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Novel Anti-Cancer, Anti-Bacterial Coatings for Biomaterial Applications: Selenium Nanoclusters

Published online by Cambridge University Press:  31 January 2011

Phong Anh Tran
Affiliation:
phong_tran@brown.edu, Brown univeristy, 192 Hope street, Providence, 02912, United States
Erik Taylor
Affiliation:
erik_taylor@brown.edu, Brown University, Engineering, Providence, Rhode Island, United States
Love Sarin
Affiliation:
love_sarin@brown.edu, Brown University, Providence, Rhode Island, United States
Robert H. Hurt
Affiliation:
Robert_Hurt@brown.edu
Thomas J Webster
Affiliation:
thomas.webster@scholarone.com, United States
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Abstract

Two common problems with implantation after cancerous tumor resection are cancer recurrence and bacteria infection at the implant site. Tumor resection surgery sometimes can not remove all the cancerous cells, thus, cancer can return after implantation. In addition, bacteria infection is one of the leading causes of implant failure. Therefore, it is desirable to have anti-cancer and anti-bacterial molecules which both rapidly (for anti-infection purposes) and continuously (for anti-cancer purposes) are available at the implant site following implantation. Therefore, the objective of the present in vitro study was to create a multi-functional coating for anti-cancer and anti-bacterial orthopedic implant applications. Elemental selenium was chosen as the biologically active agent in this effort because of its known chemopreventive and anti-bacterial properties. To achieve that objective, titanium (Ti), a conventional orthopedic implant material was coated with selenium (Se) nanoclusters. Different coating densities were achieved by varying Se concentration in the reaction mixture. Titanium substrates coated with Se nanoclusters were shown to enhance healthy osteoblast (bone-forming cell) and inhibit cancerous osteoblast proliferation in co-culture experiments. Functions of S. epidermidis (one of the leading bacteria that infect implants) were inhibited on Ti coated with Se-nanoclusters compared to uncoated materials. Thus, this study provided for the first time a coating material (selenium nanoclusters) to the biomaterials’ community to promote healthy bone cells’ functions, inhibit cancer growth and prevent bacteria infection.

Type
Research Article
Copyright
Copyright © Materials Research Society 2010

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References

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