% of the selected EtAA concentration, whereas MC often failed to reach the clinician's desired value. The difference in median percent deviation from desired EtAA value was 15.7% ([95% CI, 13.5%-19.0%], P < 0001). CONCLUSIONS: EtC achieves and maintains the EtAA and Eto2 concentration in a manner that is noninferior to manually controlled anesthesia delivery.

Trends in Cardiac Anesthesiologist Compensation, Work Patterns, and Training From 2010 to 2020: A Longitudinal Analysis of the Society of Cardiovascular Anesthesiologists Salary Survey.

Increasing cardiac procedural volume, a shortage of practicing cardiac anesthesiologists, and growth in specialist physician compensation would be expected to increase cardiac anesthesiologist compensation and work load. Additionally, more cardiac anesthesiologists are graduating from accredited fellowships and completing echocardiography certification. The Society of Cardiovascular Anesthesiologists (SCA) biannual salary survey longitudinally measures these data; we analyzed these data from 2010 to 2020 and hypothesized survey respondent inflation-adjusted total compensation, work load, and training would increase. For the primary outcome, we adjusted the median reported annual gross taxable income for inflation using the Consumer Price Index and then used linear regression to assess changes in inflation-adjusted median compensation. For the secondary outcomes, we analyzed the number of cardiac anesthetics managed annually and the most common care delivery staffing ratios. For the tertiary outcomes, we assessed changes in the proportion of respondents reporting transesophageal echocardiography (TEE) certification and completion of a 12-month cardiac anesthesia fellowship. We performed sensitivity analyses adjusting for yearly proportions of academic and private practice respondents. Annual survey response rates ranged from 8% to 17%. From 2010 to 2020, respondents reported a continuously compounded inflation-adjusted compensation decrease of 1.1% (95% confidence interval [CI], -1.6% to -0.6%; P = .003), equivalent to a total inflation-adjusted salary reduction of 10%. In sensitivity analysis, private practice respondents reported a continuously compounded compensation loss of -0.8% (95% CI, -1.4% to -0.2%; P = .022), while academic respondents reported no significant change (continuously compounded change, 0.4%; 95% CI, -0.4% to 1.1%; P = .23). The percentage of respondents managing more than 150 cardiac anesthetics per year increased from 26% in 2010 to 43% in 2020 (adjusted odds ratio [aOR], 1.03 per year; 95% CI, 1.03-1.04; P < .001). The proportion of respondents reporting high-ratio care models increased from 31% to 41% (aOR, 1.01 per year; 95% CI, 1.01-1.02; P < .001). Reported TEE certification increased from 69% to 90% (aOR, 1.10 per year; 95% CI, 1.10-1.11; P < .001); reported fellowship training increased from 63% to 82% (aOR, 1.15 per year; 95% CI, 1.14-1.16; P < .001). After adjusting for the proportion of academic or private practice survey respondents, SCA salary survey respondents reported decreasing inflation-adjusted compensation, rising volumes of cardiac anesthetics, and increasing levels of formal training in the 2010 to 2020 period. Future surveys measuring burnout and job satisfaction are needed to assess the association of increasing work and lower compensation with attrition in cardiac anesthesiologists.

The Emory University Perioperative Algorithm for the Management of Hyperglycemia and Diabetes in Non-cardiac Surgery Patients.

Hyperglycemia is a frequent manifestation of critical and surgical illness, resulting from the acute metabolic and hormonal changes associated with the response to injury and stress (Umpierrez and Kitabchi, Curr Opin Endocrinol. 11:75-81, 2004; McCowen et al., Crit Care Clin. 17(1):107-24, 2001). The exact prevalence of hospital hyperglycemia is not known, but observational studies have reported a prevalence of hyperglycemia ranging from 32 to 60 % in community hospitals (Umpierrez et al., J Clin Endocrinol Metab. 87(3):978-82, 2002; Cook et al., J Hosp Med. 4(9):E7-14, 2009; Farrokhi et al., Best Pract Res Clin Endocrinol Metab. 25(5):813-24, 2011), and 80 % of patients after cardiac surgery (Schmeltz et al., Diabetes Care 30(4):823-8, 2007; van den Berghe et al., N Engl J Med. 345(19):1359-67, 2001). Retrospective and randomized controlled trials in surgical populations have reported that hyperglycemia and diabetes are associated with increased length of stay, hospital complications, resource utilization, and mortality (Frisch et al., Diabetes Care 33(8):1783-8, 2010; Kwon et al., Ann Surg. 257(1):8-14, 2013; Bower et al., Surgery 147(5):670-5, 2010; Noordzij et al., Eur J Endocrinol. 156(1):137-42, 2007; Mraovic et al., J Arthroplasty 25(1):64-70, 2010). Substantial evidence indicates that correction of hyperglycemia reduces complications in critically ill, as well as in general surgery patients (Umpierrez et al., J Clin Endocrinol Metab. 87(3):978-82, 2002; Clement et al., Diabetes Care 27(2):553-97, 2004; Pomposelli et al., JPEN J Parented Enteral Nutr. 22(2):77-81, 1998). This manuscript reviews the pathophysiology of stress hyperglycemia during anesthesia and the perioperative period. We provide a practical outline for the diagnosis and management of preoperative, intraoperative, and postoperative care of patients with diabetes and hyperglycemia.

Performance of bedside diagnostic ultrasound in an Ebola isolation unit: the Emory University Hospital experience.

OBJECTIVE: Individuals with Ebola virus disease, a contagious and potentially lethal infection, are now being treated in specialized units in the United States. We describe Emory University's initial experience, current operating procedures, and ongoing planning with diagnostic ultrasound in the isolation unit. CONCLUSION: Ultrasound use has been limited to date. Future planning considerations include deciding what types of ultrasound studies will be performed, which personnel will acquire the images, and which ultrasound machine will be used.

Mitral Regurgitation in Patients Undergoing Noncardiac Surgery.

Mitral regurgitation (MR) is one of the most frequently encountered types of valvular heart disease in the United States. Patients with significant MR (moderate-to-severe or severe) undergoing noncardiac surgery have an increased risk of perioperative cardiovascular complications. MR can arise from a diverse array of causes that fall into 2 broad categories: primary (diseases intrinsic to the valvular apparatus) and secondary (diseases that disrupt normal valve function via effects on the left ventricle or mitral annulus). This article highlights key guideline updates from the American College of Cardiologists (ACC) and the American Heart Association (AHA) that inform decision-making for the anesthesiologist caring for a patient with MR undergoing noncardiac surgery. The pathophysiology and natural history of acute and chronic MR, staging of chronic primary and secondary MR, and considerations for timing of valvular corrective surgery are reviewed. These topics are then applied to a discussion of anesthetic management, including preoperative risk evaluation, anesthetic selection, hemodynamic goals, and intraoperative monitoring of the noncardiac surgical patient with MR.

Positioning an intraaortic balloon pump using intraoperative transesophageal echocardiogram guidance.

A 72-year-old man with an ejection fraction of 25% is scheduled to undergo elective coronary artery bypass graft using cardiopulmonary bypass. Because of the high-risk nature of the operation, the surgeon wants to insert an intraaortic balloon pump (IABP) before initiating cardiopulmonary bypass. An intraoperative transesophageal echocardiogram (TEE) is requested to ensure correct placement.

Cost-effectiveness of bispectral index monitoring.

PURPOSE OF REVIEW: In the current era of limited resources, organizations are evaluating the cost-effectiveness of their care. To analyze the cost-effectiveness of a physiologic monitor, one must first determine what negative outcome will be reduced or what positive outcome will be promoted. For example, if one was studying the cost-effectiveness of the pulse oximeter, it would be important to state whether the endpoint is prevention of hypoxic events or prevention of myocardial infarction. One would then need outcome data demonstrating the incidence of the chosen endpoint with and without the monitor. With these data, one can begin to construct a model for cost-effectiveness. Like many medical technologies, the bispectral index (BIS) monitor has recently been the subject of several articles which study its cost-effectiveness. This review examines the rationale of cost-effectiveness analyses and their application specifically to the BIS monitor. RECENT FINDINGS: The BIS monitor has been shown in multiple prospective randomized studies to positively affect several important aspects of an anesthetic. Use of the BIS monitor results in less use of hypnotic anesthetic drugs, decreased time to extubation, decreased incidence of nausea and vomiting, and decreased intraoperative awareness. These benefits are achieved for an additional cost of around five dollars per anesthetic. In addition, there is an emerging body of literature demonstrating an association between low intraoperative BIS readings and decreasing intermediate-term survival in both noncardiac and cardiac surgical patients. SUMMARY: Given the trivial cost of the BIS and the proven benefits demonstrated in prospective randomized studies, we consider its use justified in every general anesthetic.