Your search keyword '"Amanda M. Kleiman"' showing total 3 results

1. Untapped Potential of Dexmedetomidine

Author

Amanda M. Kleiman and Ken B. Johnson

Subjects

medicine.medical_specialty, MEDLINE, Risk Assessment, Perioperative Care, law.invention, Patient safety, law, Cardiopulmonary bypass, Medicine, Humans, Hypnotics and Sedatives, Dexmedetomidine, Intensive care medicine, Pain, Postoperative, Cardiopulmonary Bypass, business.industry, Analgesics, Non-Narcotic, Opioid-Related Disorders, Analgesics, Opioid, Anesthesiology and Pain Medicine, Perioperative care, Patient Safety, business, Risk assessment, Electrophysiologic Techniques, Cardiac, Introductory Journal Article, medicine.drug

Published

2019

2. Impact of Caffeine Ingestion on the Driving Performance of Anesthesiology Residents After 6 Consecutive Overnight Work Shifts

Author

Amanda M. Kleiman, Edward C. Nemergut, Matthew Moncrief, David C. Scalzo, Daniel J. Cox, and Julie L. Huffmyer

Subjects

Adult, Male, medicine.medical_specialty, Automobile Driving, Time Factors, Workload, law.invention, 03 medical and health sciences, 0302 clinical medicine, Randomized controlled trial, 030202 anesthesiology, law, Anesthesiology, Caffeine, Task Performance and Analysis, medicine, Reaction Time, Energy Drinks, Humans, Cross-Over Studies, business.industry, Psychomotor vigilance task, Driving simulator, Accidents, Traffic, Internship and Residency, Shift Work Schedule, Crossover study, Anesthesiologists, Alertness, Sleep deprivation, High Fidelity Simulation Training, Anesthesiology and Pain Medicine, Education, Medical, Graduate, Physical therapy, Central Nervous System Stimulants, Female, medicine.symptom, business, Arousal, 030217 neurology & neurosurgery

Abstract

Background Residency training in anesthesiology involves care of hospitalized patients and necessitates overnight work, resulting in altered sleep patterns and sleep deprivation. Caffeine consumption is commonly used to improve alertness when fatigued after overnight work, in preparation for the commute home. Methods We studied the impact of drinking a caffeinated energy drink (160 mg of caffeine) on driving performance in a high-fidelity, virtual reality driving simulator (Virginia Driving Safety Laboratory using the Driver Guidance System) in anesthesiology resident physicians immediately after 6 consecutive night-float shifts. Twenty-six residents participated and were randomized to either consume a caffeinated or noncaffeinated energy drink 60 minutes before the driving simulation session. After a subsequent week of night-float work, residents performed the same driving session (in a crossover fashion) with the opposite intervention. Psychomotor vigilance task (PVT) testing was used to evaluate reaction time and lapses in attention. Results After 6 consecutive night-float shifts, anesthesiology residents who consumed a caffeinated energy drink had increased variability in driving for throttle, steering, and speed during the first 10 minutes of open-road driving but proceeded to demonstrate improved driving performance with fewer obstacle collisions (epoch 2: 0.65 vs 0.87; epoch 3: 0.47 vs 0.95; P = .03) in the final 30 minutes of driving as compared to driving performance after consumption of a noncaffeinated energy drink. Improved driving performance was most apparent during the last 30 minutes of the simulated drive in the caffeinated condition. Mean reaction time between the caffeine and noncaffeine states differed significantly (278.9 ± 29.1 vs 294.0 ± 36.3 milliseconds; P = .021), while the number of major lapses (0.09 ± 0.43 vs 0.27 ± 0.55; P = .257) and minor lapses (1.05 ± 1.39 vs 2.05 ± 3.06; P = .197) was not significantly different. Conclusions After consuming a caffeinated energy drink on conclusion of 6 shifts of night-float work, anesthesiology residents had improved control of driving performance variables in a high-fidelity driving simulator, including a significant reduction in collisions as well as slightly faster reaction times.

Published

2019

3. Generative Retrieval Improves Learning and Retention of Cardiac Anatomy Using Transesophageal Echocardiography

Author

Jennie Z. Ma, Katherine T. Forkin, Allison J. Bechtel, Julie L. Huffmyer, Edward C. Nemergut, Stephen R. Collins, and Amanda M. Kleiman

Subjects

Male, medicine.medical_specialty, Linear mixed effect model, Students, Medical, 020205 medical informatics, Cardiac anatomy, Video Recording, 02 engineering and technology, law.invention, 03 medical and health sciences, 0302 clinical medicine, Randomized controlled trial, law, Anesthesiology, Internal medicine, 0202 electrical engineering, electronic engineering, information engineering, Medicine, Humans, 030212 general & internal medicine, business.industry, Teaching, Significant difference, Virginia, Internship and Residency, Retention, Psychology, Heart, Perioperative, Cardiac Anesthesia, Anesthesiologists, Anesthesiology and Pain Medicine, Education, Medical, Graduate, Cardiology, Mixed effects, Linear Models, Educational Status, Female, Clinical Competence, Curriculum, Educational Measurement, Anatomy, business, human activities, Echocardiography, Transesophageal, Education, Medical, Undergraduate

Abstract

Background Transesophageal echocardiography (TEE) is a valuable monitor for patients undergoing cardiac and noncardiac surgery as it allows for evaluation of cardiovascular compromise in the perioperative period. It is challenging for anesthesiology residents and medical students to learn to use and interpret TEE in the clinical environment. A critical component of learning to use and interpret TEE is a strong grasp of normal cardiovascular ultrasound anatomy. Methods Fifteen fourth-year medical students and 15 post-graduate year (PGY) 1 and 2 anesthesiology residents without prior training in cardiac anesthesia or TEE viewed normal cardiovascular anatomy TEE video clips; participants were randomized to learning cardiac anatomy in generative retrieval (GR) and standard practice (SP) groups. GR participants were required to verbally identify each unlabeled cardiac anatomical structure within 10 seconds of the TEE video appearing on the screen. Then a correctly labeled TEE video clip was shown to the GR participant for 5 more seconds. SP participants viewed the same TEE video clips as GR but there was no requirement for SP participants to generate an answer; for the SP group, each TEE video image was labeled with the correctly identified anatomical structure for the 15 second period. All participants were tested for intermediate (1 week) and late (1 month) retention of normal TEE cardiovascular anatomy. Improvement of intermediate and late retention of TEE cardiovascular anatomy was evaluated using a linear mixed effects model with random intercepts and random slopes. Results There was no statistically significant difference in baseline score between GR (49% ± 11) and SP (50% ± 12), with mean difference (95% CI) -1.1% (-9.5, 7.3%). At 1 week following the educational intervention, GR (90% ± 5) performed significantly better than SP (82% ± 11), with mean difference (95% CI) 8.1% (1.9, 14.2%); P = .012. This significant increase in scores persisted in the late posttest session at one month (GR: 83% ± 12; SP: 72% ± 12), with mean difference (95% CI) 10.2% (1.3 to 19.1%); P = .026. Mixed effects analysis showed significant improvements in TEE cardiovascular anatomy over time, at 5.9% and 3.5% per week for GR and SP groups respectively (P = .0003), and GR improved marginally faster than SP (P = .065). Conclusions Medical students and anesthesiology residents inexperienced in the use of TEE showed both improved learning and retention of basic cardiovascular ultrasound anatomy with the incorporation of GR into the educational experience.

Published

2017