Military Medicine International Journal of amsus raising the bar: extremity trauma care guest editors
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pathological human bone. 29 Further, when data from this cohort of wounded warriors was limited to patients with no more than a two-year period from injury to excision, and known correlates (traumatic brain injury and nonsteroidal anti-in flammatory drugs), the MAR and recurrence severity were signi ficantly related. 29 Research by Dr. Isaacson and his team will now focus on devel- oping a translatable animal model to investigate combat-related factors which have been associated with ectopic bone growth (tourniquets, 34 wound vacuum usage, bioburden, and trauma). RESEARCH FOCUS AREA 3: APPLICATION OF NEW TECHNOLOGIES TO ADVANCE REHABILITATION AND PERFORMANCE CRSR supports and enhances existing clinical programs at the MTFs by facilitating the use of new technologies for rehabilita- tion and performance optimization. A strong partnership has been forged with the MHS, VA, and EACE to help provide infrastruc- ture and personnel support for research projects. Efforts within this research area are led by a team of principal investigators, including Drs. Erik Wolf, Brad Hendershot, Alison Pruziner, Jason Wilken, Christopher Rábago, Elizabeth Russell Esposito, and Ms. Marilynn Wyatt. Advanced evaluation and treatment techniques are applied to help service members regain functionality after physical and cognitive injuries and to understand the longer-term implications of such injuries and rehabilitation processes. Novel rehabilitation techniques applied in multisensory virtual reality environments (VRE) promote resilience and recovery to improve physical and cognitive skills in wounded service members. 4 There are four high-end VRE (Computer Assisted Rehabilitation Environment, Motekforce Link, The Netherlands) used in the MHS to provide a safe, interactive setting for clinicians to simulate com- munity, recreational, or occupational tasks. Dr. Wolf led a CRSR effort to determine the most bene ficial bio- mechanical and physiological feedback modalities within a VRE for delivering physical therapy to injured service members. Preliminary results indicate that a game-style application that provides feedback to the patient in an indirect manner produces the most positive out- comes. In collaboration with Dr. Wolf ’s efforts, Drs. Pruziner and Hendershot are utilizing a VRE to identify how dual tasking with increased cognitive demand affects walking ability for people with unilateral lower limb amputation. Previous research has shown that performing tasks requiring divided attentional resources result in abnormal gait mechanics. Preliminary analyses suggest individuals with amputations may differentially prioritize cognitive and motor processes when walking. This study has potentially important impli- cations regarding the ability to fully participate in a person ’s natural environment after limb loss, and also may relate to an increased risk of falling. Additional ongoing efforts are aimed at evaluating bio- mechanical and cognitive responses to walking in more ecologi- cally valid VRE, as opposed to game-style environments, which will include additional challenges to working memory, decision- making, and navigational skills. Optimizing performance and maximizing functional outcomes are critical components of a rehabilitation program and are synony- mous with returning to active duty for many wounded service mem- bers. Drs. Wilken and Rábago implemented an assessment battery within a militarized VRE to identify functional and cognitive de ficits
that emerge when performing military-speci fic tasks. This study incorporates load carriage, variable terrain negotiation, and quick decision-making. Physiological and biomechanical data collected during these tasks can guide future therapies and the prescription of prosthetic or orthotic devices for service members with lower extremity injuries. This study is the first step in developing a military-relevant assessment battery with objective performance metrics that correlate to return to duty rehabilitation goal. Follow- up studies supported by CRSR will incorporate the knowledge gained from the assessment study into a VRE-based, military- speci fic treatment intervention aimed at returning injured service members to duty and increasing military readiness. In addition to VRE-based rehabilitation, other studies within this focus area seek to understand secondary musculoskeletal complica- tions of limb loss and the in fluences of various technologies and reha- bilitation paradigms. As noted, LBP is especially prevalent among persons with amputation(s), perhaps related to altered gait and move- ment patterns. To better understand these speci fic risk factors, Dr. Hendershot has performed several retrospective studies using the large biomechanical database at WRNMMC to directly quantify how gait deviations in fluence trunk and spine motion among service mem- bers with lower limb loss. Notably, larger and asymmetric trunk MILITARY MEDICINE, Vol. 181, November/December Supplement 2016 23 Advancing the Rehabilitative Care for Service Members With Complex Trauma motions with amputation were associated with increased loading at the lower back during walking 35 and sit-to-stand movements. 36 Although these increases were of small-moderate magnitude, repeated exposures over time may predispose these individuals to LBP onset and recurrence. 37 Ongoing and future research will investigate the origins of altered trunk motion and subsequently assess methods or devices to minimize these loads in an effort to mitigate the preva- lence of LBP among service members with lower limb amputation. Another secondary musculoskeletal complication of unilateral limb loss is osteoarthritis (OA) within joints of the intact limb. Per- sons with unilateral lower limb amputation tend to preferentially use their intact limb during gait and movement, which leads to larger and more prolonged forces applied to the intact knee and/or hip joints. CRSR has funded two retrospective studies to assess gait mechanics in individuals with transtibial and transfemoral limb loss to deter- mine how the intact limb is loaded at various time points during the rehabilitative process. Excessive intact limb loads (relative to con- trols) were only present at early time points among people with trans- tibial amputation, but persisted through late rehabilitation for persons with transfemoral amputation. 38 Such evidence suggests an increased risk for early onset of OA and supports the development and assessment of interventions to correct modi fiable gait mechanics in this population. A prospective evaluation of knee loading has been initiated to begin to address this gap. In order to assist with multisite efforts aimed at sharing and com- bining commonly used biomechanical data across the MTFs, CRSR supported a project to evaluate the intra- and interlab reliability of gait data obtained at WRNMMC, CFI, and NMCSD. 39 Ten par- ticipants traveled to each site to complete three biomechanical gait evaluations according to each laboratory ’s standard operating proce- dures. Data were analyzed by a third party to eliminate bias. Results indicated that these measurements were highly reliable both within and between laboratories, with mean kinematic errors less than 5 degrees across all joints and planes of motion, and mean kinetic errors less than 10% for all joint moments. The ability to collect reliable biomechanical data at these three major facilities will support future multisite studies and data sharing. RESEARCH FOCUS AREA 4: TRANSFER OF NEW TECH- NOLOGY TO IMPROVE INDIVIDUAL PERFORMANCE AND FUNCTIONALITY AFTER INJURYNovel devices, includ- ing prosthetics and orthotics, help return service members with cog- nitive and physical trauma to independent function. Previous research supported by CRSR and USAMRMC compared passive energy-storing and return (ESR) prosthetic feet with a powered ankle foot prosthesis to determine, which novel technology could provide the highest quality of life and expedite rehabilitation regimens. 40 Results indicated that the powered device had a larger range of motion and generated more power during the preswing phase of gait as compared to the energy storing and return, 40 demonstrating how powered devices may assist those with limb loss improve their gait. Ongoing studies continue to examine the effects of advanced prosthetic components, including microprocessor and power knee prosthetics. In addition to examining prosthetic components, orthotic devices are being evaluated to determine their ef ficacy for improv- ing gait in injured service members with extremity trauma and limb salvage. Recent initiatives by Drs. Wilken and Russell Esposito systematically modi fied several mechanical parameters of an ankle-foot orthosis to identify optimal design and prescription criteria for various terrains. 41,42
Because of the high incidence of upper limb loss occurring in combat casualties, focused research has been needed to improve prosthetics and control strategies for individuals with upper limb amputation. CRSR partnered with the Alfred Mann Foundation (http://aemf.org) to conduct a clinical trial through the Food and Drug Administration (FDA) entitled, “First-in-man demonstration of a fully implanted myoelectric sensors system to control an advanced electromechanical prosthetic hand. ” 43 A signi ficant limitation to cur- rent myoelectric devices is their dependence on surface skin sensor electrodes to control their actuation. Unfortunately, these sensors are often unreliable, especially when individuals perspire or when their prosthetic socket moves in different positions. In addition, surface electrodes are limited in that they can only detect super ficial muscle activity and do not provide the user with enough intuitive control. This collaborative study demonstrated the feasibility of implanting wireless electrodes in the forearm of service members with trans- radial amputation to control a 3-degrees-of-freedom prosthetic hand. Future work will include expanding the use of this technology for individuals with transhumeral level amputations. Expanding on the field of upper extremity prosthetics, CRSR is also proud of its partnership with the Defense Advanced Projects Agency (DARPA) to evaluate the performance of the DEKA arm (http://www.dekaresearch.com/deka_arm.shtml). This revolutionary multiple degrees-of-freedom prosthetic arm has received FDA approval and is the first of its kind to help pioneer the intersection between robotics and improving human performance for individuals with disabilities. CRSR also works with DARPA and other aca- demic and industry groups to utilize novel neuroprosthetics to help restore sensory/haptic feedback for prosthetic users. Our research portfolio is bolstered by strong partnerships with teams, such as the Human Engineering Research Laboratories (www.herlpitt.edu), which have helped collectively develop a specialized patient- controlled analgesia device adapter to improve postsurgical pain, autonomy, and independence for patients who have lost the use of their limbs, enabling them to participate in rehabilitation. CONCLUSIONSThe clinical research community has an obliga- tion to address the needs of these service members and veterans with complex orthopedic and neurological injuries stemming from recent con flicts. Injuries to young military service mem- bers, particularly those caused by blasts, pose unique challenges to rehabilitation that require research programs and consortia to help advance science and care. CRSR is dedicated to not only identifying gaps in the research but also to aligning resources in a synergized fashion to de fine and validate the most effective rehabilitation strategies for this patient population. CRSR engages a broad group of interdisciplinary investigators from medicine, biology, engineering, anthropology, and physiology and connects them directly with clinicians, patients, and families to help solve clinically relevant problems for our service mem- bers, veterans, and their families. ACKNOWLEDGMENTS This work is supported by the Department of Physical Medicine and Reha- bilitation, Center for Rehabilitation Science Research, USU, Bethesda, Maryland, awards HU0001-11-1-0004 and HU0001-15-2-0003. MILITARY MEDICINE, Vol. 181, November/December Supplement 2016 24 Advancing the Rehabilitative Care for Service Members With Complex Trauma REFERENCES 1. Fischer H: A Guide to U.S. Military Casualty Statistics: Operation Inherent Resolve, Operation New Dawn, Operation Iraqi Freedom, and Operation Enduring Freedom. CRS Report for Congress 2014:1 –9. Available at https:// www.fas.org/sgp/crs/natsec/RS22452.pdf; accessed August 22, 2016. 2. Pasquina PF: DoD paradigm shift in care of servicemembers with major limb loss. J Rehabil Res Dev 2010; 47(4): xi –xiv. 3. Isaacson BM, Weeks SR, Pasquina PF, Webster JB, Beck JP, Bloebaum RD: The road to recovery and rehabilitation for injured service members with limb loss: a focus on Iraq and Afghanistan. US Army Med Dep J 2010; Jul-Sep: 31 –6.
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MILITARY MEDICINE, Vol. 181, November/December Supplement 2016 25 Advancing the Rehabilitative Care for Service Members With Complex Trauma MILITARY MEDICINE, 181, 11/12:26, 2016 Improving Outcomes Following Extremity Trauma: The Need for a Multidisciplinary Approach MAJ Daniel J. Stinner, MC USA Yüklə 2,47 Mb. Dostları ilə paylaş:
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