1 / 1

Memory Foam Density:

Memory Foam Density:. >. >. Foot Orthotic. MASS Position (grey) Neutral Position (red ). Full Contact Orthotic. Gait Referenced Casting. Development of a Reusable Casting Apparatus for Custom Made Foot Orthotics Keegan Compton, Ryan Cook, Michelle Sauer

alagan
Télécharger la présentation

Memory Foam Density:

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Memory Foam Density: > > Foot Orthotic MASS Position (grey) Neutral Position (red) Full Contact Orthotic Gait Referenced Casting Development of a Reusable Casting Apparatus for Custom Made Foot Orthotics Keegan Compton, Ryan Cook, Michelle Sauer Biomedical Engineering, Vanderbilt University, Nashville, TN 37235 Sole Supports, Inc., Lyles, TN 37098 ABSTRACT RESULTS RESULTS CONTINUED • Introduction • Sole Supports, Inc. spends ~$500,000 annually to ship their foam casting box • Goal: Develop an economically advantageous reusable casting apparatus • Methods • Design and test a number of different casting devices • Brainstorm a number of solutions; perform research on these solutions • Build and test a number of prototypes • .Finalize sand design and test the device using Sole Supports, Inc.’s laser scanners to verify the effectiveness of our design • Results and Conclusion • Building and testing a number of our designs we were able to conclude that there were many limitations to the memory foam and modeling clay designs • Dual-compartment sandbox system had limited problems and proved to satisfy all of the objectives that were set forth for this project, resulting in a successful design of a reusable casting apparatus Investigation of Memory Foam Properties: Prototype Testing Continued: • Retraction time increases as time of applied force increases and density of memory foam increases • E. Moist Sand Piled in the Center of a Wooden Box • Captured and held foot shape and arch height • Sand displaced laterally under applied force • F. Moist Sand in a Dual-Compartment Wooden Box System • Captured and held foot shape and arch height. • Sand displaced vertically into bottom catch box under applied force • Depth of cast increased due to reduction in sand compaction BACKGROUND Economic Analysis: • Foot Orthotics • Support the arches of the patient’s feet • Correct the function of the foot muscles • Used with patients suffering from collapsed • arches caused by aging or disease • MASS Position Theory • Maximum Arch Supination Stabilization • Deficient supination of the foot arch during • midstance to forefoot loading 1 • Full Contact Orthotics • Remain in full contact with the arch at all times throughout the gait cycle.2 • Gait Referenced Casting • Follows the biomechanics of the foot as if the patient were going through their normal gait cycle. 3 • Changes in retraction time due to decreases in temperature were inconclusive because water caused memory foam to loose its memory capabilities • Total Saving: $543,000 • Must use dual-compartment sandbox system 4 times to break even CONCLUSION After testing several different prototypes it was concluded the dual-compartment sandbox system (Prototype F) is the least expensive casting method that maintains the requirements for Sole Support, Inc.’s casting technique. It is easily reusable. All materials used to construct the dual-compartment sandbox system (Prototype F) are inexpensive, can be found at a local home improvement store, and are recyclable. Therefore, all of the project objectives have been achieved with the dual-compartment sandbox system (Prototype F). Prototype Testing: • A. Memory Foam with Latex Exterior and Check Valve • Memory foam absorbed liquid latex instead of creating a vacuum tight exterior layer FUTURE WORK • B. Memory Foam with Ziploc Bag • Held the shape of a square wooden block after air was removed • Rounded edges were not desired by Sole Supports, Inc. • Sand can get messy, especially when transporting it from the bottom catch box back to wire grated top box. • Readjust catch-box size • Use a funnel to minimize spilling • Moisture levels in sand should be measured and standardized • If sand is too dry the shape of the foot cannot be maintained • If sand is too wet the sand compacts too much to cast the foot PURPOSE Sole Supports, Inc.. spends $500,000 annually to ship foam casting boxes to their clients. Clients cast the arch of their patients’ feet in the foam and then send a scan of the cast via the Internet to Sole Supports, Inc.. for manufacturing of the patients’ custom foot orthotics. The foam material currently used for casting can only be utilized once and then must be thrown out. Our project is to develop a reusable casting apparatus that: 1.  Maintains Sole Supports, Inc.'s casting technique 2.  Easily returns to its original shape 3.  Is cost effective 4.  Is environmentally friendly • C. Play-Doh in Rubbermaid Container • Captured and held the foot shape and arch height • Very dense, required lots of applied force to cast the foot • Play-Doh stuck to patient’s foot after casting REFERENCES • D. Moist Sand in Sole Supports, Inc. Casting Box • Captured and held the foot shape and arch height • Depth of cast limited due to sand compaction • Scan of sand cast met Sole Supports, Inc. specifications 1 “Corrective Paradigm: Mass Position” http://www.solesupports.com/visitorhome/theoryandresearch.apsx 2 Dr. Stu Currie, “Advancements in Custom Orthotics” http://www.solesupports.com/visitorhome/theoryandresearch.apsx 3 http://www.solesupports.com METHODS 1. Generate List of Possible Reusable Casting Materials 2. Research and Select Most Promising Reusable Casting Materials for Testing 3. Test Memory Foam Properties 4. Build and Test Prototypes 5. Conduct an Economic Analysis ACKNOWLEDGEMENTS 3D Scans:Left: Sand castRight: Sole Supports, Inc. current foam cast Special thanks to Dr. Paul King, Mr. Matt Moore, Dr. Hak-Joon Sung, and Mr. Brad Compton for their help with this project. We also appreciate the support of the Vanderbilt Biomedical Engineering Department and Sole Supports, Inc. Laboratory.

More Related