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Exoskeletal solutions to enable mobility with a lower leg fracture in austere environments

Published online by Cambridge University Press:  28 February 2023

W. Brett Johnson*
Affiliation:
Research and Surveillance Division, Extremity Trauma and Amputation Center for Excellence, San Antonia, TX 78234, USA Center for the Intrepid, Brooke Army Medical Center, San Antonia, TX 78219, USA
Aaron Young
Affiliation:
School of Mechanical Engineering, Georgia Institute of Technology, Atlanta, GA 30332, USA
Stephen Goldman
Affiliation:
Research and Surveillance Division, Extremity Trauma and Amputation Center for Excellence, San Antonia, TX 78234, USA Uniformed Services University of the Health Sciences, Bethesda, MD 20814, USA
Jon Wilson
Affiliation:
Alabama College of Osteopathic Medicine, Dothan, AL 36303, USA
Joseph F. Alderete
Affiliation:
US Army Institute of Surgical Research, San Antonia, TX 78234, USA
W. Lee Childers
Affiliation:
Research and Surveillance Division, Extremity Trauma and Amputation Center for Excellence, San Antonia, TX 78234, USA Center for the Intrepid, Brooke Army Medical Center, San Antonia, TX 78219, USA
*
*Author for correspondence: W. Brett Johnson, Email: [email protected]

Abstract

The treatment and evacuation of people with lower limb fractures in austere environments presents unique challenges that assistive exoskeletal devices could address. In these dangerous situations, independent mobility for the injured can preserve their vital capabilities so that they can safely evacuate and minimize the need for additional personnel to help. This expert view article discusses how different exoskeleton archetypes could provide independent mobility while satisfying the requisite needs for portability, maintainability, durability, and adaptability to be available and useful within austere environments. The authors also discuss areas of development that would enable exoskeletons to operate more effectively in these scenarios as well as preserve the health of the injured limb so that definitive treatment after evacuation will produce better outcomes.

Type
Review Article
Creative Commons
Creative Common License - CCCreative Common License - BY
To the extent any of this work is attributable solely to the US Government, it is not subject to copyright protection within the United States. Published by Cambridge University Press.
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Georgia Institute of Technology, 2023

1. Introduction

Whether they are adventuring in the wilderness, navigating a disaster area, or fighting in a warzone, people encounter austere environments, which are characterized by rugged or remote terrain and potential exposure to hazardous kinetic, potential, thermal, or electromagnetic energy. Given the nature of these domains and the inherent challenges in resupply logistics, medical resources are often limited relative to demand. Survival in austere environments becomes much more challenging when an individual acquires a severe lower limb injury, such as a Gustilo type II/III long bone fracture. Hazards within austere environments and a paucity of resources limit the extent of care for extremity injuries (Anagnostou et al., Reference Anagnostou, Michas and Giannou2020). As such, medical evacuation away from the austere environment and toward a well-resourced medical facility is ideal for reducing injuries and their sequelae and has been a key medical strategy of the U.S. Military for the past two decades of conflict (Kotwal et al., Reference Kotwal, Howard, Orman, Tarpey, Bailey, Champion, Mabry, Holcomb and Gross2016; Keenan and Riesberg, Reference Keenan and Riesberg2017). However, rugged and remote terrain, hazardous weather, unstable geology (e.g. disaster area), or active combat within contested airspace (Venticinque and Grathwohl, Reference Venticinque and Grathwohl2008; Keenan, Reference Keenan2015; Mohr and Keenan, Reference Mohr and Keenan2015; Karlberg, Reference Karlberg2016; US Department of the Army, 2016, 2018; Keenan and Riesberg, Reference Keenan and Riesberg2017; Anagnostou et al., Reference Anagnostou, Michas and Giannou2020) can prevent rapid medical evacuation. To decrease mortality and morbidity when evacuation is delayed, medical personnel in austere environments will need to provide care analogous to hospital-based management, but with limited resources at hand. This effort is known as Prolonged Care (PC) (Keenan, Reference Keenan2015; Keenan and Riesberg, Reference Keenan and Riesberg2017). PFC involves care beyond the traditional acute damage control measures found in combat casualty care and wilderness medicine but is still short of resource-intensive definitive treatment.

Lower extremity fractures are challenging in PFC because they occur frequently and require a lot of resources to treat and transport people with these injuries (Owens et al., Reference Owens, Kragh, Macaitis, Svoboda and Wenke2007; Wild, Reference Wild2008; Dougherty et al., Reference Dougherty, Mohrle, Galarneau, Woodruff, Dye and Quinn2009; Belmont et al., Reference Belmont, Schoenfeld and Goodman2010; Belmont et al., Reference Belmont, Thomas, Goodman, Schoenfeld, Zacchilli, Burks and Owens2011; US Department of the Army, 2011; Stella-Watts et al., Reference Stella-Watts, Holstege, Lee and Charlton2012; Schoenfeld et al., Reference Schoenfeld, Dunn, Bader and Belmont2013; Soteras et al., Reference Soteras, Subirats and Strapazzon2015; Ströhle et al., Reference Ströhle, Beeretz, Rugg, Woyke, Rauch and Paal2020). During the US conflict in Afghanistan, musculoskeletal injuries to the extremities were the most common injury (Owens et al., Reference Owens, Kragh, Macaitis, Svoboda and Wenke2007; Dougherty et al., Reference Dougherty, Mohrle, Galarneau, Woodruff, Dye and Quinn2009; Belmont et al., Reference Belmont, Schoenfeld and Goodman2010, Reference Belmont, Thomas, Goodman, Schoenfeld, Zacchilli, Burks and Owens2011; US Department of the Army, 2011; Schoenfeld et al., Reference Schoenfeld, Dunn, Bader and Belmont2013), and among those injuries, fractures were the second most frequent, second only to gunshot wounds (Owens et al., Reference Owens, Kragh, Macaitis, Svoboda and Wenke2007). The tibia was the most common fracture site (Owens et al., Reference Owens, Kragh, Macaitis, Svoboda and Wenke2007). People with tibia fractures (particularly those with open fractures) in austere environments will need assistance moving to avoid hazards, navigate terrain, and reach a safe evacuation point. Also, outside of the combat environment injuries to individuals participating in wilderness activities most often involve the lower extremities (Wild, Reference Wild2008; Stella-Watts et al., Reference Stella-Watts, Holstege, Lee and Charlton2012; Soteras et al., Reference Soteras, Subirats and Strapazzon2015; Ströhle et al., Reference Ströhle, Beeretz, Rugg, Woyke, Rauch and Paal2020), with 41% of those being fractures (Stella-Watts et al., Reference Stella-Watts, Holstege, Lee and Charlton2012).

Injured people are often carried on litters/stretchers by four to six people, and in combat zones, this litter team will need to be protected by a fire team of up to five members. In such a scenario, one lower limb injury has effectively removed ten people from a mission. This large cost in personnel can quickly drain a team’s human resources and limit their efficacy in the field. In a wilderness rescue scenario, there may not be enough people to carry the injured person out of an area. Enabling the injured to move independently without a litter would preserve human resources and increase the capabilities of teams with a casualty in the field (Figure 1).

Figure 1. A fracture sustained in the field traditionally requires splinting to immobilize the limb and additional personnel are required to evacuate the wounded (a). Packable exoskeleton solutions may provide the opportunity for a person to remain mobile so that they can self-evacuate, or remain on mission (b).

Given that extremity injuries, particularly long bone fractures, are (1) highly prevalent in modern warfare (Owens et al., Reference Owens, Kragh, Macaitis, Svoboda and Wenke2007; Dougherty et al., Reference Dougherty, Mohrle, Galarneau, Woodruff, Dye and Quinn2009; Belmont et al., Reference Belmont, Schoenfeld and Goodman2010, Reference Belmont, Thomas, Goodman, Schoenfeld, Zacchilli, Burks and Owens2011; US Department of the Army, 2011; Schoenfeld et al., Reference Schoenfeld, Dunn, Bader and Belmont2013) and wilderness activities (Wild, Reference Wild2008; Stella-Watts et al., Reference Stella-Watts, Holstege, Lee and Charlton2012; Soteras et al., Reference Soteras, Subirats and Strapazzon2015; Ströhle et al., Reference Ströhle, Beeretz, Rugg, Woyke, Rauch and Paal2020) and (2) inherently disabling by preventing weight bearing through the affected limb, there exists a need for enabling technologies that can stabilize an injured limb and restore some level of independent mobility. These technologies would allow a wounded person to reach a safe evacuation point and/or unburden the mission. However, stabilizing lower limb fractures in a pre-hospital setting while simultaneously enabling weight bearing is a challenge for medical care. The current standard of care for fractures in the field is to stabilize them through splinting (Figure 2) and evacuate the patient to a surgical team for more definitive treatments within an hour (Keenan and Riesberg, Reference Keenan and Riesberg2017). These splints are typically made from semi-rigid materials that are not strong enough to bear weight, and therefore cannot restore upright mobility to the injured.

Figure 2. Devices for stabilizing fractures in the field. (a) A Structural Aluminum Malleable (SAM) splint is a thin sheet of aluminum that can be folded to form a splint. (b) Rigid Immobilization System for Extremities (RISE) is a foldable plastic strip with snaps that allow it to form an ‘L’ shape; so that it can stabilize joints like the ankle or the elbow.

Exoskeletons have the potential to restore mobility to someone who acquires a long bone fracture in an austere environment. Exoskeletal orthoses have been used for decades to help people with lower leg injuries move independently (Figure 3). Exoskeletons can redirect loads around an injured limb to more proximal tissues (Franklin et al., Reference Franklin, Hsu, Wilken, McMenemy, Ramasamy and Stinner2019), stabilize joints, and provide power to limbs; all of which would be useful in helping people with injured limbs move and interact with their environment. Redistributing loads away from the injury will prevent exacerbation and reduce pain while preserving the ability to bear weight. Stabilizing a joint can restore the ability of the limb to bear loads when pain or musculoskeletal damage prevents voluntary joint control. Adding power to limbs may restore even more function, allowing the exoskeleton to perform work without loading the injured limb.

Figure 3. Exoskeletons that enable mobility for people with lower leg injuries. (a) Fracture Orthosis for ankle sprains and fractures (Orthotronix, Las Vegas, NV). (b) Intrepid Dynamic Exoskeletal Orthosis (IDEO) uses a stiff carbon fiber strut to offload the ankle joint, relieve pain, and improve functional control for people who underwent limb salvage surgery.

However, austere environments provide unique challenges for traditional exoskeletal designs (Table 1). Many of the exoskeletal orthoses provided in clinics are designed for domestic conditions (clean, dry, even, level, firm terrain) and for limbs that have received definitive fracture stabilization treatment (e.g., open reduction and internal fixation). They are not intended to be used in the dirty, wet, uneven, inclined, loose terrain found in austere environments (Venticinque and Grathwohl, Reference Venticinque and Grathwohl2008; Keenan, Reference Keenan2015; Mohr and Keenan, Reference Mohr and Keenan2015; US Department of the Army, 2016, 2018; Keenan and Riesberg, Reference Keenan and Riesberg2017; Anagnostou et al., Reference Anagnostou, Michas and Giannou2020), or for legs with unstable fractures. Effective exoskeletal devices for PFC should be adaptable: able to traverse mud, sand, and snow and navigate up, down, or across steep slopes. Devices will need to be durable enough to withstand the abrasive and corrosive conditions typical of austere environments (Venticinque and Grathwohl, Reference Venticinque and Grathwohl2008; Keenan, Reference Keenan2015; Mohr and Keenan, Reference Mohr and Keenan2015; US Department of the Army, 2016, 2018; Keenan and Riesberg, Reference Keenan and Riesberg2017; Anagnostou et al., Reference Anagnostou, Michas and Giannou2020). Sand and grit can get inside joints and crevices and weaken the device through wear, while moisture can induce rust and rot in different materials. Exoskeletons for PFC must be strong enough to endure impacts from the falls that will occur when navigating rugged terrain.

Table 1. Summary of essential criterion for medical exoskeletons in austere environments

The remoteness of austere environments will also be a challenge for PFC exoskeletons (Venticinque and Grathwohl, Reference Venticinque and Grathwohl2008; Keenan, Reference Keenan2015; Mohr and Keenan, Reference Mohr and Keenan2015; Keenan and Riesberg, Reference Keenan and Riesberg2017; US Department of the Army, 2016, 2018; Anagnostou et al., Reference Anagnostou, Michas and Giannou2020). Operation of the exoskeletons must be maintainable long enough to get the user out of the austere environment with limited access to supplies like fuel, electricity, or tools. In addition, limited opportunities for resupply necessitate that the exoskeleton is portable because someone will need to carry the device along with their other equipment so that it is available at the time and point of injury. As such, the exoskeleton should be lightweight to minimize total pack load, and must fit within a backpack, while allowing room for other equipment (and in the case of a combat unit, weapons, ammunition, and armor). These restrictions on bulk and weight mean that the traditional clinical practice of using multiple, separate devices of varied sizes to fit a range of users is not feasible. A single PFC exoskeleton must accommodate most leg sizes among people and fit both the right and left leg.

The purpose of this article was to provide our perspective on currently available exoskeletons from different application areas (load carriage, rehabilitation, and joint control) and how they could enable mobility after someone has sustained a tibia fracture in an austere environment. The authors discuss device capabilities and how these characteristics may be suitable for PC with an emphasis on adaptability, durability, maintainability, and portability. While this article focuses on a unique application for exoskeletons, there are several comprehensive reviews with a broader scope for interested readers (Dollar and Herr, Reference Dollar and Herr2008; Yan et al., Reference Yan, Cempini, Oddo and Vitiello2015; Young and Ferris, Reference Young and Ferris2017).

2. Useful exoskeleton design features for an austere environment

Exoskeletons are designed for different functions. Some offload the human skeleton so that people can lift and carry loads beyond their innate capacity (Chu et al., Reference Chu, Kazerooni and Zoss2005; Ghan et al., Reference Ghan, Steger and Kazerooni2006; Bogue, Reference Bogue2015) (Figure 4). Others redistribute power across joints, which offloads muscles, reduces interjoint forces, and enhances performance through increased force generation (Bogue, Reference Bogue2015) or reduced metabolic cost (Mooney et al., Reference Mooney, Rouse and Herr2014; Mooney and Herr, Reference Mooney and Herr2016). Clinical exoskeletons support healing and rehabilitation by immobilizing injured joints or restoring functional losses following muscle or nerve injury (Douglas et al., Reference Douglas, Larson, D’Ambrosia and McCall1983).

Figure 4. Examples of hard active and hard passive exoskeletons performing different functions.

Different design features can help fulfill the same function but impart different benefits and costs to each device. Some exoskeletons are active with actuators and power sources (Chu et al., Reference Chu, Kazerooni and Zoss2005; Ghan et al., Reference Ghan, Steger and Kazerooni2006), while others utilize only passive components (Douglas et al., Reference Douglas, Larson, D’Ambrosia and McCall1983) such as struts, springs and dampers. Many exoskeletons are made from hard, rigid materials that can support the wearer under compressive or tensile loads (Douglas et al., Reference Douglas, Larson, D’Ambrosia and McCall1983; Chu et al., Reference Chu, Kazerooni and Zoss2005; Bogue, Reference Bogue2015). However, some recent exoskeletons have been made from soft and flexible materials (Ding et al., Reference Ding, Kim, Kuindersma and Walsh2018). These devices are light, portable, and can easily conform to the contours of many different users. Soft exoskeletons can even add power to human movements by actuating flexible cables that behave like external muscles. Prototype soft exoskeletons like the Warrior Web have demonstrated how these devices can help improve human performance by reducing metabolic energy cost (Ding et al., Reference Ding, Kim, Kuindersma and Walsh2018). Soft exoskeletons can also offload joint forces, which may be useful in treating some injuries. However, soft exoskeletal frames cannot transmit compressive loads. To offload the fracture site during walking, compressive loads from the body center of mass to the ground that were normally born through the fractured bone must be redirected and transmitted through some other structure. Therefore, soft exoskeletons will not likely be helpful in offloading an injured limb as there is no clear way for them to fulfill this critical function.

2.1. Hard active

Exoskeletons with a rigid frame and actuated joints have been studied and commercialized for numerous applications in rehabilitation, walking assistance, and human augmentation (Young and Ferris, Reference Young and Ferris2017). In general, these devices have key advantages in adapting to both the environment and user through advanced sensing and artificial intelligence capabilities (Cardona et al., Reference Cardona, García Cena, Serrano and Saltaren2020; Kang et al., Reference Kang, Molinaro, Choi and Young2020; Vélez-Guerrero et al., Reference Vélez-Guerrero, Callejas-Cuervo and Mazzoleni2021). In addition, hard active devices have been shown to augment human performance in terms of reducing the metabolic cost of ambulation (Mooney et al., Reference Mooney, Rouse and Herr2014; Seo et al., Reference Seo, Lee, Lee, Ha and Shim2016; Sawicki et al., Reference Sawicki, Beck, Kang and Young2020) and joint loading (Weston et al., Reference Weston, Alizadeh, Knapik, Wang and Marras2018). These traits make hard active devices an appealing candidate for PC exoskeletons; however, available devices in this class would likely limit one’s mobility after major lower limb injury within austere environments. The following case examples of representative devices from key classes of hard active exoskeletons will illustrate these points, while also detailing important design features, which these devices entail, that could be useful in PFC.

Hard active exoskeletons are already used in clinical settings to help with walking rehabilitation after injury; examples include FDA-approved devices such as the Ekso (Ekso Bionics, Richmond, CA) (Kolakowsky-Hayner et al., Reference Kolakowsky-Hayner, Crew, Moran and Shah2013), Rewalk (ReWalk Robotics, Marlborough, MA) (Zeilig et al., Reference Zeilig, Weingarden, Zwecker, Dudkiewicz, Bloch and Esquenazi2012) and Indego (Parker Hannafin, Macedonia, OH) (Farris et al., Reference Farris, Quintero, Murray, Ha, Hartigan and Goldfarb2014; Parker Hannifin Corporation, 2020). The Indego exoskeleton is comprised of fully powered bilateral knee and hip joints and enables walking after lower limb neuromuscular disability with the use of walking aids (Juszczak et al., Reference Juszczak, Gallo and Bushnik2018). One useful feature of the Indego is its ability to fit people of different sizes. Versions of the Indego for use in the clinic were made adjustable, so that one device could be used with multiple patients. This adjustability is well suited for use in austere environments, so that only one device needs to be carried to treat different-sized patients. The Indego’s packability highlights another feature that is useful for PFC. The modular design allows the Indego to be disassembled and stored in a small duffle bag, and it can be quickly reassembled for deployment. However, these gains in portability are limited by the bulk and mass of the electric motors and large batteries. These complex components also introduce more potential points of failure and limit their durability in austere environments. The need for external power also limits a device’s maintainability as access to replacement batteries will be unlikely during PFC. Lastly, these devices currently enable slow walking speeds, which is not ideal for scenarios (like combat) that will require rapid movements.

Single joint control exoskeletons have demonstrated benefits by reducing metabolic cost and muscle effort during locomotion (Lenzi et al., Reference Lenzi, Carrozza and Agrawal2013; Mooney et al., Reference Mooney, Rouse and Herr2014; Seo et al., Reference Seo, Lee, Lee, Ha and Shim2016; MacLean and Ferris, Reference MacLean and Ferris2019). These devices can be constructed efficiently with minimal weight and a low profile, but they lack the ability to formally stabilize gait because they only act across a single joint. A commercially available example for military applications is the Dephy Exoboot (Dephy, Maynard, MA). Past studies have shown significant advantages in reducing metabolic cost compared to unaided walking as well as during load carriage (Mooney et al., Reference Mooney, Rouse and Herr2014). These exoskeletons (regardless of joint) provide active torque around the targeted joint to increase the ground reaction force and help propel the body forward (Mooney and Herr, Reference Mooney and Herr2016), which could be useful for supplementing muscular power lost due to injury. However, to increase forward propulsion, the added impulse must travel through the entire leg, which would exacerbate a lower limb injury. There is potential to avoid this by transmitting the energy through a rigid mechanical frame and around the injury site, which leads to our next class of devices.

Load-transferring exoskeletons redirect added load, usually in the form of a backpack near the center of mass, into the ground through a rigid exoskeleton frame. An example of this type of design was the BLEEX (Berkeley Lower Extremity Exoskeleton), eventually renamed HULC (Human Universal Load Carrier) (Lockheed Martin, Bethesda, MD), which was designed for dismounted warfighters (Chu et al., Reference Chu, Kazerooni and Zoss2005; Zoss et al., Reference Zoss, Kazerooni and Chu2006; Kazerooni, Reference Kazerooni2008). Full-powered lower limb control could enable the exoskeleton to move in tandem with the user without creating resistance and even compensate for limitations in the user’s lower limb function. However, in practice, complicated and sometimes antagonistic interactions between the user and the exoskeleton’s computerized joint control system have limited these designs (Li et al., Reference Li, Cheng, Liu, Zhang and Wang2018; Mudie et al., Reference Mudie, Billing, Garofolini, Karakolis and LaFiandra2021). Evaluations of the BLEEX by the U.S. Army showed increased metabolic cost both with and without load and revealed kinematic limitations that reduced stability measures (Schiffman et al., Reference Schiffman, Gregorczyk, Bensel, Hasselquist and Obusek2008; Gregorczyk et al., Reference Gregorczyk, Hasselquist, Schiffman, Bensel, Obusek and Gutekunst2010). Presently available hard active exoskeletons do not appropriately support a wounded user or provide them sufficient mobility. These devices will need a significant redesign and more advanced control systems to be used in austere environments.

2.2. Hard passive

Hard passive exoskeletons offer offloading capabilities like hard active exoskeletons, yet without the drawbacks of increased weight and complexity from actuators, control systems, and batteries. The lighter passive devices are more portable and have fewer points of failure, which enhances their durability. They are also easier to maintain as they do not require fuel or electricity for continued operation, an essential feature in resource-restricted environments. However, passive exoskeletons lack the adaptability that active devices can provide. Without actuators to stabilize and control joints, passive exoskeletons often rely on immobilizing or constraining joints, which limits the limb’s ability to adapt to different terrain. This reduced adaptability may limit user mobility and thus reduce the utility of the device, yet to what extent and how that relates to the cost/benefit of the overall system to a team remains unknown.

Some passive exoskeletons, like the Ultralight Passive Ruggedized Integrated Soldier Exoskeleton (UPRISE) (Mawashi, Quebec, Canada) (Diamond-Ouellette et al., Reference Diamond-Ouellette, Telonia, Blanchette, Crocker, Bouyer and Best2020), have been designed for load transmission. The UPRISE has a light titanium frame that extends from the trunk to the ground. Loads placed on the back can be transmitted directly to the ground through this frame. Redistributing loads through the exoskeleton may help prevent chronic musculoskeletal injuries in those who carry heavy loads; however, the UPRISE’s passive joints are not able to assist in moving the limbs. As a result, the wearer’s muscles must still be used to move and stabilize their own joints as well as those of the exoskeleton, so it is unclear if these devices are able to reduce the metabolic cost of walking under a load.

Some hard passive devices have been designed for clinical applications. The iWalk (iWALKFree, Long Beach, CA) (iWalkFree, 2021) allows the person to walk with a tibia, foot, or ankle fracture by re-directing loads from the ground to the distal end of the femur/knee and the anterior surface of the shank (Martin et al., Reference Martin, Unangst, Huh and Chisholm2019). This design, while useful for restoring mobility after lower limb fracture, is bulky and increases the wearer’s profile by holding the knee flexed at ninety degrees. Navigating rugged terrain with the leg in this position may cause the foot to collide with or catch on obstacles like trees and rocks, which may exacerbate the injury. Additionally, this design may not be suitable for all lower leg injuries as loading the anterior surface of a fractured tibia may not always be feasible given the severity of tibia fractures from blast injuries. Another clinical device, the Intrepid Dynamic Exoskeletal Orthosis (IDEO), was designed to reduce debilitating ankle pain after limb salvage surgery. The IDEO is an Ankle Foot Orthosis (AFO), but features a much stiffer foot plate, an elastic strut, and a proximal cuff around the tibia. The IDEO stores energy from ankle motion during the midstance phase of gait and later returns that energy for push-off. The transfer of energy around the injured limb reduces joint forces within the ankle and reduces pain. The IDEO has enabled people with severe leg injuries to return to normal activities of daily living (including running); however, the stiff foot plate prevents the foot from conforming to uneven terrain. This lack of adaptability can hinder mobility in austere environments. In addition, the IDEO is custom made for each patient and the requirement for skilled personnel and manufacturing space would prohibit care at the point of injury.

Hard passive exoskeletons can also improve performance for healthy joints. The Collins/Sawicki exoskeleton is an articulated AFO with a posteriorly mounted spring that can store energy from dorsiflexion in midstance and release that energy during plantarflexion in preswing (Collins et al., Reference Collins, Wiggin and Sawicki2015). A ratcheting mechanism can engage and disengage the spring so that the ankle is unencumbered during the swing phase of gait to promote toe clearance. By storing and releasing energy, the spring can replicate the function of the triceps surae muscles, which reduces muscle loads and metabolic energy costs. However, the spring and ratchet are optimized for ankle motion and loading on level ground. On uneven terrain, moving with the engaged spring could require more muscle effort and reduce the utility of the device in an austere environment. Additionally, the energy released by the spring is transmitted through the skeleton of the lower leg, which can exacerbate musculoskeletal injuries.

3. Mechanical considerations

To our knowledge, there is not a commercially available exoskeleton suited for the unique problem of enabling someone to walk independently with a lower leg fracture in an austere environment. Given their relative advantages in portability, maintainability, and durability, hard passive exoskeletons are likely the best archetype to base designs on. The biggest weakness of these designs is their limited adaptability for variable terrain. However, the human body has multiple degrees of freedom (Latash, Reference Latash2012), so constraining or limiting a joint does not necessarily prevent the person from being able to adapt to the landscape. Effective designs for PFC must strike a balance between stabilizing joints and the fracture to prevent exacerbating injuries while minimizing degree of freedom constraints that enable navigation over varied terrain.

Hard active devices may become more viable in the future; however, more work is required to improve their control. Experience with the HULC has demonstrated the need for improving the powered exoskeleton controller so that the wearer and device move synergistically (Li et al., Reference Li, Cheng, Liu, Zhang and Wang2018). This problem is not trivial (Stirling et al., Reference Stirling, Kelty-Stephen, Fineman, Jones, Park, Reed, Parham and Choi2020) and will be further compounded by the user’s injury, which will alter their capacity to control the exoskeleton. Some work has shown that adaptive oscillator controllers can be used to reduce forces between the user and the orthosis even for irregular gait patterns (Ishmael et al., Reference Ishmael, Archangeli and Lenzi2021; Yang et al., Reference Yang, Xu, Yu, Chen and Yang2021). These oscillators learn the periodic motion of the wearer’s gait and can identify what point the wearer is at within the gait cycle. Using that information, the controller can provide properly timed assistive torques to move the limb. Such controllers have even demonstrated a reduction in energy cost for walking with a prosthesis. While these developments are encouraging, the devices need to be tuned to the individual wearer, which currently requires time and a trained technician. Service members in austere environments may not have the time or space for a controller to learn their gait, and training field medical personnel how to tune a niche technical device can overburden an already overwhelming cognitive load from all the other life-saving measures and techniques they need to know. Controllers can be tuned automatically, but this requires even more time and current tuning algorithms may not work for non-able-bodied individuals.

Improving the control of hard-active systems would also maximize their key advantage over passive systems: adapting across multi-modal terrain. This requires a control system capable of shaping the exoskeleton assistance appropriately across a diverse set of activities. This has been a concentrated research area over the last decade which include direct estimation of environmental state through techniques including heuristic state machine logic (Stolyarov et al., Reference Stolyarov, Carney and Herr2021) to machine learning activity patterns (Laschowski et al., Reference Laschowski, McNally, Wong and McPhee2021; Kang et al., Reference Kang, Molinaro, Choi, Camargo and Young2022; Wang et al., Reference Wang, Wu, Gao, Wang, Li, Xu and Dong2022). Alternatively, control strategies have also been formulated to provide task-invariant capability such as through myoelectric control (Nasr et al., Reference Nasr, Laschowski and McPhee2021) or energy-shaping techniques (Lin et al., Reference Lin, Divekar, Lv and Gregg2021). However, these studies have typically been carried out in laboratory environments with flat, hard ground which is not representative of terrain encountered in austere environments. Environmental recognition for austere conditions needs to include uneven, rocky, sandy, grassy, non-level, wet, and/or compliant surfaces. This problem has not yet been seriously studied for recognition and control for autonomous exoskeleton systems and needs further research before system deployment is possible. However, mobile robotic systems and machine vision systems (Riopelle et al., Reference Riopelle, Caspers and Sofge2018) have made progress in this domain and offer promising potential methods for translating to exoskeleton systems for austere environmental recognition.

Work should also be done on reducing reliance on external power to increase the efficacy of active devices in austere environments. Quasi-passive devices (Orendurff et al., Reference Orendurff, Segal, Klute, McDowell, Pecoraro and Czerniecki2006; Shepherd and Rouse, Reference Shepherd and Rouse2017) have the potential to reduce these energy requirements and help exoskeletons last longer in austere environments while using smaller and lighter power sources. These devices use actuators to modulate passive components such as springs or dampers, which in turn control the power transmitted across a joint. The actuators consume less power while providing some of the adaptability found in active exoskeletons. These techniques are already used in commercial prostheses that actively alter damping, such as the C-leg by Ottobock, and are being explored in other prosthetic applications (Orendurff et al., Reference Orendurff, Segal, Klute, McDowell, Pecoraro and Czerniecki2006). Regenerative braking is another possibility for improving active exoskeletons’ maintainability by using energy that is normally dissipated during walking to recharge batteries (Laschowski et al., Reference Laschowski, McPhee and Andrysek2019), and is already being implemented in exoskeletons such as the Amplify (Bionic Power, Vancouver, Canada). These techniques can also contribute to exoskeleton adaptability by modulating joint power while extending battery life.

Effective PFC exoskeletons will also have to balance durability with portability. Designs need to be strong enough to withstand repeated impacts from walking and/or falling, but still be light and small enough to fit inside a backpack or they will not be fielded. Materials with high strength-to-weight ratios will be important to satisfy both conditions, and designs should concentrate bulk in regions that will experience high levels of mechanical stress while minimizing material where little stress exists. In this way, designs can be optimized to provide sufficient strength while maintaining low weight and volume. Titanium is an excellent candidate with the highest strength-to-weight ratios among metals (219 kNm/kg) (Aerospace Specification Metals [1], 2022) and good biocompatibility (Court-Brown et al., Reference Court-Brown, Heckman, McQueen, Ricci, Tornetta and McKee2015). Aluminum is another viable option; although, it is not as strong as Titanium (102 kNm/kg) (Aerospace Specification Metals [2], 2022). Aluminum is lightweight and is used in a variety of clinical applications for transporting the injured including crutches and litters. Carbon fiber composites have an even higher strength-to-weight ratio than Titanium alloys (356 kNm/kg) (Performance Composites, 2009) and are already used in custom prosthetic and orthotic components. Pre-pregnated carbon fiber is optimized to use the least amount of resin so that the resulting structures are as lightweight as possible without compromising strength. While carbon fiber composites seem to be the most desirable option, second-order effects such as environmental hazards or material and manufacturing costs may make other materials more feasible.

Interfacing with the human body will also be a challenge. Loads will have to be transferred around the injury site to more proximal regions of the user, but not all parts of the body are suited to bear weight. An effective device will interface with areas that can tolerate pressure and shear to minimize discomfort. Prosthetists and orthotists face these challenges daily, and the techniques they use can greatly inform exoskeleton designs. However, prosthetists and orthotists often manage pressure and shear by custom fitting devices to their wearers, which will not work for a one-size-fits-most exoskeleton. Future work should focus on generalizing prosthetic and orthotic principles to ensure that a broad range of different-sized first-responders, wilderness enthusiasts, and Service members can use the device without causing serious injury to the skin and other soft tissues at the user interface. Finite element modeling of human tissues over regions traditionally used by prosthetists and orthotists for loading could shed insight as to the forces and pressure different designs would apply to the skin during ambulation (Panagiotopoulou, Reference Panagiotopoulou2009; Steer et al., Reference Steer, Worsley, Browne and Dickinson2020). Designs can then be optimized for minimizing dangerous shear forces.

Not only should the devices be able to interface with different-sized wearers, it should also be quick to don. While field care on the battlefield conjures images of treatment under fire, these exoskeletons will likely be applied to the wearer under less urgent conditions. Field care under pressure often focuses on life-saving measures like preventing mass hemorrhages and making sure the patient can breathe until hostile threats have been contained. Once an area has been secured and patients have been stabilized, field care personnel will have the opportunity to treat less urgent injuries, such as fractures. Field care personnel would benefit from devices that can be quickly applied because they may have many patients and a finite amount of time to treat them. If the exoskeleton cannot be applied quickly, it may not be applied at all.

While the need for portability, maintainability, adaptability, and durability have been identified for exoskeletons designed for prolonged care, many explicit design specifications are currently unknown due to the novelty and uniqueness of the problem. Future work should also focus on establishing standards for designs. These standards need to consider not only the environmental and loading conditions the devices will experience, but also the human factors associated with their function. Exoskeletons need to satisfy the needs of the casualty who will be ambulating with them and the field care personnel who will be carrying and applying the device.

4. Clinical considerations

A successful PFC exoskeleton design will enable a person to evacuate safely from an austere environment; however, attention should also be given to field care treatments that will optimize healing outcomes as early after injury as possible. Ideal orthopedic care will never be realized in a PC scenario. The nature of PC may require mobility of the injured to be prioritized for survival, even to the detriment of the injured limb at times. However, there are opportunities for exoskeletal technologies to preserve and protect the limb so that the definitive treatments they receive after medical evacuation will have better outcomes. Bone fractures all require an appropriate bio-mechanochemical environment to achieve appropriate fracture healing over the course of several weeks to months (Court-Brown et al., Reference Court-Brown, Heckman, McQueen, Ricci, Tornetta and McKee2015). Creating this environment usually requires maintaining the proper spacing, orientation, and alignment of the bone segments, often through immobilizing and offloading the fracture site (Sarmiento et al., Reference Sarmiento, Schaeffer, Beckerman, Latta and Enis1977). Even though field medical personnel may likely not be able to properly align and set the bone segments in the field or surgically apply internal or external fixators, an exoskeleton should be able to stabilize and offload the fracture site to prevent further damage to tissues. Fracture orthoses like the Air Cam Walker Boot (Orthotronix, Las Vegas, NV) were designed to stabilize and offload lower leg injuries; however, they are too bulky to fit in a pack, and multiple sizes would have to be carried to make sure most Service members could be treated. Additionally, severe trauma could alter the shape and volume of the leg so that it no longer fits securely in the device. Casting technologies such as plaster, fiberglass, and even spray foam (Martin et al., Reference Martin, Unangst and Chisholm2019) are more portable technologies that could accommodate limbs of all shapes and size. However, in the case of severe open fractures (e.g., Gustilo type II/III), wound contamination and soft tissue comorbidities (e.g., volumetric muscle loss, nerve injury, vascular injury) and complications (e.g., compartment syndrome or infection) will require other care in addition to stabilizing the fracture. Not only should the exoskeleton not cause further harm to the injured tissues, but it also must not interfere with vital medical treatments such as bandaging, controlling bleeding, irrigating wounds, administering local antibiotics, providing analgesia, and other adjunctive soft tissue therapies. In light of these considerations, semi-permanent solutions like casts would prevent access to the wound and complicate the treatment of damaged soft tissues around the fracture. Fracture stabilization devices must be readily removable and conformable to the limb to increase the probability of the individual’s survival while preserving limb health until the injured can receive definitive treatment at a fixed medical facility.

Going beyond merely not interfering with medical treatment, exoskeletons could incorporate elements that act synergistically with therapeutics to enhance fracture and soft tissue wound healing at the tissue level. Mechanisms that could convert the kinetic energy associated with locomotion into a positive stimulus for wound healing may enable innovation. Surprisingly, one potential mechanism for imparting a stimulus on the wound is mechanical loading. According to Wolff’s law, mechanical strain can lead to bone growth (Meyer, Reference Meyer1867). Exoskeletal mediated fine tuning of the mechanical load and micromotions experienced at the fracture site may help with intramembranous and endochondral bone formation (Yamaji et al., Reference Yamaji, Ando, Wolf, Augat and Claes2001). Furthermore, since electric fields can also stimulate bone regeneration (Rajabi et al., Reference Rajabi, Jaffe and Arinzeh2015), piezoelectric materials that produce an electric field in response to mechanical load could also be included to enhance healing (Jacob et al., Reference Jacob, More, Kalia and Kapusetti2018). The main challenge for this approach is the sensitivity of healing to the magnitude, rate, and timing of mechanical load. If done inappropriately, this could lead to delayed healing. As such, the mechanism for fine tuning an exoskeleton to provide precise loads across a fracture would need to be robust enough so as not to risk promoting adverse healing outcomes if applied suboptimally, particularly in austere environments associated with PFC.

Another opportunity for converting locomotive kinetic energy from the exoskeleton to enhance wound healing may lie in the incorporation of positive displacement pumps for applying negative pressure to an open fracture wound. Most open fracture wound sites are contaminated and closure would not be attempted in a PFC environment. As such, management of this open wound to prevent progression to deep infection and biofilm formation is paramount to achieving positive fracture healing outcomes. Negative pressure wound therapy has been clinically demonstrated to reduce the risk of deep infection after open fracture (Blum et al., Reference Blum, Esser, Richardson, Paul and Rosenfeldt2012) by using suction and wound dressing to remove infectious material and wound exudate. While this approach would vary procedurally relative to what is done at fixed medical facilities, the approach could plausibly provide therapeutic levels of pulsatile vacuum (~125 mmHG) to help curtail infection and better position the wound for definitive treatment and thus increase the probability of positive surgical outcomes after a successful medical evacuation.

Wearable devices for monitoring the wound environment (e.g., pH, pressure, temperature sensors) represent another prime opportunity for innovation in the design of exoskeletons for PFC of extremity fractures. Assessment and monitoring is an essential part of the clinical management of open wounds that traditionally require visual evaluation of the wound for a number of parameters. This visual evaluation would require the removal and reapplication of wound dressings, an approach that is not well suited to the low-resource environments where the availability of fresh, replacement dressings may be limited. As such, devices that incorporate low-powered wearable sensors capable of providing information on the wound environment in real time would be of great value and could amplify the value of telemedicine consults in guiding treatment decisions and/or emergent surgical procedures.

5. Conclusion

Helping people with acute lower leg injuries independently navigate austere environments on foot is a unique challenge but is important for the preservation of life in both peacetime and war. Assistive exoskeletal devices are a promising solution. Currently, most commercially available devices cannot effectively operate under the special conditions imposed by austere environments. Although some designs have features that would be useful, they do not completely satisfy the need for portability, durability, maintainability, and adaptability. Modifying hard passive exoskeletons for this unique application is an attractive option as they can bear compressive loads while still being portable, durable, and maintainable. The potential adaptability inherent to hard active exoskeletons is desirable for the varied and unpredictable terrain found in austere environments, but the added complexity, bulk, and energy demands from the actuators, controllers, and power sources limit their ability to reach the point of injury and remain operational until the wearer can be safely evacuated. Ongoing work in reducing the power consumption and improving the control of these exoskeletons will help them become more effective solutions in the field. Future work can also focus on incorporating technologies that will promote healing and preserve limb health so that users have a better chance of recovering limb functionality after receiving definitive medical care. In the meantime, hard passive exoskeletons can be modified to meet the mechanical and clinical requirements of ambulating with an injured limb in an austere environment.

Acknowledgments

The views expressed herein are those of the authors and do not reflect the official policy or position of Brooke Army Medical Center, the U.S. Army Medical Department, the U.S. Army Office of the Surgeon General, the Department of the Army, the Department of the Air Force, the Defense Health Agency, or the Department of Defense, or the U.S. Government. Illustrations courtesy of Erica Lee Vasquez and Brooke Army Medical Center’s Electronic Multimedia Imaging Center.

Data Availability Statement

Data sharing is not applicable to this article as no new data were created or analyzed in this study.

Authorship Contributions

W.B.J. contributed to the hard passive and mechanical considerations sections of the article and harmonized the different contributions from the authors into a single article. A.Y. contributed to the hard active section and final edits. S.G. contributed to the clinical considerations section as well as the introduction. J.W. contributed his experiences as a US Air Force Pararescueman in framing the rationale for this paper as well as writing the introduction and final edits. J.F.A. contributed his experiences as a US Army surgeon in writing the clinical considerations section. W.L.C. formulated the core ideas for this paper and assembled the team of authors. He contributed to the introduction and made the final edits on the paper.

Funding Statement

This paper is part of a project funded by the US Army Medical Research and Development Command (USAMRDC) Combat Casualty Care Research Program (CCCRP) Proposal #CO210052.

Competing Interests

The authors declare no competing interests exist.

References

Aerospace Specification Metals [1] (2022) ASM Material Data Sheet. Accessed on 1/9/2023. Available at https://asm.matweb.com/search/SpecificMaterial.asp?bassnum=mtp641.Google Scholar
Aerospace Specification Metals [2] (2022) ASM Material Data Sheet. Accessed on 1/9/2023. Available at https://asm.matweb.com/search/SpecificMaterial.asp?bassnum=MA6061t6.Google Scholar
Anagnostou, E, Michas, A and Giannou, C (2020) Practicing military medicine in truly austere environments: What to expect, how to prepare, when to improvise. Military Medicine 185(5–6), e656e661. https://doi.org/10.1093/milmed/usz467CrossRefGoogle ScholarPubMed
Army Technology (2020) Human Universal Load Carrier (HULC). New York, New York: Army Technology. Accessed on 1/9/2023. Available at https://www.army-technology.com/projects/human-universal-load-carrier-hulc/.Google Scholar
Belmont, PJ, Schoenfeld, AJ and Goodman, G (2010) Epidemiology of combat wounds in operation Iraqi freedom and operation enduring freedom: Orthopaedic burden of disease. Journal of Surgical Orthopaedic Advances 19(1), 27.Google ScholarPubMed
Belmont, PJ, Thomas, D, Goodman, GP, Schoenfeld, AJ, Zacchilli, M, Burks, R and Owens, BD (2011) Combat musculoskeletal wounds in a US Army brigade combat team during operation Iraqi freedom. The Journal of Trauma 71(1), E1E7. https://doi.org/10.1097/TA.0b013e3181edebedGoogle Scholar
Blum, ML, Esser, M, Richardson, M, Paul, E and Rosenfeldt, FL (2012) Negative pressure wound therapy reduces deep infection rate in open tibial fractures. Journal of Orthopaedic Trauma 26(9), 499505. https://doi.org/10.1097/BOT.0b013e31824133e3CrossRefGoogle ScholarPubMed
Bogue, R (2015) Robotic exoskeletons: A review of recent progress. Industrial Robot: An International Journal 42(1), 510. https://doi.org/10.1108/IR-08-2014-0379CrossRefGoogle Scholar
Cardona, M, García Cena, CE, Serrano, F and Saltaren, R (2020) ALICE: Conceptual development of a lower limb exoskeleton robot driven by an on-board musculoskeletal simulator. Sensors 20(3), 789.CrossRefGoogle ScholarPubMed
Chu, A, Kazerooni, H and Zoss, A (2005) On the biomimetic design of the Berkeley lower extremity exoskeleton (BLEEX). In Paper presented at the IEEE International Conference on Robotics and Automation. New York, NY: IEEE.Google Scholar
Collins, SH, Wiggin, MB and Sawicki, GS (2015) Reducing the energy cost of human walking using an unpowered exoskeleton. Nature 522(7555), 212215. https://doi.org/10.1038/nature14288CrossRefGoogle ScholarPubMed
Court-Brown, CM, Heckman, JD, McQueen, MM, Ricci, WM, Tornetta, P and McKee, MD (2015) Rockwood and Green’s Fractures in Adults, 8th Edn. Baltimore, MD: Wolters Kluwer.Google Scholar
Diamond-Ouellette, G, Telonia, A, Blanchette, M, Crocker, J, Bouyer, L and Best, K (2020) Investigating the change in energy expenditure before and after familiariztion with a passive load-bearing exoskeleton: A case series. In Paper Presented at the 5th International Congress on Soldiers Physical Performance, Quebec, Canada. Quebec, Canada: Department of National Defense of Canada.Google Scholar
Ding, Y, Kim, M, Kuindersma, S and Walsh, CJ (2018) Human-in-the-loop optimization of hip assistance with a soft exosuit during walking. Science Robotics 3(15), eaar5438.CrossRefGoogle ScholarPubMed
Dollar, A and Herr, H (2008) Lower extremity exoskeletons and active orthoses: Challenges and state-of-the-art. IEEE Transactions on Robotics 24(1), 144158.CrossRefGoogle Scholar
Dougherty, AL, Mohrle, CR, Galarneau, MR, Woodruff, SI, Dye, JL and Quinn, KH (2009) Battlefield extremity injuries in operation Iraqi freedom. Injury 40(7), 772777. https://doi.org/10.1016/j.injury.2009.02.014CrossRefGoogle ScholarPubMed
Douglas, R, Larson, PF, D’Ambrosia, R and McCall, RE (1983) The LSU reciprocation-gait orthosis. Orthopedics 6(7), 834839. https://doi.org/10.3928/0147-7447-19830701-05CrossRefGoogle ScholarPubMed
Ekso Bionics East (2020) Personal Use|Indego Exoskeleton. Ekso Bionics East, Macedonia, OH: Indego. Available at https://www.indego.com/indego/us/en/indego-personal. Accessed 1/9/2023.Google Scholar
Farris, RJ, Quintero, HA, Murray, SA, Ha, KH, Hartigan, C and Goldfarb, M (2014) A preliminary assessment of legged mobility provided by a lower limb exoskeleton for persons with paraplegia. IEEE Transactions on Neural Systems and Rehabilitation Engineering 22(3), 482490. https://doi.org/10.1109/TNSRE.2013.2268320CrossRefGoogle ScholarPubMed
Franklin, N, Hsu, JR, Wilken, J, McMenemy, L, Ramasamy, A and Stinner, DJ (2019) Advanced functional bracing in lower extremity trauma: Bracing to improve function. Sports Medicine and Arthroscopy Review 27(3), 107111. https://doi.org/10.1097/jsa.0000000000000259CrossRefGoogle ScholarPubMed
Ghan, J, Steger, R and Kazerooni, H (2006) Control and system identification for the Berkeley lower extremity exoskeleton (BLEEX). Advanced Robotics 20(9), 9891014.CrossRefGoogle Scholar
Gregorczyk, KN, Hasselquist, L, Schiffman, JM, Bensel, CK, Obusek, JP and Gutekunst, DJ (2010) Effects of a lower-body exoskeleton device on metabolic cost and gait biomechanics during load carriage. Ergonomics 53(10), 12631275.CrossRefGoogle ScholarPubMed
Gruevski, KM, Cameron, IJ, McGuinness, C, Sy, A, Best, KL, Bouyer, L, Diamond-Ouellette, G, Graham, RB and Karakolis, T (2020) A pilot investigation of the influence of a passive military exoskeleton on the performance of lab-simulated operational tasks. IISE Transactions on Occupational Ergonomics and Human Factors 8(4), 195203. https://doi.org/10.1080/24725838.2021.1912852CrossRefGoogle ScholarPubMed
Ishmael, MK, Archangeli, D and Lenzi, T (2021) Powered hip exoskeleton improves walking economy in individuals with above-knee-amputation. Nature Medicine 27, 17821788.CrossRefGoogle ScholarPubMed
iWalkFree (2021). iWALK3.0 Product Specifications. Accessed on 1/9/2023. Available at https://iwalk-free.com/specifications/.Google Scholar
Jacob, J, More, N, Kalia, K and Kapusetti, G (2018) Piezoelectric smart biomaterials for bone and cartilage tissue engineering. Inflammation and Regeneration 38(1), 2. https://doi.org/10.1186/s41232-018-0059-8CrossRefGoogle ScholarPubMed
Juszczak, M, Gallo, E and Bushnik, T (2018) Examining the effects of a powered exoskeleton on quality of life and secondary impairments in people living with spinal cord injury. Topics in Spinal Cord Injury Rehabilitation 24(4), 336342. https://doi.org/10.1310/sci17-00055CrossRefGoogle ScholarPubMed
Kang, I, Molinaro, D, Choi, G, Camargo, J and Young, A (2022) Subject-independent continuous locomotion mode classification for robotic hip exoskeleton applications. IEEE Transactions on Biomedical Engineering 69, 32343242. https://doi.org/10.1109/TBME.2022.3165547CrossRefGoogle ScholarPubMed
Kang, I, Molinaro, D, Choi, G and Young, A (2020) Continuous locomotion mode classification using a robotic hip exoskeleton. In Paper presented at the IEEE RAS/EMBS International Conference on Biomedical Robotics and Biomechatronics, New York, NY: IEEE.Google Scholar
Karlberg, CEJ (2016) Strategic Training Management: Training to Win in a Complex World. U.S. Army War College: Carlisle, PA.Google Scholar
Kazerooni, H (2008) Exoskeletons for human performance augmentation. In Springer Handbook of Robotics. Berlin: Springer, pp. 773793.CrossRefGoogle Scholar
Keenan, S (2015) Deconstructing the definition of prolonged field care. Journal of Special Operations Medicine 15(4), 125.CrossRefGoogle ScholarPubMed
Keenan, S and Riesberg, JC (2017) Prolonged field care: Beyond the “golden hour”. Wilderness & Environmental Medicine 28(2s), S135S139. https://doi.org/10.1016/j.wem.2017.02.001CrossRefGoogle ScholarPubMed
Kolakowsky-Hayner, SA, Crew, J, Moran, S and Shah, A (2013) Safety and feasibility of using the EksoTM bionic exoskeleton to aid ambulation after spinal cord injury. Journal of Spine 4, 18.Google Scholar
Kotwal, RS, Howard, JT, Orman, JA, Tarpey, BW, Bailey, JA, Champion, HR, Mabry, RL, Holcomb, JB, and Gross, KR. (2016) The effect of a Golden hour policy on the morbidity and mortality of combat casualties. JAMA Surgery 151(1), 1524. https://doi.org/10.1001/jamasurg.2015.3104CrossRefGoogle ScholarPubMed
Laschowski, B, McNally, W, Wong, A and McPhee, J (2021) Computer vision and deep learning for environment-adaptive control of robotic lower-limb exoskeletons. In 43rd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC), New York, NY: IEEE, pp. 46314635. https://doi.org/10.1109/EMBC46164.2021.9630064CrossRefGoogle Scholar
Laschowski, B, McPhee, J and Andrysek, J (2019) Lower-limb prostheses and exoskeletons with energy regeneration: Mechatronic design and optimization review. Journal of Mechanisms and Robotics 11(4): 040801040808. https://doi.org/10.1115/1.4043460CrossRefGoogle Scholar
Latash, ML (2012) The bliss (not the problem) of motor abundance (not redundancy). Experimental Brain Research 217(1), 15. https://doi.org/10.1007/s00221-012-3000-4CrossRefGoogle ScholarPubMed
Lenzi, T, Carrozza, MC and Agrawal, SK (2013) Powered hip exoskeletons can reduce the user’s hip and ankle muscle activations during walking. IEEE Transactions on Neural Systems and Rehabilitation Engineering 21(6), 938948.CrossRefGoogle ScholarPubMed
Li, H, Cheng, W, Liu, F, Zhang, M and Wang, K (2018) The effects on muscle activity and discomfort of varying load carriage with and without an augmentation exoskeleton. Applied Sciences 8(12), 2638.CrossRefGoogle Scholar
Lin, J, Divekar, NV, Lv, G and Gregg, RD (2021) Optimal task-invariant energetic control for a knee-ankle exoskeleton. IEEE Control Systems Letters 5(5), 50295034. https://doi.org/10.23919/ACC50511.2021.9483212CrossRefGoogle Scholar
MacLean, MK and Ferris, DP (2019) Energetics of walking with a robotic knee exoskeleton. Journal of Applied Biomechanics 35(5), 320326.CrossRefGoogle ScholarPubMed
Martin, KD, Unangst, A and Chisholm, J (2019) Fracture immobilization in an austere environment: A comparative study of military special operations medical personnel using a SAM splint vs a one-step spray on foam. Foot & Ankle Orthopaedics 4(4), 2473011419S00297.CrossRefGoogle Scholar
Martin, KD, Unangst, AM, Huh, J and Chisholm, J (2019) Patient preference and physical demand for hands-free single crutch vs standard axillary crutches in foot and ankle patients. Foot & Ankle International 40(10), 12031208. https://doi.org/10.1177/1071100719862743CrossRefGoogle ScholarPubMed
Meyer, GH (1867) Die Architektur der Spongiosa. Archiv fur Anatomie Physiologie und Wissenschaftliche Medicin 34, 615628.Google Scholar
Mohr, CJ and Keenan, S (2015) Prolonged field care working group position paper: Operational context for prolonged field care. Journal of Special Operations Medicine 15(3), 7880.CrossRefGoogle Scholar
Mooney, LM and Herr, HM (2016) Biomechanical walking mechanisms underlying the metabolic reduction caused by an autonomous exoskeleton. Journal of Neuroengineering and Rehabilitation 13(1), 1.CrossRefGoogle ScholarPubMed
Mooney, L, Rouse, E and Herr, H (2014) Autonomous exoskeleton reduces metabolic cost of human walking during load carriage. Journal of Neuroengineering and Rehabilitation 11(1), 80.CrossRefGoogle ScholarPubMed
Mooney, LM, Rouse, EJ and Herr, HM (2014) Autonomous exoskeleton reduces metabolic cost of human walking. Journal of Neuroengineering and Rehabilitation 11(1), 16.Google ScholarPubMed
Mudie, K, Billing, D, Garofolini, A, Karakolis, T and LaFiandra, M (2022) The need for a paradigm shift in the development of military exoskeletons. European Journal of Sport Science 22, 3542. https://doi.org/10.1080/17461391.2021.1923813CrossRefGoogle ScholarPubMed
Nasr, A, Laschowski, B and McPhee, J (2021) Myoelectric control of robotic leg prostheses and exoskeletons: A review. In Proceedings of the ASME 2021 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. Volume 8A: 45th Mechanisms and Robotics Conference (MR). Virtual, Online. August 17–19, 2021. V08AT08A043. New York, NY: ASME. https://doi.org/10.1115/DETC2021-69203Google Scholar
Orendurff, MS, Segal, AD, Klute, GK, McDowell, ML, Pecoraro, JA and Czerniecki, JM (2006) Gait efficiency using the C-leg. Journal of Rehabilitation Research and Development 43(2), 239246. https://doi.org/10.1682/jrrd.2005.06.0095CrossRefGoogle ScholarPubMed
Owens, BD, Kragh, JF Jr, Macaitis, J, Svoboda, SJ and Wenke, JC (2007) Characterization of extremity wounds in operation Iraqi freedom and operation enduring freedom. Journal of Orthopaedic Trauma 21(4), 254257. https://doi.org/10.1097/BOT.0b013e31802f78fbCrossRefGoogle ScholarPubMed
Panagiotopoulou, O (2009) Finite element analysis (FEA): Applying an engineering method to functional morphology in anthropology and human biology. Annals of Human Biology 36(5), 609623. https://doi.org/10.1080/03014460903019879CrossRefGoogle ScholarPubMed
Performance Composites (2009) Mechanical Properties of Carbon Fibre Composite Materials. Accessed on 1/9/2023. Available at http://www.performance-composites.com/carbonfibre/mechanicalproperties_2.asp.Google Scholar
Rajabi, AH, Jaffe, M and Arinzeh, TL (2015) Piezoelectric materials for tissue regeneration: A review. Acta Biomaterialia 24, 1223. https://doi.org/10.1016/j.actbio.2015.07.010CrossRefGoogle ScholarPubMed
Riopelle, N, Caspers, P and Sofge, D (2018) Terrain classification for autonomous vehicles using bat-inspired echolocation. In International Joint Conference on Neural Networks (IJCNN), pp. 16. https://doi.org/10.1109/IJCNN.2018.8489046CrossRefGoogle Scholar
Sarmiento, A, Schaeffer, JF, Beckerman, L, Latta, LL and Enis, JE (1977) Fracture healing in rat femora as affected by functional weight-bearing. The Journal of Bone and Joint Surgery American 59(3), 369375.CrossRefGoogle ScholarPubMed
Sawicki, GS, Beck, O, Kang, I and Young, A (2020) The exoskeleton expansion: Improving walking and running economy. Journal of Neuroengineering and Rehabilitation 17(1), 19.CrossRefGoogle ScholarPubMed
Schiffman, JM, Gregorczyk, KN, Bensel, CK, Hasselquist, L and Obusek, JP (2008) The effects of a lower body exoskeleton load carriage assistive device on limits of stability and postural sway. Ergonomics 51(10), 15151529.CrossRefGoogle ScholarPubMed
Schoenfeld, AJ, Dunn, JC, Bader, JO and Belmont, PJ (2013) The nature and extent of war injuries sustained by combat specialty personnel killed and wounded in Afghanistan and Iraq, 2003-2011. Journal of Trauma and Acute Care Surgery 75(2), 287291. https://doi.org/10.1097/TA.0b013e31829a0970CrossRefGoogle ScholarPubMed
Seo, K, Lee, J, Lee, Y, Ha, T and Shim, Y (2016) Fully autonomous hip exoskeleton saves metabolic cost of walking. In Paper presented at 2016 IEEE International Conference on Robotics and Automation (ICRA). New York, NY: IEEE, pp. 46284635, doi: 10.1109/ICRA.2016.7487663.CrossRefGoogle Scholar
Shepherd, MK and Rouse, EJ (2017) The VSPA foot: A quasi-passive ankle-foot prosthesis with continuously variable stiffness. IEEE Transactions on Neural Systems and Rehabilitation Engineering 25(12), 23752386. https://doi.org/10.1109/TNSRE.2017.2750113CrossRefGoogle Scholar
Soteras, I, Subirats, E and Strapazzon, G (2015) Epidemiological and medical aspects of canyoning rescue operations. Injury 46(4), 585589. https://doi.org/10.1016/j.injury.2014.12.030CrossRefGoogle ScholarPubMed
Steer, JW, Worsley, PR, Browne, M and Dickinson, AS. (2020) Predictive prosthetic socket design: Part 1—Population-based evaluation of transtibial prosthetic sockets by FEA-driven surrogate modelling. Biomechanics and Modeling in Mechanobiology, 19, 13311346. https://doi.org/10.1007/s10237-019-01195-5CrossRefGoogle ScholarPubMed
Stella-Watts, AC, Holstege, CP, Lee, JK and Charlton, NP (2012) The epidemiology of caving injuries in the United States. Wilderness & Environmental Medicine 23(3), 215222. https://doi.org/10.1016/j.wem.2012.03.004CrossRefGoogle ScholarPubMed
Stirling, L, Kelty-Stephen, D, Fineman, R, Jones, MLH, Park, B-KD, Reed, MP, Parham, J and Choi, HJ. (2020) Static, dynamic, and cognitive fit of exosystems for the human operator. Human Factors 62(3), 424440. https://doi.org/10.1177/0018720819896898CrossRefGoogle ScholarPubMed
Stolyarov, R, Carney, M and Herr, H (2021) Accurate heuristic terrain prediction in powered lower-limb prostheses using onboard sensors. IEEE Transactions on Biomedical Engineering 68(2), 384392. https://doi.org/10.1109/TBME.2020.2994152CrossRefGoogle ScholarPubMed
Ströhle, M, Beeretz, I, Rugg, C, Woyke, S, Rauch, S and Paal, P (2020) Canyoning accidents in Austria from 2005 to 2018. International Journal of Environmental Research and Public Health 17(1), 102.CrossRefGoogle Scholar
US Department of the Army (2011) Causes of medical evacuations from Operations Iraqi Freedom (OIF). New Dawn (OND) and Enduring Freedom (OEF), active and reserve components, U.S. Armed Forces, October 2001–September 2010. MSMR 18(2), 27.Google Scholar
US Department of the Army (2016) The Warfighters’ Science and Technology Needs. Newport News, VA: Fort Eustis.Google Scholar
US Department of the Army (2018) The US Army in Multi-Domain Operations 2028. Newport News, VA: Fort Eustis.Google Scholar
Vélez-Guerrero, MA, Callejas-Cuervo, M and Mazzoleni, S (2021) Artificial intelligence-based wearable robotic exoskeletons for upper limb rehabilitation. A Review. Sensors 21(6), 2146.CrossRefGoogle ScholarPubMed
Venticinque, SG and Grathwohl, KW (2008) Critical care in the austere environment: Providing exceptional care in unusual places. Critical Care Medicine, 36(7 Suppl), S284S292. https://doi.org/10.1097/CCM.0b013e31817da8ecCrossRefGoogle ScholarPubMed
Wang, J, Wu, D, Gao, Y, Wang, X, Li, X, Xu, G and Dong, W (2022) Integral real-time locomotion mode recognition based on GA-CNN for lower limb exoskeleton. Journal of Bionic Engineering 19, 13591373. https://doi.org/10.1007/s42235-022-00230-zCrossRefGoogle Scholar
Weston, EB, Alizadeh, M, Knapik, GG, Wang, X and Marras, WS (2018) Biomechanical evaluation of exoskeleton use on loading of the lumbar spine. Applied Ergonomics 68, 101108. https://doi.org/10.1016/j.apergo.2017.11.006CrossRefGoogle ScholarPubMed
Wild, FJ (2008) Epidemiology of mountain search and rescue operations in Banff, Yoho, and Kootenay National Parks, 2003–06. Wilderness & Environmental Medicine, 19(4), 245251.CrossRefGoogle ScholarPubMed
Yamaji, T, Ando, K, Wolf, S, Augat, P and Claes, L (2001) The effect of micromovement on callus formation. Journal of Orthopaedic Science 6(6), 571575. https://doi.org/10.1007/s007760100014CrossRefGoogle ScholarPubMed
Yan, T, Cempini, M, Oddo, CM and Vitiello, N (2015) Review of assistive strategies in powered lower-limb orthoses and exoskeletons. Robotics and Autonomous Systems 64, 120136.CrossRefGoogle Scholar
Yang, W, Xu, LH, Yu, LF, Chen, YT and Yang, CJ (2021) Hybrid oscillator-based no-delay hip exoskeleton control for free walking assistance. Industrial Robot. 48(6), 906914.CrossRefGoogle Scholar
Young, A and Ferris, DP (2017) State-of-the-art and future directions for robotic lower limb exoskeletons. IEEE Transactions on Neural Systems and Rehabilitation Engineering 25(2), 171182. https://doi.org/10.1109/TNSRE.2016.2521160CrossRefGoogle Scholar
Zeilig, G, Weingarden, H, Zwecker, M, Dudkiewicz, I, Bloch, A and Esquenazi, A (2012) Safety and tolerance of the ReWalk™ exoskeleton suit for ambulation by people with complete spinal cord injury: A pilot study. The Journal of Spinal Cord Medicine 35(2), 101196.CrossRefGoogle ScholarPubMed
Zoss, AB, Kazerooni, H and Chu, A (2006) Biomechanical design of the Berkeley lower extremity exoskeleton (BLEEX). IEEE/ASME Transactions on Mechatronics 11(2), 128138.CrossRefGoogle Scholar
Figure 0

Figure 1. A fracture sustained in the field traditionally requires splinting to immobilize the limb and additional personnel are required to evacuate the wounded (a). Packable exoskeleton solutions may provide the opportunity for a person to remain mobile so that they can self-evacuate, or remain on mission (b).

Figure 1

Figure 2. Devices for stabilizing fractures in the field. (a) A Structural Aluminum Malleable (SAM) splint is a thin sheet of aluminum that can be folded to form a splint. (b) Rigid Immobilization System for Extremities (RISE) is a foldable plastic strip with snaps that allow it to form an ‘L’ shape; so that it can stabilize joints like the ankle or the elbow.

Figure 2

Figure 3. Exoskeletons that enable mobility for people with lower leg injuries. (a) Fracture Orthosis for ankle sprains and fractures (Orthotronix, Las Vegas, NV). (b) Intrepid Dynamic Exoskeletal Orthosis (IDEO) uses a stiff carbon fiber strut to offload the ankle joint, relieve pain, and improve functional control for people who underwent limb salvage surgery.

Figure 3

Table 1. Summary of essential criterion for medical exoskeletons in austere environments

Figure 4

Figure 4. Examples of hard active and hard passive exoskeletons performing different functions.