Characterizing Bodyweight-Supported Treadmill Walking on Land and Underwater Using Foot-Worn Inertial Measurement Units and Machine Learning for Gait Event Detection.

Gait rehabilitation commonly relies on bodyweight unloading mechanisms, such as overhead mechanical support and underwater buoyancy. Lightweight and wireless inertial measurement unit (IMU) sensors provide a cost-effective tool for quantifying body segment motions without the need for video recordings or ground reaction force measures. Identifying the instant when the foot contacts and leaves the ground from IMU data can be challenging, often requiring scrupulous parameter selection and researcher supervision. We aimed to assess the use of machine learning methods for gait event detection based on features from foot segment rotational velocity using foot-worn IMU sensors during bodyweight-supported treadmill walking on land and underwater. Twelve healthy subjects completed on-land treadmill walking with overhead mechanical bodyweight support, and three subjects completed underwater treadmill walking. We placed IMU sensors on the foot and recorded motion capture and ground reaction force data on land and recorded IMU sensor data from wireless foot pressure insoles underwater. To detect gait events based on IMU data features, we used random forest machine learning classification. We achieved high gait event detection accuracy (95-96%) during on-land bodyweight-supported treadmill walking across a range of gait speeds and bodyweight support levels. Due to biomechanical changes during underwater treadmill walking compared to on land, accurate underwater gait event detection required specific underwater training data. Using single-axis IMU data and machine learning classification, we were able to effectively identify gait events during bodyweight-supported treadmill walking on land and underwater. Robust and automated gait event detection methods can enable advances in gait rehabilitation.

General Surgery Resident Operative Experiences in Solid Organ Injury: An Examination of Case Logs.

BACKGROUND: Non-operative management (NOM) of traumatic solid organ injury (SOI) has become commonplace. This paradigm shift, along with reduced resident work hours, has significantly impacted surgical residents' operative trauma experiences. We examined ongoing changes in residents' operative SOI experience since duty hour restriction implementation, and assessed whether missed operative experiences were gained elsewhere in the resident experience. METHODS: We examined data from American College of Graduate Medical Education case log reports from 2003 to 2018. We collected mean case volumes in the categories of non-operative trauma, trauma laparotomy, and splenic, hepatic, and pancreatic trauma operations; case volumes for comparable non-traumatic solid organ operations were also collected. Solid organ injury operative volumes were compared against non-traumatic cases, and change over time was analyzed. RESULTS: Over the study period, both trauma laparotomies and non-operative traumas increased significantly (P < .001). In contrast, operative volumes for splenic, hepatic, and pancreatic trauma all significantly decreased (P < .001; P = .014; P < .001, respectively). Non-traumatic spleen cases also significantly decreased (P < .001), but liver cases and distal pancreatectomies increased (P < .001; P = .017). Pancreaticoduodenectomies increased, albeit not to a significant degree (P = .052). CONCLUSIONS: Continuing increases in NOM of SOI correlate with declining resident experience with operative solid organ trauma. These decreases can adversely affect residents' technical skills and decision-making, although trends in specific non-traumatic areas may help to mitigate such losses. Further work should determine the impact of these trends on resident competence and autonomy.

Implementation of a Level 1 Neuro Trauma Activation at a Tertiary Pediatric Trauma Center.

INTRODUCTION: Timely management improves outcomes in patients with traumatic brain injury (TBI), especially those requiring operative intervention. We implemented a "Level 1 Neuro" (L1N) trauma activation for severe TBI, aiming to decrease times to intervention. METHODS: We evaluated whether an L1N activation was associated with shorter times to operating room (OR) incision and pediatric intensive care unit (PICU) admission using multivariable regression models. Trauma patients with severe TBI undergoing operative intervention or PICU admission from January 2008-October 2020 met inclusion. The L1N cohort included patients meeting our institution's L1N criteria. The L1 and L2 cohorts included head injury patients with hAIS ≥3 and an L1 or L2 activation, respectively. RESULTS: Median hAIS, GCS, Rotterdam CT score, and ISS were 4.5 (4-5), 8 (3-15), 2 (1-3), and 17 (11-26), respectively. We demonstrate clinically shorter times to OR incision among L1N traumas (93.3 min) compared to L1 (106.7 min; P = 0.73) and L2 cohorts (133.5 min; P = 0.03). We also demonstrate clinically shorter times to anesthesia among L1N traumas (51.9 min) compared to L1 (70.1 min; P = 0.13) and L2 cohorts (101.3 min; P < 0.01). Median GCS, ISS and hAIS in the PICU patients were 10 (IQR:3-15), 17 (11-26), and 4 (3-4), respectively. We demonstrate clinically shorter times to PICU among L1N traumas (82.1 min) and the L2 cohort (154.7 min; P < 0.01). CONCLUSIONS: An L1N activation is associated with shorter times to anesthesia and OR management. Enhancing communication with standardized neurotrauma activation has the potential to improve timeliness of care in severe pediatric TBI.

Quantification of Global Myoelectric Spatial Activations to Delineate Normal Hamstring Function at Progressive Running Speeds: A Technical Report.

ABSTRACT: Schlink, BR, Nordin, AD, Diekfuss, JA, and Myer, GD. Quantification of global myoelectric spatial activations to delineate normal hamstring function at progressive running speeds: A technical report. J Strength Cond Res 36(3): 867-870, 2022-Hamstring function is critical to maintain sport performance, and strain injuries to the biceps femoris muscle commonly force an athlete to withdraw from their sport while the muscle heals. Current mechanistic understanding of underlying injury and return-to-play (RTP) guidelines has limited prognostic value because of limitations in technology and nonfunctional assessment strategies to guide clinical care. Integrated structural and functional determinants and dynamic assessment methods are needed to guide advanced rehabilitation strategies for safe and rapid return to sport. A potential solution for assessment of hamstring function is high-density electromyography (EMG), which can noninvasively measure spatial muscle activity in dynamic environments. In this study, we demonstrated the utility of high-density EMG by measuring spatial myoelectric activity from the biceps femoris from a group of recreational athletes running at a range of speeds. The level of significance set for this study was p < 0.05. During the late swing phase of running, we observed increased EMG amplitudes in the central and distal portions of the muscle. There were no changes in this pattern of EMG activation across speed, suggesting that running speed does not affect the general neuromuscular recruitment in the biceps femoris. Applying these methods to athletes with hamstring strains may lead to a more complete understanding of muscle function during rehabilitation and adjunctively support current methods to enhance RTP decision-making.

British Gynaecological Cancer Society recommendations for women with gynecological cancer who received non-standard care during the COVID-19 pandemic.

During the COVID-19 pandemic, pressures on clinical services required adaptation to how care was prioritised and delivered for women with gynecological cancer. This document discusses potential 'salvage' measures when treatment has deviated from the usual standard of care. The British Gynaecological Cancer Society convened a multidisciplinary working group to develop recommendations for the onward management and follow-up of women with gynecological cancer who have been impacted by a change in treatment during the pandemic. These recommendations are presented for each tumor type and for healthcare systems, and the impact on gynecological services are discussed. It will be important that patient concerns about the impact of COVID-19 on their cancer pathway are acknowledged and addressed for their ongoing care.

Mobile Electroencephalography for Studying Neural Control of Human Locomotion.

Walking or running in real-world environments requires dynamic multisensory processing within the brain. Studying supraspinal neural pathways during human locomotion provides opportunities to better understand complex neural circuity that may become compromised due to aging, neurological disorder, or disease. Knowledge gained from studies examining human electrical brain dynamics during gait can also lay foundations for developing locomotor neurotechnologies for rehabilitation or human performance. Technical barriers have largely prohibited neuroimaging during gait, but the portability and precise temporal resolution of non-invasive electroencephalography (EEG) have expanded human neuromotor research into increasingly dynamic tasks. In this narrative mini-review, we provide a (1) brief introduction and overview of modern neuroimaging technologies and then identify considerations for (2) mobile EEG hardware, (3) and data processing, (4) including technical challenges and possible solutions. Finally, we summarize (5) knowledge gained from human locomotor control studies that have used mobile EEG, and (6) discuss future directions for real-world neuroimaging research.

Secondary overtriage in a pediatric level one trauma center.

BACKGROUND: Previous studies have explored under- and overtriage, and the means by which to optimize these rates. Few have examined secondary overtriage (SO), or the unnecessary transfer of minimally injured patients to higher level trauma centers. We sought to determine the incidence and impact of SO in our pediatric level one trauma center. METHODS: We performed a retrospective analysis of all trauma activations at our institution from 2015 through 2017. SO was defined as transferred patients who required neither PICU admission nor an operation, with ISS ≤ 9 and LOS ≤ 24 h. We compared SO patients against all trauma activation transfers, and against similar non-transferred patients. RESULTS: We identified 1789 trauma activations, including 766 (42.8%) transfers. Of the transfers, 335 (43.7%) met criteria for SO. Compared to other transfers, SO patients had a shorter mean travel distance (52.9 v 58.1 mi; p = 0.02). Compared to similar patients transported from the trauma scene, SO patients were more likely to be admitted (52.2% v 29.2%; p < 0.001), with longer inpatient stay and greater hospital charges. CONCLUSIONS: SO represents an underrecognized burden to trauma centers which could be minimized to improve resource allocation. Future research should evaluate trauma activation criteria for transferred pediatric patients.

Fatigue induces altered spatial myoelectric activation patterns in the medial gastrocnemius during locomotion.

This research investigates the effects of muscle fatigue on spatial myoelectric patterns in the lower limb during locomotion. Both spatial and frequency aspects of neuromuscular recruitment in the medial gastrocnemius change in response to fatigue, resulting in altered myoelectric patterns during walking and running. These data may help us better understand the adaptations that occur in lower limb muscles to avoid overuse injuries caused by fatigue.

Human myoelectric spatial patterns differ among lower limb muscles and locomotion speeds.

The spatial distribution of myoelectric activity within lower limb muscles is often nonuniform and can change during different stationary tasks. Recent studies using high-density electromyography (EMG) have suggested that spatial muscle activity may also differ among muscles during locomotion, but contrasting electrode array sizes and experimental designs have limited cross-study comparisons. Here, we sought to determine if spatial EMG patterns differ among lower limb muscles and locomotion speeds. We recorded high-density EMG from the vastus medialis, tibialis anterior, biceps femoris, medial gastrocnemius, and lateral gastrocnemius muscles of 11 healthy subjects while they walked (1.2 and 1.6 m/s) and ran (2.0, 3.0, 4.0, and 5.0 m/s) on a treadmill. To overcome the detrimental effects of cable, electrode, and soft tissue movements on high-density EMG signal quality during locomotion, we applied multivariate signal cleaning methods. From these data, we computed the spatial entropy and center of gravity from the total myoelectric activity within each recording array during the stance or swing phases of the gait cycle. We found heterogeneous spatial EMG patterns evidenced by contrasting spatial entropy among lower limb muscles. As locomotion speed increased, mean entropy values decreased in four of the five recorded muscles, indicating that EMG signal amplitudes were more spatially heterogeneous, or localized, at faster speeds. The EMG center of gravity location also shifted in multiple muscles as locomotion speed increased. Contrasting myoelectric spatial distributions among muscles likely reflect differences in muscle architecture, but increasingly localized activity and spatial shifts in the center of gravity location at faster locomotion speeds could be influenced by preferential recruitment of faster motor units under greater loads.

Motion and Muscle Artifact Removal Validation Using an Electrical Head Phantom, Robotic Motion Platform, and Dual Layer Mobile EEG.

Motion and muscle artifacts can undermine signal quality in electroencephalography (EEG) recordings during locomotion. We evaluated approaches for recovering ground-truth artificial brain signals from noisy EEG recordings. We built an electrical head phantom that broadcast four brain and four muscle sources. Head movements were generated by a robotic motion platform. We recorded 128-channel dual layer EEG and 8-channel neck electromyography (EMG) from the head phantom during motion. We evaluated ground-truth electrocortical source signal recovery from artifact contaminated data using Independent Component Analysis (ICA) to determine: (1) the number of isolated noise sensor recordings needed to capture and remove motion artifacts, (2) the ability of Artifact Subspace Reconstruction to remove motion and muscle artifacts at contrasting artifact detection thresholds, (3) the number of neck EMG sensor recordings needed to capture and remove muscle artifacts, and (4) the ability of Canonical Correlation Analysis to remove muscle artifacts. We also evaluated source signal recovery by combining the best practices identified in aims 1-4. By including isolated noise and EMG recordings in the ICA decomposition, we more effectively recovered ground-truth artificial brain signals. A reduced subset of 32-noise and 6-EMG channels showed equivalent performance compared to including the complete arrays. Artifact Subspace Reconstruction improved source separation, but this was contingent on muscle activity amplitude. Canonical Correlation Analysis also improved source separation. Merging noise and EMG recordings into the ICA decomposition, with Artifact Subspace Reconstruction and Canonical Correlation Analysis preprocessing, improved source signal recovery. This study expands on previous head phantom experiments by including neck muscle source activity and evaluating artificial electrocortical spectral power fluctuations synchronized with gait events.

Footwear and footstrike change loading patterns in running.

Loading rates have been linked to running injuries, revealing persistent impact features that change direction among three-dimensional axes in different footwear and footstrike patterns. Extracting peak loads from ground reaction forces, however, can neglect the time-varying loading patterns experienced by the runner in each footfall. Following footwear and footstrike manipulations during laboratory-based overground running, we examined three-dimensional loading rate-time features in each direction (X, Y, Z) using principal component analysis. Twenty participants (9 M, 11 F, age: 25.3 ± 3.6 y) were analysed during 14 running trials in each of two footwear (cushioned and minimalist) and three footstrike conditions (forefoot, midfoot, rearfoot). Two principal components (PC) captured the primary loading rate-time features (PC1: 42.5% and PC2: 22.8% explained variance) and revealed interaction among axes, footwear, and footstrike conditions (PC1: F (2.1, 40.1) = 5.6, p = 0.007, η 2 = 0.23; PC2: F (2.0, 38.4) = 62.3, p < 0.001, η 2 = 0.77). Rearfoot running in cushioned footwear attenuated impact loads in the vertical direction, and forefoot running in minimalist footwear attenuated impact loads in the anterior-posterior and medial-lateral directions relative to forefoot running in cushioned shoes. Loading patterns depend on footwear and footstrike interactions, which require shoes that match the runner's footstrike pattern.

Pediatric supracondylar humerus fractures and vascular injuries: A cross-sectional study based on the National Trauma Data Bank.

OBJECTIVE: Supracondylar humerus (SCH) fractures represent one of the most commonly treated fractures. We sought to determine: 1) how often SCH fractures are associated with vascular injury; 2) mechanism of injuries; 3) where cases are treated 4) time to operating room (OR); and 5) length of stay (LOS). METHODS: The 2007-2014 National Trauma Data Bank (NTDB) data were analyzed for all patients <18 years of age who presented with an isolated supracondylar humerus fracture, with or without an associated vascular injury. Both non-operative and operative management were included. Main outcome measures were demographics, mechanism of injury, presence of vascular injury, time to OR, number of OR procedures, type of treating facility, and LOS. Comparisons were performed using Chi square test for categorical variables and Student's t-test for continuous variables. RESULTS: We identified a total of 53,571 pediatric patients over eight years with SCH fractures. Vascular injuries occurred in 149 patients (0.3%), which were significantly more common with open fractures (p < 0.001). Patients with vascular injuries had significantly longer LOS (3.5 days v 1.4 days; p < 0.001) and shorter times to the OR (4.7 h v 10.4 h; p < 0.001), and were more likely to be treated in teaching hospitals and pediatric level 1 trauma centers (p = 0.037). CONCLUSION: The percentage of vascular injuries associated with SCH fractures in pediatric patients remains low (0.3%). The majority of pediatric patients with these injuries are treated at level 1 pediatric trauma centers. LEVEL OF EVIDENCE: Therapeutic, III.

Comparison of Signal Processing Methods for Reducing Motion Artifacts in High-Density Electromyography During Human Locomotion.

Objective: High-density electromyography (EMG) is useful for studying changes in myoelectric activity within a muscle during human movement, but it is prone to motion artifacts during locomotion. We compared canonical correlation analysis and principal component analysis methods for signal decomposition and component filtering with a traditional EMG high-pass filtering approach to quantify their relative performance at removing motion artifacts from high-density EMG of the gastrocnemius and tibialis anterior muscles during human walking and running. Results: Canonical correlation analysis filtering provided a greater reduction in signal content at frequency bands associated with motion artifacts than either traditional high-pass filtering or principal component analysis filtering. Canonical correlation analysis filtering also minimized signal reduction at frequency bands expected to consist of true myoelectric signal. Conclusions: Canonical correlation analysis filtering appears to outperform a standard high-pass filter and principal component analysis filter in cleaning high-density EMG collected during fast walking or running.

Faster Gait Speeds Reduce Alpha and Beta EEG Spectral Power From Human Sensorimotor Cortex.

OBJECTIVE: Our aim was to determine if walking speed affected human sensorimotor electrocortical dynamics using mobile high-density electroencephalography (EEG). METHODS: To overcome limitations associated with motion and muscle artifact contamination in EEG recordings, we compared solutions for artifact removal using novel dual-layer EEG electrodes and alternative signal processing methods. Dual-layer EEG simultaneously recorded human electrocortical signals and isolated motion artifacts using pairs of mechanically coupled and electrically independent electrodes. For electrical muscle activity removal, we incorporated electromyographic (EMG) recordings from the neck into our mobile EEG data processing pipeline. We compared artifact removal methods during treadmill walking at four speeds (0.5, 1.0, 1.5, and 2.0 m/s). RESULTS: Left and right sensorimotor alpha and beta spectral power increased in contralateral limb single support and push off, and decreased during contralateral limb swing at each speed. At faster walking speeds, sensorimotor spectral power fluctuations were less pronounced across the gait cycle with reduced alpha and beta power (p < 0.05) compared to slower speeds. Isolated noise recordings and neck EMG spectral power fluctuations matched gait events and showed broadband spectral power increases at faster speeds. CONCLUSION AND SIGNIFICANCE: Dual-layer EEG enabled us to isolate changes in human sensorimotor electrocortical dynamics across walking speeds. A comparison of signal processing approaches revealed similar intrastride cortical fluctuations when applying common (e.g., artifact subspace reconstruction) and novel artifact rejection methods. Dual-layer EEG, however, allowed us to document and rule out residual artifacts, which exposed sensorimotor spectral power changes across gait speeds.

Decreasing surgical site infections in pediatric stoma closures.

INTRODUCTION: Gastrointestinal (GI) operations represent a significant proportion of the surgical site infection (SSI) burden in pediatric patients, resulting in significant morbidity. We have previously demonstrated that a GI bundle decreases SSI rates, length of stay (LOS), and hospital charges. Following this success, we hypothesized that by targeting the preoperative antibiotics for stoma closures based on organisms found in infected wounds, we could further decrease SSI rates. METHODS: As part of a broad quality improvement effort to reduce SSI rates, we reviewed the responsible pathogens and their sensitivities as well as the preoperative antibiotic used, and found that 15% of wound infections were caused by enterococcus. Based on this information, starting in April 2017, we changed the prior preoperative antibiotic cefoxitin to ampicillin-sulbactam, which more accurately targeted the prevalent pathogens from April 2017 to October 2018. RESULTS: The baseline SSI rate for all stoma takedown patients was 21.4% (25 of 119). After bundle implementation, this decreased to 7.9% (17 of 221; p = 0.03) over a period of 2.5 years. Then, after changing the preoperative antibiotics, our rate of SSI decreased further to 2.2% (1 of 44; p = 0.039) over a period of 1.5 years. CONCLUSION: Significant reduction of SSI in GI surgery can be accomplished with several prevention strategies (our GI bundle). Then a change of the preoperative antibiotic choice, chosen based on causative wound infection organisms, may further decrease SSI rates. We recommend an institution specific analysis of wound infections and modification of preoperative antibiotics if the responsible organisms are resistant to the original antibiotic choice. TYPE OF STUDY: Retrospective cohort study. LEVEL OF EVIDENCE: Level III.

Age-adjusted shock index: From injury to arrival.

BACKGROUND: Studies have demonstrated the superiority of the shock index, pediatric age-adjusted (SIPA) in predicting outcomes in pediatric blunt trauma patients. However, all have utilized SIPA calculated on emergency department (ED) arrival. We sought to evaluate the utility of SIPA at the trauma scene and describe changes in SIPA from the trauma scene to the ED. METHODS: We used 2014-2016 Trauma Quality Improvement Program Data to identify blunt trauma patients 1-15 years old with an injury severity score (ISS) > 15. We calculated SIPA using vitals obtained at the trauma scene and on ED arrival. Outcome measures included ISS, transfusion within 24 h, intensive care unit (ICU), hospital length of stay (LOS), ventilator days, and mortality. RESULTS: We identified 2917 patients, and 34.2% had a persistently elevated SI from the injury scene to ED arrival, whereas 17.9% had a persistently elevated SIPA. An elevated SIPA at the trauma scene was more predictive of greater ISS, LOS, and ventilator requirements. Furthermore, a SIPA that remained abnormal was associated with greater ISS, LOS, ICU admission, mechanical ventilation, and mortality. CONCLUSIONS: Prehospital SIPA values predict worse outcomes in pediatric trauma patients, and their change over time may have greater predictive utility than a single value alone. LEVEL OF EVIDENCE: II TYPE OF STUDY: Prognosis Study.

Human electrocortical dynamics while stepping over obstacles.

To better understand human brain dynamics during visually guided locomotion, we developed a method of removing motion artifacts from mobile electroencephalography (EEG) and studied human subjects walking and running over obstacles on a treadmill. We constructed a novel dual-layer EEG electrode system to isolate electrocortical signals, and then validated the system using an electrical head phantom and robotic motion platform. We collected data from young healthy subjects walking and running on a treadmill while they encountered unexpected obstacles to step over. Supplementary motor area and premotor cortex had spectral power increases within ~200 ms after object appearance in delta, theta, and alpha frequency bands (3-13 Hz). That activity was followed by similar posterior parietal cortex spectral power increase that decreased in lag time with increasing locomotion speed. The sequence of activation suggests that supplementary motor area and premotor cortex interrupted the gait cycle, while posterior parietal cortex tracked obstacle location for planning foot placement nearly two steps ahead of reaching the obstacle. Together, these results highlight advantages of adopting dual-layer mobile EEG, which should greatly facilitate the study of human brain dynamics in physically active real-world settings and tasks.

Reviewing the Variability-Overuse Injury Hypothesis: Does Movement Variability Relate to Landing Injuries?

PURPOSE: Overuse injuries are common in sport, but complete understanding of injury risk factors remains incomplete. Although biomechanical studies frequently examine musculoskeletal injury mechanisms, human movement variability studies aim to better understand neuromotor functioning, with proposed connections between overuse injury mechanisms and changes in motor variability. METHOD: In a narrative review, we discuss the variability-overuse injury hypothesis, which suggests repeated load application leads to mechanical tissue breakdown and subsequent injury when exceeding the rate of physiological adaptation. Due to the multidisciplinary nature of this hypothesis, we incorporate concepts from motor control, neurophysiology, biomechanics, as well as research design and data analysis. We therefore summarize multiple perspectives while proposing theoretical relationships between movement variability and lower extremity overuse injuries. RESULTS: Experimental data are presented and summarized from published experiments examining interactions between experimental task demands and movement variability in the context of drop landing movements, along with comparisons to previous movement variability studies. CONCLUSION: We provide a conceptual framework for sports medicine researchers interested in predicting and preventing sports injuries. Under performance conditions with greater task demands, we predict reduced trial-to-trial movement variability that could increase the likelihood of overuse injuries.

An Enhanced Recovery Protocol that Facilitates Same-day Discharge for Simple Laparoscopic Appendectomies.

Acute appendicitis is the most common gastrointestinal condition requiring urgent operation in the pediatric population with laparoscopic appendectomy (LA) being the current surgical technique. We describe the implementation of a standardized protocol to reduce postoperative nausea and vomiting (PONV) and facilitate same-day discharge after LA. METHODS: A multidisciplinary team developed this protocol to facilitate same-day discharge after observing high rates of overnight stay due to PONV among simple appendectomies performed in 2011-2012. The protocol was implemented in November 2014 and underwent a revision in June 2016. Following the implementation of the protocol, we monitored the patients undergoing an LA at Nationwide Children's Hospital between November 2014 and August 2017. RESULTS: We identified 691 patients (255 female) who underwent a simple LA at Nationwide Children's Hospital between November 2014 and August 2017. The patient population had a median age of 11 years (interquartile range: 9, 14). Among these patients, 514 (74%) were discharged on the day of surgery, and 387 (56%) were protocol compliant. The rate of same-day discharge was higher for compliant cases (79%) than noncompliant cases (69%, P = 0.003). Multivariable statistical analysis associated compliance with an increased likelihood of same-day discharge (Odds ratio [OR] = 1.7, 95% CI: 1.2, 2.4, P = 0.002). CONCLUSIONS: Implementation of the LA protocol to reduce PONV demonstrated a significant increase in the rate of same-day discharge from the hospital among compliant patients. Also, the adoption of a protocol to select patients for early discharge after LA has shown results with a 45% reduction in the need for inhospital beds.

Gangrenous appendicitis: No longer complicated.

BACKGROUND: Appendicitis presents on a spectrum ranging from inflammation to gangrene to perforation. Studies suggest that gangrenous appendicitis has lower postoperative infection rates relative to perforated cases. We hypothesized that gangrenous appendicitis could be successfully treated as simple appendicitis, reducing length of stay (LOS) and antibiotic usage without increasing postoperative infections. METHODS: In February 2016, we strictly defined complex appendicitis as a hole in the appendix, extraluminal fecalith, diffuse pus or a well-formed abscess. We switched gangrenous appendicitis to a simple pathway and reviewed all patients undergoing laparoscopic appendectomy for 12 months before (Group 1) and 12 months after (Group 2) the protocol change. Data collected included demographics, appendicitis classification, LOS, presence of a postoperative infection, and 30-day readmissions. RESULTS: Patients in Group 1 and Group 2 were similar, but more cases of simple appendicitis occurred in Group 2. Average LOS for gangrenous appendicitis patients decreased from 2.5 to 1.4 days (p < 0.001) and antibiotic doses decreased from 5.2 to 1.3 (p < 0.001). Only one gangrenous appendicitis patient required readmission, and one patient in each group developed a superficial infection; there were no postoperative abscesses. CONCLUSIONS: Gangrenous appendicitis can be safely treated as simple appendicitis without increasing postoperative infections or readmissions. TYPE OF STUDY: Prognosis study. LEVEL OF EVIDENCE: Level II.