Blinking Orbital Prosthesis

1. Blinking Orbital Prosthesis Hallie Kreitlow, Joel Gaston, Ryan Kimmel, Allison McArton

2. Outline • Problem Statement • Background • Summary of PDS • Designs and the Matrix • Future Work • Conclusion

3. Problem Statement • Realistic blinking orbital prosthesis • Same speed as functional eye • Reasonable size and weight • Non-harmful mechanism and materials • Automated system

4. Background-Orbital Prosthesis Many causes of eye loss Prosthesis provide a realistic solution Currently, prostheses do not blink

5. Background-Problem Motivation • Providing a more realistic prosthesis • Syncing the blinking motion in both eyes • Satisfying the patient • Create interest in the field

6. Product Design Specification • Function • Client Requirements • Design Requirements • Physical and Operational Characteristics • Production Characteristics • Miscellaneous

7. Function • Animated orbital prosthesis • Currently few attempts • Previously ran a wire from the contralateral eye muscle into orbital prosthesis • Small enough to fit inside eye cavity and contain all parts

8. Requirements • Client Requirements • Impart life-like quality to a variety of materials • Thin materials to save weight and space • Synchronization could and should be considered later • We are provided with an adequate budget Design Requirements • It must be able to function for an entire day, but it doesn’t need to be aesthetically pleasing

9. Physical and Operational Characteristics Performance Requirements • Safety • Accuracy, Reliability, and Life in Service • Operating Environment • Ergonomics, Size, and Weight • Materials and aesthetics

10. Production Characteristics and Miscellaneous • Quantity • Target Product Cost • Standards and Specifications • Patient-related Concerns • Competition

11. Possible Designs Actuator Movement Attracting Magnetic Field Repelling Magnetic Field Memory Metal Circuit

12. Actuator movement • Cons • Highly Invasive • Power source must be located in cavity • Components take up a lot of space • Cannot be removed Pros • Will work regardless of environment outside cavity • Durable • Fairly safe

13. Design-Common Aspects • Air-core solenoid located in glasses frame B-Field i

14. Repelling Magnetic Field • Pros • Non-invasive • Power source located outside cavity • Power only used when blink occurs • Cons • Large magnetic field/current required Compression Spring Eye Lid B-Field Permanent magnetic plate Boundary of Cavity

15. Magnetic Field Designs-Alternate View Top View Side View

16. Attracting Magnetic Field Eye Lid Tension Spring B-Field Permanent magnetic plate Boundary of Cavity Pros • Non-invasive • Power source located outside cavity Cons • Large magnetic field/current required • Constant power must be provided

17. Memory Metal Circuit Pros • Space efficient Cons • Power source located in cavity • High current running through wire • Extensive circuit engineering required

18. Design Matrix

19. Future Work • Research on IR sensor • Fabrication of needed parts • Assembly of prototype • Dealing with size issues • Prototype testing • Redesigning and subsequent testing

20. Conclusion • Extensive research has been done on orbital prosthesis • Developed several designs and chose the best design • Work still needs to be done

21. Credits • Professor Murphy • Greg Gion • Professor Bruch