摘要
Plasma immersion ion implantation and deposition (PIII&D) has been shown to be an effective tech- nique to enhance the surface bioactivity of materials. In this paper, recent progress made in our laboratory on plasma surface modification single-crystal silicon and amorphous carbon is reviewed. Silicon is the most important material in the integrated circuit industry but its surface biocompatibility has not been investigated in details. We have re- cently performed hydrogen PIII into silicon and observed the biomimetic growth of apatite on its surface in simulated body fluid. Diamond-like carbon (DLC) is widely used in the industry due to its excellent mechanical properties and chemical inertness. The use of this material in biomedical engineering has also attracted much attention. It has been observed in our laboratory that doping DLC with nitrogen by means of PIII can improve the surface blood compati- bility. The properties as well as in vitro biological test results will be discussed in this article.
Plasma immersion ion implantation and deposition (PIII&D) has been shown to be an effective tech- nique to enhance the surface bioactivity of materials. In this paper, recent progress made in our laboratory on plasma surface modification single-crystal silicon and amorphous carbon is reviewed. Silicon is the most important material in the integrated circuit industry but its surface biocompatibility has not been investigated in details. We have re- cently performed hydrogen PIII into silicon and observed the biomimetic growth of apatite on its surface in simulated body fluid. Diamond-like carbon (DLC) is widely used in the industry due to its excellent mechanical properties and chemical inertness. The use of this material in biomedical engineering has also attracted much attention. It has been observed in our laboratory that doping DLC with nitrogen by means of PIII can improve the surface blood compati- bility. The properties as well as in vitro biological test results will be discussed in this article.
基金
Jointly supported by Hong Kong Research Grants Council (RGC) Competitive Earmarked Research Grant (CERG) #City U1137/03E
Germany / Hong Kong Joint Research Scheme sponsored by the Research Grants Council of Hong Kong and the German Academic Ex
关键词
表面生物活性
等离子体
非晶体碳
类金刚石碳
单晶硅
Hydrogen implanted silicon, Plasma, Bioactivity, Apatite, Diamond-like carbon, Amorphous carbon, Blood compatibility
