Discomfort/Pain and Tissue Oxygenation at the Lower Limb During Circumferential Compression: Application to Soft Exoskeleton Design

Objective To establish the relationship between circumferential compression on the lower limb during simulated ramp and staircase profile loading, and the resultant relationship with discomfort/pain and tissue oxygenation. Background Excessive mechanical loading by exoskeletons on the body can lead to pressure-related soft tissue injury. Potential tissue damage is associated with objective oxygen deprivation and accompanied by subjective perception of pain and discomfort. Method Three widths of pneumatic cuffs were inflated at the dominant thigh and calf of healthy participants using two inflation patterns (ramp and staircase), using a computer-controlled pneumatic rig. Participants rated discomfort on an electronic visual analog scale and deep tissue oxygenation was monitored using near infrared spectroscopy. Results Circumferential compression with pneumatic cuffs triggered discomfort and pain at lower pressures at the thigh, with wider cuffs, and with a ramp inflation pattern. Staircase profile compression caused an increase in deep tissue oxygenation, whereas the ramp profile compression decreased it. Conclusion Discomfort and pain during circumferential compression at the lower limb is related to the width of pneumatic cuffs, the inflation pattern, and the volume of soft tissue at the assessment site. The occurrence of pain is also possibly related to the decrease in deep tissue oxygenation during compression. Application Our findings can be used to inform safe and comfortable design of soft exoskeletons to avoid discomfort and possible soft tissue injury.

[1]  Morris F. Collen,et al.  Pain tolerance: differences according to age, sex and race. , 1972 .

[2]  Wenqi Shen,et al.  Validity and reliability of rating scales for seated pressure discomfort , 1997 .

[3]  M E Robinson,et al.  Temporal summation of second pain: Variability in responses to a fixed protocol , 2013, European journal of pain.

[4]  Lars Arendt-Nielsen,et al.  Cuff Pressure Pain Detection Is Associated with Both Sex and Physical Activity Level in Nonathletic Healthy Subjects , 2017, Pain medicine.

[5]  C. Ecoffey,et al.  Tourniquet pain in a volunteer study: effect of changes in cuff width and pressure , 2000, Anaesthesia.

[6]  C. Oomens,et al.  The etiology of pressure ulcers: skin deep or muscle bound? , 2003, Archives of physical medicine and rehabilitation.

[7]  S M Peirce,et al.  Ischemia‐reperfusion injury in chronic pressure ulcer formation: A skin model in the rat , 2008, Wound repair and regeneration : official publication of the Wound Healing Society [and] the European Tissue Repair Society.

[8]  Atilla Kilicarslan,et al.  Real-Time Strap Pressure Sensor System for Powered Exoskeletons , 2015, Sensors.

[9]  Shuping Xiong,et al.  An indentation apparatus for evaluating discomfort and pain thresholds in conjunction with mechanical properties of foot tissue in vivo. , 2010, Journal of rehabilitation research and development.

[10]  A. Gefen,et al.  Stress analyses coupled with damage laws to determine biomechanical risk factors for deep tissue injury during sitting. , 2009, Journal of biomechanical engineering.

[11]  Bader Dl,et al.  The recovery characteristics of soft tissues following repeated loading. , 1990 .

[12]  I. Demmelmaier,et al.  Long-term, health-enhancing physical activity is associated with reduction of pain but not pain sensitivity or improved exercise-induced hypoalgesia in persons with rheumatoid arthritis , 2018, Arthritis Research & Therapy.

[13]  Leonard O'Sullivan,et al.  Cuff Pressure Algometry in Patients with Chronic Pain as Guidance for Circumferential Tissue Compression for Wearable Soft Exoskeletons: A Systematic Review. , 2018, Soft robotics.

[14]  Antonio Bicchi,et al.  An atlas of physical human-robot interaction , 2008 .

[15]  J. Donofrio,et al.  Skin perfusion responses to surface pressure-induced ischemia: implication for the developing pressure ulcer. , 1999, Journal of rehabilitation research and development.

[16]  E. Heath Borg's Perceived Exertion and Pain Scales , 1998 .

[17]  Debby Gawlitta,et al.  Deep tissue injury: how deep is our understanding? , 2008, Archives of physical medicine and rehabilitation.

[18]  D L Bader,et al.  The recovery characteristics of soft tissues following repeated loading. , 1990, Journal of rehabilitation research and development.

[19]  C. Woolf,et al.  Central sensitization: a generator of pain hypersensitivity by central neural plasticity. , 2009, The journal of pain : official journal of the American Pain Society.

[20]  Jasper Reenalda,et al.  Clinical Use of Interface Pressure to Predict Pressure Ulcer Development: A Systematic Review , 2009, Assistive technology : the official journal of RESNA.

[21]  Robert G Radwin,et al.  Comparison of stoop versus prone postures for a simulated agricultural harvesting task. , 2007, Applied ergonomics.

[22]  P Buckle,et al.  Mattress evaluation--assessment of contact pressure, comfort and discomfort. , 1998, Applied ergonomics.

[23]  Lars Arendt-Nielsen,et al.  Spatial and temporal aspects of deep tissue pain assessed by cuff algometry , 2002, Pain.

[24]  M. Jensen,et al.  Interpretation of visual analog scale ratings and change scores: a reanalysis of two clinical trials of postoperative pain. , 2003, The journal of pain : official journal of the American Pain Society.

[25]  A F Mak,et al.  State-of-the-art research in lower-limb prosthetic biomechanics-socket interface: a review. , 2001, Journal of rehabilitation research and development.

[26]  L. Arendt-Nielsen,et al.  Tissue characteristics during temporal summation of pressure-evoked pain , 2012, Experimental Brain Research.

[27]  T. Graven-Nielsen,et al.  Cuff Algometry for Estimation of Hyperalgesia and Pain Summation , 2016, Pain medicine.

[28]  L. Stovner,et al.  Light-Induced Discomfort and Pain in Migraine , 1997, Cephalalgia : an international journal of headache.

[29]  Leonard O'Sullivan,et al.  Estimating upper limb discomfort level due to intermittent isometric pronation torque with various combinations of elbow angles, forearm rotation angles, force and frequency with upper arm at 90° abduction , 2007 .

[30]  Carlo Ferraresi,et al.  Increased tissue oxygenation explains the attenuation of hyperemia upon repetitive pneumatic compression of the lower leg. , 2017, Journal of applied physiology.

[31]  Valerie Power,et al.  Computerized Cuff Pressure Algometry as Guidance for Circumferential Tissue Compression for Wearable Soft Robotic Applications: A Systematic Review. , 2017, Soft robotics.

[32]  M. Camilleri,et al.  Functional gastroduodenal disorders , 1999, Gut.

[33]  M. Collen,et al.  Pain tolerance: differences according to age, sex and race K. M. Woodrow, G. D. Friedman, A. B. Siegelaub and M. F. Collen, Psychosom. Med., 34 (1972) 548–556 , 1972, PAIN.

[34]  Conor J. Walsh,et al.  Stronger, Smarter, Softer: Next-Generation Wearable Robots , 2014, IEEE Robotics & Automation Magazine.

[35]  A Gefen,et al.  Pressure ulcers and deep tissue injury: a bioengineering perspective. , 2007, Journal of wound care.

[36]  H Ashton,et al.  Effect of inflatable plastic splints on blood flow. , 1966, British medical journal.

[37]  J. Czerniecki,et al.  Circulatory and mechanical response of skin to loading , 1989, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[38]  Jose L Pons,et al.  Wearable Robots: Biomechatronic Exoskeletons , 2008 .

[39]  Edward S. Neumann,et al.  Measurement of Socket Discomfort—Part I: Pressure Sensation , 2001 .

[40]  Dan L. Bader,et al.  The importance of internal strain as opposed to interface pressure in the prevention of pressure related deep tissue injury. , 2010, Journal of tissue viability.

[41]  N. Talley,et al.  Nomenclature of dyspepsia, dyspepsia subgroups and functional dyspepsia: clarifying the concepts. , 1998, Bailliere's clinical gastroenterology.