Abstract

We investigate by different complementary methods the processes occurring when a polydimethylsiloxane film is used as interlayer for a silver doped hydroxyapatite coating. The X-ray diffraction and Fourier Transform Infrared Spectroscopy measurements show that the hydroxyapatite doped with silver is in a crystalline form and some ions formation takes place at the surface and in the bulk of the new hydroxyapatite doped with silver/polydimethylsiloxane composite layer. The possibility of ions incorporation in the structure of silver doped hydroxyapatite by the mechanism of / ions substitution is analysed. The new formed silver doped hydroxyapatite/polydimethylsiloxane composite layer is compact, homogeneous, with no cracks as it was shown by Scanning Electron Microscopy and Glow Discharge Optical Emission Spectrometry.

1. Introduction

Hydroxyapatite (HAp, Ca10(PO4)6(OH)2) is a biomaterial with a wide range of applications in medicine due to its biocompatibility, bioactivity, and osteoconductivity [14]. Hydroxyapatite has been used to fill a wide range of bony defects in orthopedic and maxillofacial surgeries and dentistry [58]. It has also been widely used as a coating for metallic prostheses to improve their biological properties [911].

From an antibacterial point of view, silver nanoparticles are widely used in medical devices and supplies such as wound dressings, scaffold, skin donation, recipient sites, and sterilized materials in hospitals, medical catheters, contraceptive devices, surgical instruments, bone prostheses, artificial teeth, and bone coating.

Recently, the use of inorganic antibacterial agents, like silver or copper, incorporated in the structure of hydroxyapatite has been shown to be of great interest in the fight against microbes [4]. Hydroxyapatite (HAp) has a very high cation exchange rate with silver ions. Even if at high concentration the silver can be toxic, in small concentrations it has a broad spectrum of antibacterial activity for a wide range of microorganisms like viruses, bacteria, or fungi [2]. Therefore the optimization of the Ag concentration in the HAp structure is critical to guarantee an optimum antibacterial effect without cytotoxicity.

The most common technique to incorporate Ag into HAp structure is via an ion exchange method, in which the Ca ions in HAp are replaced by Ag ions while dipping the HAp coatings into AgNO3 for a period of time [2]. The limitation of this ion exchange method is that Ag will reside mostly on the outer surface of the coating and will be quickly depleted in vivo/in vitro without long-term antibacterial effect.

In our previous studies [11] we presented preliminary results regarding the synthesis, characterization, and antibacterial properties of hydroxyapatite (HAp) and silver doped hydroxyapatite (Ag:HAp). The exact antibacterial action of silver nanoparticles (AgNPs) is not completely understood [12]. On the other hand, in the literature, studies on the preparation and characterization of the silver doped hydroxyapatite powders are almost absent. Antibacterial studies on the Ag:HAp nanopowders are also not presented. Recent studies [11, 13] have demonstrated that Ag:HAp nanoparticles prepared by coprecipitation method at 100°C show great promise as antibacterial agents against both gram-positive and gram-negative bacteria [13, 14].

Coatings of HAp have been deposited as amorphous layers by various techniques like plasma-spray technique, pulsed laser deposition, electrodeposition, sol-gel processing, and radio-frequency magnetron sputtering [15, 16]. Therefore, the coatings are thermally crystallized at elevated temperatures. During these thermal treatments, many cracks are formed due to a thermal expansion mismatch between the coating and the metal substrate, which severely reduces the bonding strength of the coating layer with the substrate [16].

In order to improve the delamination of HAp coatings different types of interlayers between the substrate and the HAp coating have been used as reinforcement agents. For example, SiO2 layers are known for their own excellent compatibility with the living tissues and their high chemical inertness [17].

The polydimethylsiloxane (PDMS) is an elastomer with biocompatible properties and is frequently used as substrate for biological studies [6, 18]. The hydrophobic character of a PDMS layer, due to the methyl groups present on its surface, makes it suitable for nonadherent cell culture studies [19]. On the other hand, the oxidation of the PDMS surfaces can be achieved by different treatment methods [19], leading to the formation of hydrophilic SiO2 surfaces which may favor the cells adhesion.

In this paper a method for generation of a Ag:HAp-PDMS composite layer by thermal evaporation of Ag:HAp nanoparticles and their deposition on the surface of a pure Si disk substrate previously covered with a PDMS layer is presented. The role of the polymer layer and the associated physicochemical processes that take place during the interaction of the hydroxyapatite vapours with the polymer are investigated by Scanning Electron Microscopy (SEM), X-ray diffraction (XRD), Fourier Transform Infrared Spectroscopy (FTIR), and Glow Discharge Optical Emission Spectroscopy (GDOES).

2. Experimental Section

2.1. Deposition of PDMS Polymer Layer on Commercially Pure Si Disks

The PDMS layers have been generated in atmospheric air pressure corona discharges starting from liquid precursors of vinyl terminated polydimethylsiloxane. The method and the experimental conditions used for the deposition of thin PDMS layers (with an average thickness in the hundred nanometers range) on metallic substrates were presented in detail in [8, 9].

2.2. Silver Doped Hydroxyapatite (Ag:HAp) Nanoparticles

In order to synthesize the silver doped hydroxyapatite (Ag:HAp) precursors of calcium nitrate [Ca(NO3)2·4H2O, Aldrich, USA], ammonium hydrogen phosphate ((NH4)2HPO4; Wako Pure Chemical Industries Ltd.) and AgNO3 (Alpha Aesare, Germany, 99.99% purity) were used. Controlled amounts of ammonium hydrogen phosphate and silver nitrate were dissolved in ethanol. After adding distilled water, the solution was stirred vigorously for 24 h at 40°C. In a separate container, a stoichiometric amount of calcium nitrate was dissolved in ethanol with vigorous stirring for 24 h at 40°C. The Ca-containing solution was added slowly to the P-containing solution and then aged at room temperature for 72 h and further at 40°C for 24 h. The composition ratios in the Ag:HAp ( = 0 and = 0.5) sol were adjusted to have [Ca+Ag]/P as 1.67 [11, 47]. The obtained Ag:HAp nanopowders were treated at 800°C for 6 hours.

2.3. Deposition of Ag:HAp Solid Layers on Silicon Substrates Previously Coated with a PDMS Layer

Starting from an Ag:HAp ( = 0.5) powder (source material), by the thermal evaporation technique, an Ag:HAp solid layer has been deposited on a silicon substrate previously coated with a PDMS film. By this technique the Ag:HAp is evaporated in vacuum. The vapours travel directly to the substrate where they condense to a solid state. A HOCH VACUUM Dresden installation was used under environment conditions. The pressure in the deposition chamber was in the range of  torr. The time range for a deposition cycle was around 120 min. The substrate was maintained at room temperature and at ground electrical potential. The Ag:HAp powder evaporation temperature was 1100°C. The tungsten boat temperature during the Ag:HAp powder evaporation is in the range of 1178–1205°C. The distance between substrate and boat is 5 cm.

The evaporation time measured during deposition is situated in the range of 20 sec for a maximum current intensity of = 75 A and in the range of 15 sec for a maximum current = 80 A. Taking into account the deposition characteristics, such as the total amount of HAp totally deposited (in mg) and the substrate-boat distance, the calculated evaporation velocities are = 0.167 mg/s or  nm/s. The calculated thickness of a Ag:HAp ( = 0.5) layer deposited, in the experimental conditions presented above, on a silicon substrate is about 480 nm. In the presence of a PDMS film, the evaporated Ag:HAp nanoparticles that travel to the substrate condense, being trapped into the polymer bulk. Thus, an Ag:HAp-PDMS composite layer is generated.

2.4. Samples Characterizations

The morphology of the material was studied using a Quanta Inspect F Scanning Electron Microscope (SEM) equipped within gun beam in emission field, with wolfram filament and with a linear resolution of 5 nm. A part (10 mm) of a Si substrate with a diameter of 20 mm was covered with a PDMS layer by the method presented above. Then an Ag:HAp layer was deposited by thermal evaporation technique on the entire surface of the Si substrate. The XRD patterns were recorded in the range of 25–55° using a Philips PW1830 diffractometer with filtered Cu Kα radiation. The IR spectra of the Ag:HAp-PDMS composite layer formed on a silicon substrate have been obtained using an IR Perkin Elmer spectrometer equipped with a variable angle specular reflectance accessory. In order to perform depth profile studies of the Ag:HAp-PDMS composite layer we varied the angle of incidence light on the sample (equal but opposite to the angle of reflected light) from 30° to 60°. Here should be: Thus, function of the angle of incidence of the light on the sample the penetration depth of the light into the layer can be changed. For an angle of reflection of 30°, the geometrical position of the variable angle specular reflectance accessory inside the IR spectrometer allows the investigation of the composite layer/substrate interface. As the angle of reflection is increased up to 60° we can get information about molecules bonds arrangement in the composite layer bulk and as close as possible to the layer surface [9]. For certain spectral ranges, the peak fitting analyses were performed using procedures of Kolmas et al. [48]: (i) baseline correction, (ii) second derivative calculation and self-deconvolution assessment in order to determine the number and positions of the bands, and (iii) curve fittings with fixed peak positions using Lorentzian functions. In the previous studies Matsuhiro and Rivas [49] and Gómez-Ordóñez and Rupérez [50] showed that second derivatives of FTIR spectra are generally used as an aid for wavenumber determination of weak absorption bands or to improve resolution of overlapped bands in the original spectra. To that end, in our studies, derivation including Savitzky-Golay algorithm with nine smoothing points was performed. The depth profile analysis of the Ag:HAp-PDMS composite layer formed on a silicon substrate was performed by Glow Discharge Optical Emission Spectroscopy (GDOES) using a GD Profiler 2 from Horiba/Jobin-Yvon. The selected operating conditions were as follows: 650 Pa for pressure and 35 W RF power, working in pulsed mode at 1 kHz pulsing frequency, and a duty cycle of 0.25. In this technique an area of 4 mm of the layer is sputtered by a pulsed RF Ar plasma. The sputtered atoms from the layer are then excited by inelastic collisions in the plasma and the emitted lightis monitored in real time providing intensities of the elements of the investigated sample from the surface down to the substrate as a function of time.

An accurate conversion of sputtering time into sputtered depth is not straightforward because the sputtering rate is material dependent and varies during the elemental depth profiling measurement.

3. Results and Discussions

3.1. Scanning Electron Microscopy

In Figure 1(a) an image of the interface zone between the Ag:HAp-PDMS composite layer (the dark zone) and the Ag:HAp layer (the light zone) is presented. The polymer acts as a matrix layer for the Ag:HAp coating. Also, it can be observed that both the Ag:HAp-PDMS composite layer and the Ag:HAp layer are compact and homogeneous with no cracks. In this way, by placing a polymer as interlayer on a material surface intended to be used as substrate for Ag:HAp coating, it is possible to improve its delamination property and thus the adherence of the Ag:HAP layer to the substrate. A high resolution SEM image of the Ag:HAp-PDMS composite layer is presented in Figure 1(b).

3.2. X-Ray Diffraction

XRD patterns of the Ag:HAp nanopowder and the Ag:HAp-PDMS composite layer are shown in Figure 2. All the observed diffraction maxima correspond to the hexagonal hydroxyapatite phase in good agreement with the standard ASTM data (JCPDS number 9-0432). The peaks associated with other phases are not observed. The absence of other phases can indicate an incorporation of SiO2 into the Ag:HAp structure, by substitution of ions with ions [51, 52]. The XRD characterizations of the Ag:HAp-PDMS composite layer are endorsed by the surface morphologies observed by SEM (Figure 1).

3.3. Fourier Transform Infrared Spectroscopy (FT-IR)

In the following section we will present the FT-IR analysis of each component that constitutes the Ag:HAp-PDMS composite layer.

First, we investigated the polymer structure. The IR spectra and the IR bands assignment of the polymer generated from liquid precursors of vinyl terminated PDMS on a silicon substrate function of the angle of the incident light on the sample are presented in Figure 3 and Table 1.

A possible pathway of the polymerization mechanism of the vinyl terminated PDMS precursors involves the breaking of the double bond of the end group and thus the further linkage of the polymeric chains [9].

As we increase the angle of incident light on the sample up to 60°, it can be observed that the band from 1152 cm−1 increases and the band from 860 cm−1 decreases appearing like a shoulder on the new 880 cm−1 band. The increase of the intensities of the 1152 cm−1 and 880 cm−1 IR bands accompanied by the decrease of 860 cm−1 IR band can be understood knowing that, during the polymerization process of PDMS in negative corona discharge, the formation of the new Si-O bonds due to the injection of the negative ions in the liquid precursor bulk is associated with the diminishing of Si-CH3 bonds [9, 53]. Thus, in the polymer layer bulk, mainly at the polymer layer surface SiO2 structures [9] can be generated.

In the same time, in [9] it was mentioned that during the polymerization process of PDMS in negative corona discharge in air at atmospheric pressure some water molecules can be injected into the layer bulk. They can be decomposed in OH groups due to the high electric fields associated with corona discharges [9, 54].

Therefore, the band from 1650 cm−1 present in the IR spectrum of the PDMS polymer, assigned to partly hydrated silica and to the stretching vibrations of adsorbed OH group respectively (Si-OH) [46] indicates the formation of Si-OH group [55]. The existence of the Si-OH in the PDMS layer is also suggested by the formation of the new Si-O bonds by the possible hydroxylation Si-OH + Si-OH = Si-O-Si + H2O reaction [55].

Second, we performed FT-IR analysis on the Ag:HAp-PDMS composite layer. The IR spectra are presented in Figure 4. Furthermore, the IR bands assignment is highlighted in Table 1.

The IR band from 1152 cm−1, Figure 3, is shifted to 1140 cm−1, Figure 4, being visible only in the spectrum obtained for an angle of incident light on the sample of 60°. The shift of this band and its absence in the IR spectra obtained at = 30°, 40°, and 50°, respectively, Figure 4, can indicate the rearrangements of Si and O atoms in the SiO2 structures when an Ag:HAp layer is deposed, by the thermal evaporation technique, on a substrate previously coated with a PDMS film.

The formation of groups was evidenced by the 490 and 695 cm−1 IR bands (Figure 4 and Table 1).

The 1004 and 1071 cm−1 IR bands (Figure 3 and Table 1) seem to be shifted to 995 and 1066 cm−1 (Figure 4), respectively, possibly due to the overlapping of IR bands characteristics to PDMS and Ag:HAp.

In comparison with the IR spectrum of the PDMS layer (Figure 3), in the IR spectrum of Ag:HAp-PDMS composite layer (Figure 4) we can observe a broad band in 3000–3600 cm−1 region due to the adsorbed H2O from the Ag:HAp structure, OH or Si-OH groups [36, 46], its intensity being diminished as we approach the surface of the Ag:HAp-PDMS composite layer (Figure 4). The diminishing of the band intensity as close as possible to the surface layer can be explained if we consider that during the deposition process the Ag:HAp evaporated molecules that travel to the substrate diffuse into the PDMS layer bulk, heating it. During the condensation of the Ag:HAp molecules on the substrate, we suppose that several processes, such as the water evaporation and the generation of some new bonds in the bulk of the Ag:HAp-PDMS composite layer, are taking place.

The IR band from 1650 cm−1 observed in the spectrum of the PDMS layer (Figure 3) is still present in the spectrum of the Ag:HAp-PDMS composite layer (Figure 4). In some previous studies on polydimethylsiloxane/HAp composites [38], it was shown that an IRband at around 1650 cm−1 originates from the deformational vibrations of hydroxyapatite OH groups, which form hydrogen bonds with the siliconate OH groups.

According to previous studies [27, 56], the IR spectral regions specific to chemical bonds present in Si based compounds (mainly Si-O) and HAp (P-O bonds), respectively, are almost similar. Thus, we have performed a peak fitting analysis of the IR spectrum of the Ag:HAp-PDMS composite layer for a proper identification of the processes that take place during its formation (Figure 5). It was previously shown [24, 25, 38, 57, 58] that the overlapping of Si-O and P-O bands could indicate the incorporation of Si based structures in the Ag:HAp.

In Figures 5(a) and 5(b) all the IR bands specific to P-O vibrations in ions and those specific to Si-O bonds in ions which are also summarized in Table 1 can be observed. The appearance of these Si-O peaks might indicate a partial loss of phosphate groups and/or of the symmetry at the site caused by substitution of silicate species in Si-HAp [24, 25]. At the same time, the IR band from 1000 cm−1 (Figure 5(b)) and 925 cm−1 highlights the incorporation of Si into the HAp structure [57, 58]. Jovanovic et al. [38] suggested that the overlap of the Si-O and P-O bands might indicate a substitution of with .

The results of the peak fitting analysis presented in Figure 5(c) reveal the presence of Si-O-Si bonds specific to inorganic silica moiety [29], also asserting their presence in the Ag:HAp-PDMS composite layer. The Si-OH groups are present in the Ag:HAp-PDMS composite layer (Figure 4) due to the formation of the interlinked bonds of Si-O-Ag or Si-O-P type, Figure 5(d). According to [39, 40] a double displacement reaction, Si-O-H + Ag+ = Si-O-Ag + H+, would be expected to have occurred, causing the appearance of Si-O-Ag vibration bands in the FT-IR spectrum of Ag:HAP-PDMS composite layer. Likewise, the Si-O-P bonds can be formed due to the interaction of the siliconate molecules with OH groups from the structure of hydroxyapatite [38].

In Figure 5(e) the results of the peak fitting analysis obtained in the 850–890 cm−1 spectral region where the overlapping of the Si-O, Si-C, , and characteristic bands has previously been explained [20, 25, 30, 32, 34, 35, 4143] are presented.

The peaks associated with all the functional groups present in the IR spectra of Ag:Hap-PDMS composite layer are summarized in Table 1.

3.4. Glow Discharge Optical Emission Spectrometry (GDOES)

In Figure 6(a) the depth profile curves of the Si, O, C, and H atoms in the bulk and at the surface of the PDMS layer are presented.

The depth profiles of the P, Ca, Ag, and O atoms in a Ag:HAp layer were presented elsewhere [20].

In Figure 6(b) it can be observed that the depth profile curves of all the elements identified in the bulk of the Ag:HAp-PDMS composite layer have similar behaviour. There is no sharp delimitation between the Ca, Ag, P, O, and H depth profile curves specific to a Ag:HAp layer and those of Si, O, C, and H atoms present in the PDMS layer. This could result from different causes: roughness of the interface (as the GD averages the signals over the entire erosion zone), flatness of the crater bottom, or formation of a composite material. The operating conditions selected for the present analysis provide a flat crater bottom, while for other similar samples [20] the interface did not indicate any roughness. Therefore, the GD results correlate the observations made and tend to indicate that during the deposition process there are some interactions between the Ag:HAp particles and the polymer and thus the formation of a composite material.

Compared to Figure 6(a), in Figure 6(b), the intensity of the Si depth profile decreases and a broadening of its shape can be also observed. The redistribution of Si atoms in the bulk of the new composite layer emphasizes the possibility of Si involvement in the formation of new Si-O, Si-O-Ag, and Si-O-P chemical bonds. The Si depth profile curves reach a plateau only after the Ca profile curve drops down.

This observation is an indication of silicon atoms involvement not only in the silicon oxide structures, Si-O-Ag or Si-O-P bonds formation, but also in the structure of the Ag:HAp-PDMS composite layer, in accordance with FT-IR investigations. A plateau in a profile curve followed by an increase is an indication of substrate interface. This kind of behaviour of a certain depth profile curve when all the other depth profile curves decrease is generally observed when an element contained in the investigated layer is also present in the substrate material [9, 59].

In the current study we have presented for the first time the formation of an Ag:HAp-PDMS composite layer by deposition of Ag:HAp nanoparticles on a substrate previously coated with a PDMS layer via a simple and reproducible method. The studies of the Ag:HAp-PDMS composite layer are captivating, mainly because of their interesting physicochemical properties and unique structure, which make them attractive for many applications. Due to the presence of Ag in the layer structure, this compound presents a great interest in future biological and biochemical studies. In previous studies [20], it was shown that Ag:HAp thin films have antimicrobial properties against Escherichia coli and Staphylococcus aureus bacteria. According to Shevchenko et al. [40], formation of Si-O-M linkages can be indicated by the shift of Si asymmetric valence band to the field of lower frequencies. On the other hand, the GDOES analysis showed that during the deposition process there are some interactions between Ag:HAp and the polymer thus forming a new composite material. These results are supported by the presence of vibrational bands associated with Si-O-Ag bonds in the obtained IR spectrum (Figure 5(d)) which ascertain the presence of Ag in the structure of the Ag:HAp-PDMS composite layer [40]. Moreover, this study develops a novel and facile method to produce composites based on Ag (Ag:HAp-PDMS composite layer) which can be used for large-scale applications.

4. Conclusions

In this paper a method for the deposition of a Ag:HAp coating on a substrate previously covered with a PDMS layer is presented. As the SEM investigations showed, the PDMS layer acts as a matrix in which the Ag:Hap is incorporated. In this way, a Ag:HAp-PDMS composite layer is formed. The XRD measurements showed that the crystalline form of the Ag-HAP is maintained in the composite layer.

By FT-IR and GDOES spectral techniques we investigated the physicochemical processes that take place during the interaction of Ag:HAp with the PDMS layer. The FT-IR analysis, in agreement with the XRD measurements, showed that the physical procedure used for the generation of the Ag:HAp-PDMS composite layer is useful for the formation of ions. On the other hand, the , ions can be incorporated into the Ag:HAp structures substituting the ions from the structure of Ag:HAp. We suppose that after the condensation of the Ag:HAp on the substrate, due to the heating of the SiO2 network present in the polymer bulk, the ions are generated.

The GDOES depth profiling curves of the Ag:HAp-PDMS composite layer indicate that its composition is homogeneous which can be explained by the formation of the Si-O-Ag and Si-O-P bonds, respectively, and the Si involvement in Ag:HAp structure.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper. The authors also declare that they do not have any other conflicts to declare.

Acknowledgments

The financial and encouragement support provided by the Ministry of Education of Romania, Project nos. PN-II-ID-PCE-2011-3-0958 and PT-PCCA-2011-3.1-1136, is acknowledged.