Background
Many types of graft materials have been used for the reconstruction of the maxillofacial region [
1]. Although autogenous bone grafting is the gold standard, the amount of available bone is limited, and donor site morbidity has been reported [
2]. Xenografts are widely used in the dental field, and many of them are bovine-originated xenografts [
3]. For the successful bone graft procedure, timely degradation of the graft is essential for new bone regeneration. However, most xenografts and allografts have poor biodegradability [
4,
5]. If the graft is not degraded in a timely manner, the space occupied by the graft cannot be replaced by newly regenerated bone.
4-Hexylresorcinol (4HR) is a family of resorcinolic lipids [
6]. 4HR is a well-known antiseptic [
7] and reduces the melanosis of food [
8]. Therefore, it has been used for oral gargling [
7], for treatment of sore throat [
9], or as a food ingredient [
7]. Recently, its molecular mechanism was unveiled in a cancer cell study. 4HR suppresses calcium oscillation [
10] and the nuclear factor-kB (NF-kB) pathway [
11]. 4HR can induce cellular differentiation via increasing the expression of keratin 10 and involucrin [
12]. These antiproliferative properties of 4HR have synergistic effects when it is used with conventional anticancer drugs such as cisplatin [
13].
As 4HR can suppress the NF-kB pathway [
11], it may also influence osteoclast activity. The NF-kB pathway is important in osteoclast activation [
14]. If 4HR inhibits the NF-kB pathway during bone regeneration, more bone formation can be anticipated. Actually, hydroxyapatite (HA) coating with 4HR in a dental implant shows better bone formation than just HA coating without 4HR [
15]. As osteoclasts are also a type of multinucleated cell, 4HR can suppress formation of multinucleated cells [
16]. This action is helpful for the inhibition of the reaction to foreign bodies induced by silk materials and results in better bone formation [
16]. Silk is a poorly degradable material when it is implanted in the body [
17]. 4HR also accelerates degradation of silk graft materials [
16,
17].
Collectively, xenografts treated with 4HR have been shown to suppress the reaction to foreign bodies and to promote rapid degradation of poorly biodegradable materials. The objective of this study was to evaluate xenograft degradation velocity upon treatment with 4HR.
Methods
Graft preparation
The scapula of a cow was purchased from a local grocery. Using trephine bur (diameter 8.0 mm), round bone grafts were cut at a thickness of 1.0 mm. The control bone was placed into a conical tube containing a 10 % ethanol solution, and the experimental bone was placed in a 10 % ethanol and 3 % 4HR solution. These tubes were placed on a rotating machine for 24 h. Then, the grafts were placed in the drying oven for 8 h. They were sterilized with ethylene oxide gas and stored at room temperature before usage. The weight of dried grafts was measured and the amount of 4HR incorporation into the experimental bone was between 10 to 15 % by weight.
X-ray diffraction, Fourier transform infrared absorbance spectra, and endotoxin test
X-ray diffraction (XRD) patterns of the samples were collected in the range of 10 to 60° (2θ) using a diffractometer (PANalytical, X’Pert Pro MPD) with a Cu-Kα (λ = 1.5418 Å) radiation source. Fourier transform infrared (FT-IR) spectrum measurements were carried out using a Vertex 80 (Bruker Optics, Germany) spectrometer coupled with a Hyperion 3000 (Bruker Optics, Germany) microscope equipped with a germanium attenuated total reflectance objective lens (ATR ×20) and a liquid nitrogen-cooled mercury cadmium telluride detector.
An endotoxin test was performed using a commercial kit, and the subsequent procedure was in accord with the manufacturer’s protocol.
Antibacterial test
Two oral pathogens (Streptococcus sanguinis, ATCC 10556, and Aggregatibacter actinomycetemcomitans, ATCC 33384) and Staphylococcus aureus (ATCC 502A) were used for antibacterial tests. The bacterial strains were cultured with brain heart infusion (BHI) (Becton, Dickinson and Company, Sparks, MD, USA) broth under aerobic conditions supplemented with 5 % CO2. S. aureus was also cultured under aerobic conditions.
The control disc and experimental disc were placed on the surface of blood agar plates (Hangang, Gunpo-si, Korea) for S. sanguinis and S. aureus and BHI plates for A. actinomycetemcomitans. For comparison, two different types of antibiotic discs (vancomycin and penicillin) were also used. The plates of S. sanguinis and A. actinomycetemcomitans were incubated at 37 °C aerobically supplemented with 5 % CO2 for 2 days. For S. aureus, the plates were incubated at 37 °C aerobically for 1 day. The maximum diameter of the inhibition zone was observed.
Scanning electron microscopic examination with EDX microanalysis and cellular attachment assay
The specimens were coated with 0.7 nm of OsO4 (HPC-1SW, Japan). Each specimen was observed using a scanning electron microscope (Hitachi, SU-70) and underwent EDX microanalysis (EDAX Genesis; Pv 77, EDAX, USA) to analyze the elements of the area of interest. The compositions of the elements were compared.
Murine macrophages from the Cell Bank (RAW264.7; Korean Cell Line Bank No. 40071) were grown on the control and experimental discs. The growth of the cell culture was stopped at 1 h after seeding by fixing the samples. All materials including raw materials were prepared for scanning electron microscopic examination. After immobilization of the samples on the plate, each sample was coated with gold and examined using a scanning electron microscope (H-800, Hitachi, Japan).
Animal experiment
This animal study was approved by IACUC (GWNU-2014-14). Seventeen 12-week-old Sprague-Dawley rats with an average weight of 300 g were used for this experiment. A dental-trephine bur was used under copious saline solution irrigation to form a full-thickness calvarial defect. An 8-mm-diameter defect was created on the rat parietal bone, and the control graft or experimental graft was placed in the defect. The control group consisted of eight animals, and the experimental group included nine animals. After the grafting procedure, the pericranium and skin were sutured with 3-0 black silk. The animals were sacrificed 6 weeks after the operation.
Histological analysis
The calvarial samples were subjected to dehydration and embedding. The segments were embedded to show the sagittal sections in paraffin blocks. The paraffin blocks were sliced (5 μm) and stained with hematoxylin and eosin. The detailed staining procedure followed the standard method in the manufacturer’s manual. The selected sections were photographed with a digital camera (DP-73; Olympus, Tokyo, Japan). The images were analyzed with Sigma Scan Pro (SPSS, Chicago, IL). The ratio of the remaining graft was calculated based on the ratio of the remaining graft to the original size of the graft.
Statistical analysis
An independent sample t test was used to compare the control and experimental groups in the animal study. The significance level was set at P < 0.05.
Discussion
In this study, bovine bone obtained from a local grocery was used for the repair of rat calvarial defect after simple processing. 4HR-treated bovine bone had antibacterial properties, and RAW264.7 cells were well attached to the surface of the 4HR-treated bovine bone. 4HR-treated bovine bone had a higher degradation rate than the untreated control. However, its degradation velocity was too rapid and did not contribute to new bone regeneration.
4HR is a family of hydroxyl phenols [
6]. 4HR has two –OH groups. A H
+ ion can be released from –OH groups of the benzene ring, and the 4HR has acidic properties [
20]. Therefore, the concentration of 4HR in the bone graft should be carefully monitored. If the concentration of 4HR is too high and is used for HA-based bone graft materials, H
+ ions released from the graft would decrease the pH locally and result in massive loss of calcium from the graft. Although all prepared graft materials came from the same conical tube, some grafts might not have been exposed to 4HR. As a result, there might be a variation in the 4HR concentration among grafts. Based on the weight change of the graft, the 4HR concentration of each graft was expected to range from 10 to 15 % by weight. HA incorporating gluconic acid is almost completely degraded 2 weeks after surgery [
4]. The amount of acid and the release pattern would influence the overall degradation velocity of HA [
4]. In a previous study, 3 % wt 4HR in HA or silk was not shown to accelerate graft loss [
16]. Therefore, lower concentration of 4HR should be used for bovine bone graft in future study.
4HR can induce cellular apoptosis dependent on its concentration. In the case of epithelial cancer, the apoptosis-inducing concentration is much lower than that of the normal dermal fibroblast [
12]. As the 4HR concentrations of grafts were relatively higher than those of a previous study [
16], high concentrations of 4HR might induce apoptosis responsible for graft degradation in some cases. Sintered bovine bone graft and synthetic HA are biodegraded by osteoclasts [
21] or macrophages [
22]. The exact concentration of 4HR required for apoptosis in these cells is yet to be determined. The bovine bone used for the implant may have been treated by heat. However, chemically treated bovine bone has better mechanical properties than heat-treated bone [
23]. As 4HR treatment is a chemical treatment, it would not influence the bone’s original mechanical property.
In this study, the control group showed new bone deposition bordering the graft (Fig.
7d). Mixed bovine bone grafted in the rat calvarial defect was not completely degraded at 9 months, while new bone formation was observed in the defect border [
24]. There was no inflammation around the graft in the control group (Fig.
7a, d). As the control group was only treated with 24 h ethanol washing, using a graft material process that originates from bovine bone may be considered in the future. The graft materials in this study were sterilized by ethylene oxide. As demonstrated in the EDX analysis results, many organic components may remain in the bovine bone. Bio-Oss also has residual proteins [
25]. The ethylene oxide sterilization does not reduce osteoinductivity of bone morphogenetic proteins [
26]. Therefore, bone morphogenetic proteins in the bovine bone would not be destroyed by ethylene oxide. Only the concentration of 4HR in the graft appeared to be unknown in this study. The optimal 4HR concentration for bone graft should be determined in future studies.
Conclusions
In this study, 4HR was successfully incorporated into bovine bone, and 4HR-incorporated bovine bone had antibacterial property. The in vivo experiment demonstrated that 4HR-incorporated bovine bone showed more rapid degradation than untreated bovine bone. However, 4HR-incorporated bovine bone graft did not show elevated new bone formation.
Acknowledgements
The authors thank Hyo-Seon Kim and Min-Keun Kim for their help in the experiments. This work was carried out with the support of “Cooperative Research Program for Agriculture Science and Technology Development (Project No. PJ01121404)”, Rural Development Administration, Republic of Korea.