Military medicine
-
Preservation of life, preservation of limb, and preservation of eyesight are the priorities for military medical personnel when attending to casualties. The incidences of eye injuries in modern warfare have increased significantly, despite personal eye equipment for service members. Serious eye injuries are often overlooked or discovered in a delayed fashion because they accompany other life- and limb-threatening injuries, which are assigned a higher priority. Prehospital military ocular trauma care is to shield the eye and evacuate the casualty to definitive ophthalmic care as soon as possible, with exceptions for treatment of ocular chemical injury and orbital compartment syndrome. Retrospective analysis of eye injuries in recent conflicts identified gaps in clinical capabilities with up to 96% of ocular injuries being suboptimally managed. Ocular compartment syndrome (OCS) is a complication associated with orbital hemorrhage, where significant morbidity occurs as a result of increasing intracompartment pressure. The ischemic tolerance of the retina and optic nerve is approximately 90 minutes, so OCS must be rapidly diagnosed and aggressively treated through lateral canthotomy/cantholysis (LC/C) to prevent permanent vision loss. LC/C procedures consist of using hemostats to crush the lateral canthal fold and cutting the lateral canthal tendon from the inferior crus to relieve increasing intracompartment pressure. The purpose of this study was to examine the baseline capabilities of military physicians and surgeons to accurately and independently perform the LC/C procedures and identify performance gaps that could be closed through focused professional development activities. ⋯ We identified significant performance gaps among emergency medicine physicians, general surgeons, and ophthalmologists in their abilities to recognize and treat OCS through LC/C procedures. These sight-saving procedures are a critical competency for forward-situated clinicians in expeditionary contexts. We identified the need for targeted approaches to professional development for closing the performance gaps for both emergency medicine physicians and general surgeons.
-
Traumatic brain injury (TBI) is a leading cause of morbidity and mortality in both adult civilian and military populations. Currently, diagnostic and prognostic methods are limited to imaging and clinical findings. Biomarker measurements offer a potential method to assess head injuries and help predict outcomes, which has a potential benefit to the military, particularly in the deployed setting where imaging modalities are limited. We determine how biomarkers such as ubiquitin C-terminal hydrolase-L1 (UCH-L1), glial fibrillary acidic protein (GFAP), S100B, neurofilament light chain (NFL), and tau proteins can offer important information to guide the diagnosis, acute management, and prognosis of TBI, specifically in military personnel. ⋯ TBI occurs frequently in the military and civilian settings with limited methods to diagnose and prognosticate outcomes. We highlighted several promising biomarkers for these purposes including S100B, UCH-L1, NFL, GFAP, and tau proteins. S100B and UCH-L1 appear to have the strongest data to date, but further research is necessary. The robust data that explain the optimal timing and, more importantly, trending of these biomarker measurements are necessary before widespread application.
-
There are established protocols for staged return to physical activity in sport and military settings following concussion. Currently, there is no evidence-based staged return to shooting protocol in use by the U.S. military despite the unique challenges and stresses shooting places on the vestibular-ocular and cognitive systems often disrupted by a concussion. The primary purpose of this scoping review was to summarize available evidence and current practices on return to shooting post-concussion, with the goal of optimizing an evidence-based return to shooting protocol for military service members. Our secondary aim was to identify individuals who may benefit from a return to shooting progression. ⋯ Based on our results, there is insufficient evidence to inform current practices on return to shooting post-concussion. In the absence of a published return to shooting protocol, we offer recommendations for identifying individuals who may benefit from a return to shooting progression and a revised version of a U.S. Army Special Operations Command Return to Range Progression. This protocol follows a conceptual framework for progression for variables such as environment, weapon type/caliber, and shooter position/movement. Further research is needed on identifying individuals who may benefit from a return to shooting protocol and safely and effectively progressing these individuals through a return to shooting protocol post-concussion.
-
This column explores the inception, challenges, and prospects of robotic surgery in the military. It highlights the military's role in developing early prototypes, current utilization, training struggles, partnerships with civilian organizations, and potential future applications. The military's influence on the evolving landscape of robotic surgery is emphasized.
-
The potential impact of large-scale combat operations and multidomain operations against peer adversaries poses significant challenges to the Military Health System including large volumes of critically ill and injured casualties, prolonged care times in austere care contexts, limited movement, contested logistics, and denied communications. These challenges contribute to the probability of higher casualty mortality and risk that casualty care hinders commanders' forward momentum or opportunities for overmatch on the battlefield. Novel technical solutions and associated concepts of operation that fundamentally change the delivery of casualty care are necessary to achieve desired medical outcomes that include maximizing Warfighter battle-readiness, minimizing return-to-duty time, optimizing medical evacuation that clears casualties from the battlefield while minimizing casualty morbidity and mortality, and minimizing resource consumption across the care continuum. ⋯ Our path to combat casualty care automation starts with mapping and modeling the context of casualty care in realistic environments through passive data collection of large amounts of unstructured data to inform machine learning models. These context-aware models will be matched with patient physiology models to create casualty digital twins that better predict casualty needs and resources required and ultimately inform and accelerate decision-making across the continuum of care. We will draw from the experience of the automotive industry as an exemplar for achieving automation in health care and inculcate automation as a mechanism for optimizing the casualty care survival chain.