Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-29T07:33:08.305Z Has data issue: false hasContentIssue false

Present and Future Applications of Shape Memory and Superelastic Materials

Published online by Cambridge University Press:  16 February 2011

T.W. Duerig*
Affiliation:
Nitinol Devices and Components, Fremont, CA, 94539, USA
Get access

Abstract

The utility of superelastic Ni-Ti alloys in the medical industry has been rather dramatically demonstrated in recent years. A great number of devices are now in production, and still others are staged to enter production during the next few years. This surge in interest from the medical community stems from an increased acceptance of Ni-Ti because of its biocompatibility, advances in micromachining techniques and trends towards less-invasive surgical techniques. In addition, there are a variety of new developmental concepts that will have a major influence on this and other markets during the next 5 years of commercialization. This review will highlight many of the properties of Ni-Ti by illustration in a variety of recent medical applications, and then discuss some of the newer developmental concepts. Medical applications that will be presented here include guidewires, laparoscopic surgical instruments, implants, stents, retrieval baskets, and bone anchors. Some of the new concepts and capabilities that are reviewed include microvalves made from thin films, high temperature alloys, fatigue resistant composites, and robotic actuators with tactile feedback.

Type
Research Article
Copyright
Copyright © Materials Research Society 1995

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1Schetky, L. McDonald, Scientific American 241, 74 (1979).Google Scholar
2.Duerig, T.W., Mater. Sci. Forum 56, (1990) 679.Google Scholar
3.Melton, K.: Shape Memory Materials '94 (Chu, Y. and Tu, H., eds.) Inter. Academic Pub., (1994) 523.Google Scholar
4.Engineering Aspects of Shape Memory, (Duerig, T.W., eds.) Butterwort-Heinemann, Boston (1990).Google Scholar
5.Suzuki, Y.: Titanium and Zirconium 30(4), (1982), 185.Google Scholar
6.Duerig, T.W. and Zadno, R.: Eng. Aspects of Shape Memory Alloys (Duerig, T. et al. , eds) Butterworth-Heinemann, Boston (1990) 369.Google Scholar
7Miyazaki, S. and Otsuka, K.: Met. Trans. A 17, (1986) 53.Google Scholar
8.Satanabe, K.: J. Dental Engineering 23(6), (1982) 47.Google Scholar
9.Sachdeva, R. and Miyazaki, S.: Eng. Aspects of Shape Memory Alloys (Duerig, T. et al. , eds) Butterworth-Heinemann, Boston (1990) 452.Google Scholar
10.Simon, M.: Blood Clot Filter, US patent 4,425,908 (1984).Google Scholar
11.Wolford, L.M. and Cottrell, D.A.: “The Mitek Mini Anchor in Maxillofacial Surgery”, to be published in Proc. of Shape Memory and Superelastic Technologies (SMST), (Pelton, A.R., Duerig, T.W. and Hodgson, D., eds.) (1995).Google Scholar
12. Endoscope, Japanese patent application 56-129791 (1981).Google Scholar
13.Poncet, P.P. and Zadno, R.: “Applications of Superelastic Ni-Ti in Laparoscopy”, to be 505 published in Proc. of Shape Memory and Superelastic Technologies (SMST), (Pelton, A.R., Duerig, T.W. and Hodgson, D., eds.) (1995).Google Scholar
14.Melzer, A. and Stockel, D.: “Performance Improvement of Surgical Instrumentation Through the Use of Ni-Ti Materials”, to be published in Proc. of SMST, (Pelton, A.R., et al. eds.) (1995).Google Scholar
15.Melzer, A. et al. : Endoscopic Surg. and Allied. Tech. 2(1) (1994) 77.Google Scholar
16.Stice, J.: Eng. Aspects of Shape Memory Alloys (Duerig, T., et al., eds) Butterworth Heinemann, Boston (1990) 483.Google Scholar
17.Pelton, A.R. et al. : “Experimental and FEM Analysis of the Bending Behvavior of Superelastic Tubing” to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
18.Proft, J.L. et al. : “Superelastic and Shape Memory Ni-Ti Microtubing”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
19.Horikawa, H.: “Superelastic Performance of Ni-Ti Thin Tubes” to be published in Proc. of SMST, (Pelton, A.R. eds.) (1995).Google Scholar
20.Zhuk, Y.: Advanced Medical Applications of Shape Memory Alloy in Russia, Tetra Consult, Moscow (1994).Google Scholar
21.Shabalovskaya, S.A. et al. : “Porous Ni-Ti: A New Material for Implants and Prostheses”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
22.Dario, P. and Montesi, M.C.: “Shape Memory Alloy Microactuators for Minimal Invasive Surgery”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
23.Bramfitt, J.E. and Hess, R.L.: “A Novel Heat Activated Recoverable Temporary Stent (HARTS System)”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
24.Johnson, A. D.: J. Micromech. Microeng. 1, (1991) 34.Google Scholar
25.Ikuta, K. et al. : “Laser Ablation of Ni-Ti Shape Memory Alloy Thin Film”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
26.Miyasaki, S., Nomura, K. and Zhirong, He.: “Shape Memory Effect and Superelasticity Develped in Sputter-Deposited Ni-Ti Thn Films”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
27.Johnson, A.D. and Busch, J.D.: to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
28.Ray, C.A. et al. : Mat. Res. Soc. Symp. Proc. 276, (1992) 161.Google Scholar
29.Shelyakov, A.V. et al. : “Optical Devices based on Shape Memory Effect for Signal Processing”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
30.DeFilippo, J.S. and Adamski, E.G.: “Electrical Discharge Machining Utilizing Smart Electrodes”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995)Google Scholar
31.Mertmann, M., Hornbogen, E. and Escher, K.: Shape Memory Materials '94 (Chu, Y. and Tu, H., eds.) Inter. Academic Pub., (1994) 556.Google Scholar
32.Honma, D., Miwa, Y., and Iguchi, N.: Eng. 18, (1984) 274.Google Scholar
33.Mulder, J.H. et al. : “On the High Temperature Shape Memory Capabilities of Ni-(TiZr) and Ni-(TiHf) Alloys”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
34.Shape Memory Materials '94 (Chu, Y. and Tu, H., eds.) Inter. Academic Pub., (1994) 253266.Google Scholar
35.Russel, S.M. and Sczerzenie, F.: “Engineering Considerations in the Application of Ni-Ti-Hf and NiAl as Practical High-Temperature Shape Memory Alloys”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
36.Tuominen, S.M.: “High Transformation Temperature Ni-Ti-Hf Alloys”, to be published in Proc. of SMST, (Pelton, A.R. et al. eds.) (1995).Google Scholar
37.Stbckel, D.: Metall. 46(7) (1992) 668.Google Scholar