Thermal modulation of skin friction at the fingertip

Preliminary human studies show that reduced skin temperature minimises the risk of mechanically-induced skin damage. However, the mechanisms by which cooling enhances skin tolerance to pressure and shear remain poorly understood. We hypothesized that skin cooling below thermo-neutral conditions will decrease friction at the skin-material interface. To test our hypothesis, we measured the friction coefficient of a thermally pre-conditioned index finger sliding at a normal load (5N) across a plate maintained at three different temperatures (38, 24, and 16□). To quantify the temperature distribution of the skin tissue, we used 3D surface scanning and Optical Coherence Tomography to develop an anatomically-representative thermal model of the finger. Our data indicated that the sliding finger with thermally affected tissues (up to 8mm depth) experienced significantly (p<0.01) lower frictional forces at 16°C-plate temperature than at the 24°C [-23% (±19% SD)] and 38°C plate interactions [-35% (±11% SD)], respectively. This phenomenon occurred without changes in skin hydration during sliding. Accordingly, our experiments demonstrate thermal modulation of skin friction in the absence of skin-moisture effects. Our complementary experimental and theoretical results provide new insight into thermal modulation of skin friction that can be employed for developing thermal technologies to maintain skin integrity under mechanical loading.

[1]  K. Rykaczewski,et al.  Analysis of thermocouple-based finger contact temperature measurements. , 2022, Journal of thermal biology.

[2]  J. Felts,et al.  Surface haptic rendering of virtual shapes through change in surface temperature , 2022, Science Robotics.

[3]  M. Cremonesi,et al.  Thermophysical and mechanical properties of biological tissues as a function of temperature: a systematic literature review , 2022, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[4]  D. Filingeri,et al.  The role of friction on skin wetness perception during dynamic interactions between the human index finger pad and materials of varying moisture content , 2022, Journal of neurophysiology.

[5]  Xuezhi Ma,et al.  Finger Pad Topography beyond Fingerprints: Understanding the Heterogeneity Effect of Finger Topography for Human-Machine Interface Modeling. , 2021, ACS applied materials & interfaces.

[6]  J. Guest,et al.  Cohort study evaluating the burden of wounds to the UK’s National Health Service in 2017/2018: update from 2012/2013 , 2020, BMJ Open.

[7]  C. Oomens,et al.  An evaluation of dermal microcirculatory occlusion under repeated mechanical loads: Implication of lymphatic impairment in pressure ulcers , 2020, Microcirculation.

[8]  Maohui Luo,et al.  High-density thermal sensitivity maps of the human body , 2020, Building and Environment.

[9]  Yih-Kuen Jan The effects of local cooling rates on perfusion of sacral skin under externally applied pressure in people with spinal cord injury: an exploratory study , 2019, Spinal Cord.

[10]  Ülkü Güneş,et al.  Sacral Skin Temperature and Pressure Ulcer Development: A Descriptive Study. , 2019, Wound management & prevention.

[11]  K. Rykaczewski Modeling thermal contact resistance at the finger-object interface , 2018, Temperature.

[12]  D. Bader,et al.  A modified evaluation of spacer fabric and airflow technologies for controlling the microclimate at the loaded support interface , 2018, Textile Research Journal.

[13]  M. Clark Microclimate: Rediscovering an Old Concept in the Aetiology of Pressure Ulcers , 2018 .

[14]  Matt Carré,et al.  New Non-invasive Techniques to Quantify Skin Surface Strain and Sub-surface Layer Deformation of Finger-pad during Sliding , 2017 .

[15]  E. Shirani,et al.  Analytical expressions for estimating endurance time and glove thermal resistance related to human finger in cold conditions. , 2017, Journal of thermal biology.

[16]  E. Shirani,et al.  A 3D thermal model to analyze the temperature changes of digits during cold stress and predict the danger of frostbite in human fingers. , 2017, Journal of thermal biology.

[17]  Mariapaola D'Imperio,et al.  An Integrated Approach to Characterize the Behavior of a Human Fingertip in Contact with a Silica Window , 2017, IEEE Transactions on Haptics.

[18]  Philippe Lefèvre,et al.  Dynamics of fingertip contact during the onset of tangential slip , 2014, Journal of The Royal Society Interface.

[19]  Gregory J. Gerling,et al.  Validating a Population Model of Tactile Mechanotransduction of Slowly Adapting Type I Afferents at Levels of Skin Mechanics, Single-Unit Response and Psychophysics , 2014, IEEE Transactions on Haptics.

[20]  Jane Nixon,et al.  A new pressure ulcer conceptual framework , 2014, Journal of advanced nursing.

[21]  G. Havenith,et al.  Thermal and tactile interactions in the perception of local skin wetness at rest and during exercise in thermo-neutral and warm environments , 2014, Neuroscience.

[22]  John M. Johnson,et al.  Cutaneous vasodilator and vasoconstrictor mechanisms in temperature regulation. , 2014, Comprehensive Physiology.

[23]  P. Loughlin,et al.  Effectiveness of local cooling for enhancing tissue ischemia tolerance in people with spinal cord injury , 2013, The journal of spinal cord medicine.

[24]  André Dufour,et al.  Thermal sensitivity in the elderly: A review , 2011, Ageing Research Reviews.

[25]  Lacy A. Holowatz,et al.  Aging and the control of human skin blood flow. , 2010, Frontiers in bioscience.

[26]  P Lefèvre,et al.  Fingertip moisture is optimally modulated during object manipulation. , 2010, Journal of neurophysiology.

[27]  K. Seffen,et al.  Temperature-dependent mechanical behaviours of skin tissue , 2008 .

[28]  Ryutaro Himeno,et al.  Finite element analysis of blood flow and heat transfer in an image-based human finger , 2008, Comput. Biol. Medicine.

[29]  N. Spencer,et al.  Study of skin–fabric interactions of relevance to decubitus: friction and contact‐pressure measurements , 2007, Skin research and technology : official journal of International Society for Bioengineering and the Skin (ISBS) [and] International Society for Digital Imaging of Skin (ISDIS) [and] International Society for Skin Imaging.

[30]  Naotaka Sakai,et al.  Quasi-static Deformation Analysis of a Human Finger using a Three-dimensional Finite Element Model Constructed from CT Images , 2007 .

[31]  Nigel A S Taylor,et al.  The distribution of cutaneous sudomotor and alliesthesial thermosensitivity in mildly heat‐stressed humans: an open‐loop approach , 2005, The Journal of physiology.

[32]  C. Lachenbruch Skin cooling surfaces: estimating the importance of limiting skin temperature. , 2005, Ostomy/wound management.

[33]  C. Walgama Simulation of hand cooling in contact with cold materials. , 2005 .

[34]  W. Lotens Simulation of hand cooling due to touching cold materials , 2005, European Journal of Applied Physiology and Occupational Physiology.

[35]  A. W. Schopper,et al.  A structural fingertip model for simulating of the biomechanics of tactile sensation. , 2004, Medical engineering & physics.

[36]  K B Pandolf,et al.  Lumped-parameter tissue temperature-blood perfusion model of a cold-stressed fingertip. , 1996, Journal of applied physiology.

[37]  Keith J. Leland,et al.  Temperature-modulated pressure ulcers: a porcine model. , 1995, Archives of physical medicine and rehabilitation.

[38]  K A Holbrook,et al.  Regional differences in the thickness (cell layers) of the human stratum corneum: an ultrastructural analysis. , 1974, The Journal of investigative dermatology.

[39]  W F SOUTHWOOD,et al.  THE THICKNESS OF THE SKIN , 1955, Plastic and reconstructive surgery.