Fabricated Antibacterial and Bioactive Titania Nanotube Arrays Coating on the Surface of Titanium ()
1. Introduction
It is well known that titanium is widely used as bone implant materials because it has excellent biocompatibility and mechanical properties that enhance osseointegration. Nevertheless, it has not bioactive compared to bioactive materials, and requires bio-activation. According to literatures, surface treatments of bioactivities have led to improvements in the adhesion of osteoblasts and their proliferation [1-4]. The surface morphology and composition of the titanium can be regulated by surface treatments, such as alkali and heat treatment, etching, spray, anodizing, and so on.
Branemark et al. [5] reported that titanium and titanium-based alloys can be used as implant materials, many attempts have been made to modify the structure, composition, and chemistry of the titanium surfaces including fabrication of titania coating [6-11], including the fabrication of bioactive TiO2 nanotube arrays [12,13]. Tian Tian et al. [12] studied the effect of crystal structure of TiO2 nanotube arrays bioactivity and found that a mixture titania nanotube of anatase and rutile are clearly more efficient in promoting apatite formation than the amorphous state. Xiao Xiufeng et al. [13] found that the bioactive titania nanotube arrays can form on the surface of titanium by anodic oxidation in hydrofluoric (HF) electrolyte with the addition of 5 - 10 g/L Na2HPO4, ions remained in the tube attract Ca2+ in simulated body fluid and induce the nucleation of apatite.
The intuitionistic plot of the titania nanotube arrays is shown in Figure 1(a), the empty space of titania nanotube is very useful for modifying, such as fill something with especial function into it, the intuitionistic plot of modified titania nanotube arrays as shown in Figure 1(b).
Therefore, the present study was aimed to manufacture a new bioactive titanium implant material by modifying bioactive titania nanotube arrays, which will has antibacterial action. Once the bioactive titanium implant material has antibacterial action, they can avoid surgery failing because of infection.
2. Experiment Section
2.1. Preparation of Bioactive Titania Nanotube Arrays
Prior to anodization, the titanium foils (99.5% pure) were ultrasonically cleaned in acetone and distilled water for 5 min, then chemistry eroded in 4 wt% HF + 5 mol/L HNO3 for 30S, followed by ultrasonically cleaned in distilled water for 5 min and dried in air at 40 of centigrade. A two-electrode with a graphite cathode was employed for the anodization of titanium. 0.5 wt% NH4F solution counting 5 g/L Na2HPO4 solution was used as electrolytes. All electrolytes were prepared from reagent grade
Figure 1. The intuitionistic plot of the titania nanotube arrays before (a) and after (b) modified.
chemicals and DI water. The anodizing voltage was kept constant during the entire process with a DC power supply (GOA, China) at 20 V. The whole course of anodizing was conducted at room temperature (25 of centigrade) with magnetic agitation. After anodizing, the samples were rinsed with DI water and then dried at 40 of centigrade in air. The as-prepared sample was signed as NA1.
Heat treated the sample NA1 at 500˚C in muffle with air for 1hour, and signed it as NA2.
2.2. Ag Modified Bioactive Titania Nanotube Arrays
After immerging the samples into 0.1 mol∙L−1 AgNO3 solutions for 2 min, irradiated the samples by ZF-II UV lamp with the wavelengh of 365 nm and the intensity of 1400 mw∙cm−2 for 2 min. Repeat the process three times. At last ultrasonically cleaned the samples with DI water and dried them at 40˚C in air, and signed the sample as NA3.
2.3. Antibacterial Researches
Staphyloccocus aureus is an important pathogeny bacterium for human. It can evoke many badly infection. So the staphyloccocus aureus was used in the antibacterial researches.
Firstly, coated the MH agar plate onto the petri dish, and then coated the asepsis physiological brine with 0.5 wt% staphyloccocus aureus onto the MH agar plate, ultimately put the petri dish into the electrothermal incubator with 37˚C temperature for 12 hours and 24 hours. But 12 hours is not enough for antibacterial researches to make a distinction. Therefore longer time spend on the antibacterial researches in this section.
2.4. Characterization
Scanning electron microscopy (SEM) was used to determine surface morphology using HITACHI-S3400N SEM. The compositions of the coating were determined with an energy dispersive X-ray spectrometer (EDX).
3. Results and Discussions
From Figure 2, we can see the mouth of titania nano-
tube. When the sample NA3 was tested by XRD, Ti peak and TiO2 peak appeared but there is no Ag peak on the XRD patterns. The result of XRD is shown in Figure 3 XRD of NA3.
The results indicated that the amount of Ag is little. The compositions of the coating were determined with EDX, the result as shown in Figure 4. There has about 2.3 wt% Ag formed on the surface of the sample.
The results of the EDX and the real reaction as follow can prove effectively that Ag have formed on the surface of NA3. The results indicated that Ag modified was successful.
In antibacterial researches, there is an obviously antibacterial ring formed around the NA3, and there is no antibacterial ring formed around the NA1 and NA2 as contrast. The result is shown in Figure 5, the result of antibacterial researches. The results indicate that Ag modified is successful, the above process endow the bioactive titania nanotube arrays with good antibacterial capability.
It is well known that Ag has good antibacterial capability. Modifying the bioactive titania nanotube arrays with Ag is a good idea for the fabrication of the antibacterial bioactive titania nanotube arrays.
Figure 5. The result of antibacterial researches.
4. Conclusion
The antibacterial bioactive titania nanotube arrays can be obtained by follow method: modify the bioactive titania nanotube arrays with Ag. Anodic oxidation treatment and Ag modified are economical method for surface antibacterial bioactive treatment.
5. Acknowledgements
The authors would like to thanks the Research Foundation of Baotou City Youth Innovation and the Research Foundation of Zhejiang Province Public Technology Research and industrial projects (2013C31051).
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