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Design of an Ankle Foot Orthotic

Design of an Ankle Foot Orthotic. Christopher Sullivan. Outline. What is Foot Drop? Overview of gait cycle Different kinds of existing AFOs Actuator Selection Timeline Budget. Why do People Need Ankle Foot Orthotics?. Foot Drop inability to Dorsiflex the foot during the Gait Cycle

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Design of an Ankle Foot Orthotic

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  1. Design of an Ankle Foot Orthotic Christopher Sullivan

  2. Outline • What is Foot Drop? • Overview of gait cycle • Different kinds of existing AFOs • Actuator Selection • Timeline • Budget

  3. Why do People Need Ankle Foot Orthotics? • Foot Drop • inability to Dorsiflex the foot during the Gait Cycle • Foot Drop is a Symptom associated with: • List conditions from next slide here Figure 1 http://sports.jrank.org/article_images/sports.jrank.org/dorsiflexion.1.jpg

  4. Who does Drop Foot Effect? • Foot Drop is a lasting symptom to a variety of neurological conditions. • Stroke • Cerebral Palsy • Multiple Sclerosis • Polio • Direct injury to the Peroneal Nerve Figure 2 http://upload.wikimedia.org/wikipedia/commons/9/9d/Gray832.png

  5. The Gait Cycle Stance Swing • Over the years the Gait Cycle has been meticulously measured. Initial Double-Limb Support Terminal Swing Second Double-Limb Support Mid-Swing Single-Limb Stance Initial Swing Periods Foot Strike Opposite Toe-Off Opposite Foot Strike Tibia Vertical Foot Clearance Foot Strike Toe-Off % of Cycle 62% 0% 100%

  6. 2-D kinematics of leg during walking • Svensson W, Holmberg U. Ankle-Foot-Orthosis Control in Inclinations and Stairs. 2008 21-24 Sept. 2008. p 301-306.

  7. 2-D kinematics of leg during walking θP= Angle of the Pelvis relative to the ground θH=Angle of the Upper Leg relative to the Pelvis θN=Angle of the Lower Leg relative to the Upper Leg θA= Angle of the Ankle relative to the Lower Leg B

  8. 2-D kinematics of leg during walking • Free Body Diagram Created • Simple Quasistatic Analysis Done • Dynamic Analysis Still needs to be Done B

  9. What is an Ankle Foot Orthotic? Commercially Available • Hard Plastic AFO • Electrical Stimulation Recently investigated • i-AFO • Variable Dampening AFO for Inclined Surfaces • AFO with Air Muscles • Pneumatic Power Harvesting AFO • An orthopedic brace meant to repaired lost function in the foot and ankle.

  10. Hard Plastic AFO • Passive support of the Foot • Molded to fit patient’s leg • Rigidity can cause problems • Prefabricated Ankle-Foot Orthosis. (n.d.). Retrieved from ANKLE-FOOT ORTHOSIS: http://www.orthomerica.com/products/anklefoot/ankle_foot.htm

  11. Electrical Stimulation • Bioness • Stimulates the Peroneal Nerve • Expensive • Unable to use if you have • Pacemaker • Heart Conditions • Recent fracture or dislocation • peroneal nerve location • Silberstein, N. (2008, November 2). Foot Drop. Retrieved from Pt Products Online: http://www.ptproductsonline.com/issues/articles/2008-11_02.asp

  12. Variable Dampening AFO for Inclined Surfaces • Created in 2008 at Halmstad University in Sweden • Uses Magneto Rheological Damper • Very Unique • Too bulky to fit in shoe • The power supply is never specified • Svensson W, Holmberg U. Ankle-Foot-Orthosis Control in Inclinations and Stairs. 2008 21-24 Sept. 2008. p 301-306.

  13. i-AFO • Constructed in 2010 at Yamagata University in Japan • Uses Rotary braking system • Untethered • Too bulky to fit in shoe • Kikuchi T, Tanida S, Otsuki K, Yasuda T, Furusho JYM. Development of third-generation intelligently Controllable ankle-foot orthosis with compact MR fluid brake T2 - Robotics and Automation (ICRA), 2010 IEEE International Conference on. Robotics and Automation (ICRA), 2010 IEEE International Conference on 2010.

  14. AFO with Air Muscles • Created in 2005 at the University of Michigan • Uses Air Muscles to produce Plantarflexion • Too bulky to fit in shoe Tethered to an external air supply • Gordon KE, Sawicki GS, Ferris DP. Mechanical performance of artificial pneumatic muscles to power an ankle-foot orthosis. Journal of Biomechanics 2006;39(10):1832-1841.

  15. Pneumatic Power Harvesting AFO • Created in 2009 at University of Illinois at Urbana-Champaign • Used a simple Pneumatic Linear Actuator • Generated its own power • Too bulky to fit in shoe • Chin R, Hsiao-Wecksler E, Loth E, Kogler G, Manwaring S, Tyson S, Shorter K, Gilmer J. A pneumatic power harvesting ankle-foot orthosis to prevent foot-drop. Journal of NeuroEngineering and Rehabilitation 2009;6(1):1-11.

  16. Actuator Selection • Gomis-Bellmunt O, Campanile LF. Actuator Design Analysis. Design Rules for Actuators in Active Mechanical Systems: Springer London; 2010. p 29-78.

  17. Actuator Selection • Gomis-Bellmunt O, Campanile LF. Actuator Design Analysis. Design Rules for Actuators in Active Mechanical Systems: Springer London; 2010. p 29-78.

  18. Actuator Selection • Gomis-Bellmunt O, Campanile LF. Actuator Design Analysis. Design Rules for Actuators in Active Mechanical Systems: Springer London; 2010. p 29-78.

  19. Next Steps • Before Design work can truly commence • Interviews must be held • A dynamic model must be created • Proof of concepts prototypes

  20. Time Line Winter Spring (2010-2011) Goals • Initial Literature Search Begun • Finish Literature Search • Finish and present Thesis Proposal • Modeling of the Foot Course Load Winter • ACT • System Dynamics • Rapid Prototyping Spring • Thermal Fluids Lab 2 • Intro To Biomaterials • Dynamics Of Machinery • System Modeling • Comp Imp FEM

  21. Time Line Summer (2011) Goals • Co-Op working on project • Interviews • Finish Modeling the Foot • Proof of Concept prototypes created • Systems level design • Detailed Design • Building AFO Started • Writing Thesis Co-op • 40 hr/wk

  22. Time Line Fall (2011) Goals • Finish Building AFO • Bench Testing • Writing Thesis Course Load • Control Systems • Senior Design 1 • Math 1

  23. Time Line Winter (2011-2012) Goals • Finish Bench Testing • Clinical Testing • Compile Work • Writing Thesis • Submit paper to IMECE or SBC Course Load • Inter. Control Systems • Senior Design 2 • Math 2

  24. Time Line Spring (2012) Goals • Finish Clinical Testing • Finish Writing Thesis • Thesis Defense Course Load • Advanced Control Systems

  25. Budget Part Time Work • 10 hr/wk for 3 qtrs Full Time Summer Co-Op • 40 hr/wk Prototype • $1000 for parts and testing supplies

  26. Important Mile Stones • Getting Approval to talk to patients • Interviews • Design Reviews • Presentation • Bench Testing • Clinical Testing Approval

  27. Summary • The goal of this project will be to create an Ankle Foot Orthotic • The difference between our project and any of the mentioned projects, is the way that the problem will be attacked

  28. Questions?

  29. References • Silberstein, N. (2008, November 2). Foot Drop. Retrieved from Pt Products Online: http://www.ptproductsonline.com/issues/articles/2008-11_02.asp • New Device Helps Stroke Patients suffering from 'foot drop'. (2010, September 17). Retrieved from Healthlink: . http://www.nwcn.com/news/health/New-device-helps-stroke-patients-suffering-from-foot-drop-103150749.html • Roşca, I. C., & Radu, C. (2008, April 24-26 ). On the Design of the Analitycal Ankle – Foot Model . 6th International DAAAM Baltic Conference . • Sutherland DH, Olshen R, Cooper L, Woo SL. The development of mature gait. J Bone Joint Surg Am 1980;62(3):336-53. • Whittle MW. Clinical gait analysis: A review. Human Movement Science 1996;15(3):369-387. • Pandy MG. Models for understanding the dynamics of human walking 1987. • Pandy MG, Berme N. Synthesis of human walking: A planar model for single support. Journal of Biomechanics 1988;21(12):1053-1060. • Vaughan CL, Davis BL, O'Connor JC. Dynamics of human gait. Champaign, Ill.: Human Kinetics Publishers; 1992. • Prefabricated Ankle-Foot Orthoses. (n.d.). Retrieved from ANKLE-FOOT ORTHOSIS: http://www.orthomerica.com/products/anklefoot/ankle_foot.htm • Sohn RH, Park SW, Hwang SH, Ko AR, Lee YH, Lee SH, Ryu KH, Kim YH. A Potable System for Foot-Drop Correction using Electrical Stimulation.259-260. • Contraindications for Use of the NESS L300 Foot Drop System. (2010). Retrieved from Bioness: http://www.bioness.com/Canada_-_English/Contraindications.php • Kikuchi T, Tanida S, Otsuki K, Yasuda T, Furusho JYM. Development of third-generation intelligently Controllable ankle-foot orthosis with compact MR fluid brake T2 - Robotics and Automation (ICRA), 2010 IEEE International Conference on. Robotics and Automation (ICRA), 2010 IEEE International Conference on 2010. • Svensson W, Holmberg U. Ankle-Foot-Orthosis Control in Inclinations and Stairs. 2008 21-24 Sept. 2008. p 301-306. • Gordon KE, Sawicki GS, Ferris DP. Mechanical performance of artificial pneumatic muscles to power an ankle-foot orthosis. Journal of Biomechanics 2006;39(10):1832-1841. • Chin R, Hsiao-Wecksler E, Loth E, Kogler G, Manwaring S, Tyson S, Shorter K, Gilmer J. A pneumatic power harvesting ankle-foot orthosis to prevent foot-drop. Journal of NeuroEngineering and Rehabilitation 2009;6(1):1-11. • Gomis-Bellmunt O, Campanile LF. Actuator Design Analysis. Design Rules for Actuators in Active Mechanical Systems: Springer London; 2010. p 29-78. • Huber, E. J, Fleck, A. N, Ashby, F. M. The Selection of Mechanical Actuators Based on Performance Indices. London, Royaume-uni: Royal Society of London; 1997. 21 p. • Tavakoli M, Marques L, de Almeida AT. A comparison study on Pneumatic Muscles and electrical motors. 2009 22-25 Feb. 2009. p 1590-1594. • Tsagarakis N, Caldwell DGY. Improved modeling and assessment of pneumatic muscle actuators T2 - Robotics and Automation, 2000. Proceedings. ICRA '00. IEEE International Conference on. Robotics and Automation, 2000. Proceedings. ICRA '00. IEEE International Conference on 2004. • Sauer P, Kozłowski K, Morita Y, Ukai H. Ankle Robot for People with Drop Foot – Case Study.443-452. • Blaya JA, Herr H. Adaptive control of a variable-impedance ankle-foot orthosis to assist drop-foot gait. IEEE Trans Neural SystRehabilEng 2004;12(1):24-31. • Chu TT. Biomechanics of ankle-foot orthoses: past, present, and future. Top Stroke Rehabil 2001;7(4):19-28. • Ohata K, Yasui T, Tsuboyama T, Ichihashi N. Effects of an ankle-foot orthosis with oil damper on muscle activity in adults after stroke. Gait Posture. Volume 33. England: 2010 Elsevier B.V; 2011. p 102-7.

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