1. Introduction
Dental implant therapy has had a high success rate with successful maintenance for many years. Nevertheless, peri-implant inflammation is commonly observed after placing dental implants [
1]. Peri-implant diseases have become increasingly relevant with the growing role of implant therapy in modern dentistry. Peri-implant diseases comprise two entities: peri-implant mucositis and peri-implantitis [
2]. Peri-implant mucositis describes an inflammatory lesion residing in the soft tissues, while peri-implantitis describes an inflammatory reaction involving both the soft tissues and the supporting bone around the implant [
3,
4]. A recent systematic review and meta-analysis focused on the prevalence of peri-implant diseases in 47 selected studies with at least a three-year average follow-up period and at least 30 subjects and implants [
5]. Therein, Lee et al. reported weighted mean prevalence of implant- and subject-based peri-implantitis and peri-implant mucositis of 9.25%, 19.83%, 29.48% and 46.83%, respectively.
Removal of bacterial deposits is essential in the treatment of peri-implant infections. Various therapeutic modalities, including chemical and mechanical disruption of peri-implant biofilm, have been shown to have certain beneficial effects on peri-implant infections [
6]. However, biofilm-associated infection may be resistant to antimicrobial therapy without mechanical disruption [
6]. The overall resistance of biofilm bacteria may be attributed to protection by extracellular polymeric substances, the adoption of resistant physiological states or phenotypes, or the horizontal transfer of resistance and virulence genes within the biofilm community [
7,
8,
9]. Non-surgical mechanical treatment was found to be ineffective for peri-implantitis in various clinical trials and reviews [
10,
11,
12]. Hence, surgical and regenerative therapies are preferred for the management of peri-implantitis lesions [
13]. Many implant surface decontamination methods using chemical agents, mechanical debridement, or lasers have been proposed. Several methods or agents, including saline, citric acid, chlorhexidine, air-powder abrasion, hydrogen peroxide, and antimicrobials, have been used for surface decontamination in the surgical management of peri-implantitis lesions, but no agent has been found to be superior [
13,
14]. The use of mechanical instruments such as metal curettes and ultrasonic scalers on titanium is prohibited as it may cause significant implant surface alterations that may lead to plaque attachment [
15,
16]. Subsequently, the application of lasers has been considered for decontamination of implant surfaces.
The wavelengths of lasers most commonly used in periodontics, including diode lasers, neodymium-doped yttrium, aluminum and garnet (Nd:YAG) lasers, erbium-doped yttrium, aluminum and garnet (Er:YAG) lasers and CO
2 lasers range from 819 to 10,600 nm. Of the lasers emitting in the near- and mid-infrared spectral range, the Er:YAG laser exhibits high absorption of its emission wavelength (2940 nm) in water and provides the capability to remove calculus effectively without causing thermal side effects to the adjacent tissues [
16]. The interaction between laser light and metal surfaces is mainly determined by the degree of absorption and reflection. Each metal features a certain spectral reflection capacity that is dependent upon the specific wavelength of the laser. The reflection capacity of titanium for an Er:YAG laser with a 2940 nm wavelength is 71%, whereas the reflection capacity of titanium for a CO
2 laser at 10,000 nm is 96% [
17]. With high reflectivity, the implant surface does not absorb the radiation, and subsequently, there is no temperature increase, which could damage the implant surface. An in vitro study showed a bactericidal effect and no excessive temperature elevation with Er:YAG laser irradiation of different titanium surfaces [
18]. Another in vitro study showed that Er:YAG, CO
2 and diode lasers could achieve a high percentage or complete elimination of surface bacteria on contaminated titanium surfaces [
19]. Other investigations showed that CO
2 and diode lasers did not cause surface alterations following irradiation [
20,
21]. Conversely, Nd:YAG laser irradiation caused extensive surface melting of titanium discs irrespective of output energy [
22]. Studies investigating temperature changes of implant surfaces after laser irradiation showed that diode lasers caused a temperature increase above the critical threshold of 10 °C after only 10 s and was ineffective at removing calcified deposits [
16,
23]. Conversely, use of the Er:YAG laser irradiation for implant treatment was demonstrated without altering the titanium surface if proper settings were applied [
20,
21].
Nevertheless, complete implant surface decontamination using chemical and mechanical procedures has been proven unsuccessful for the following reasons: (1) limited access to implant microstructures, (2) the presence of resistant bacterial strains, (3) ineffective drug dosages and (4) inadequate bactericidal effect [
24]. Several other factors, including the equipment utilized, the macro- and micro-texture of the implant and local anatomy and access, may influence the effectiveness of surface decontamination of biofilm-contaminated implants. In addition, biofilms adhere more strongly to rough implant surfaces than to smooth ones [
25]. Previous in vitro investigations mostly applied laser irradiation to titanium discs with smooth or rough surfaces. These studies were not able to evaluate the effects of anatomical access limitations caused by peri-implant intra-bony defects and macro-structures of implants on the effectiveness of implant surface decontamination in clinical scenarios. Therefore, the aims of the present study were to integrate computer-aided design (CAD), reverse engineering and 3D-printing techniques to establish an experimental model mimicking various peri-implant intra-bony defects of root-form implants with rough surface texture between teeth. We evaluated the influence of access limitation and the effectiveness of biofilm decontamination by an Er:YAG laser in these clinically relevant models. Herein, we demonstrate effective sterilization using Er:YAG laser irradiation in both shallow and deep peri-implant intra-bony defects at different positions and diameters of dental implants.
2. Materials and Methods
To evaluate the effects of access limitation with different peri-implant intra-bony defects on the implant surface sterilization effectiveness of Er:YAG lasers, six groups with shallow or deep peri-implant intra-bony defects surrounding textured-surface dental implants were placed in three positions (mandibular central incisor, first premolar, and first molar). These models mimic clinical peri-implant situations. Five specimens in each group were tested for bacterial adhesion and laser sterilization. All bacterial culture, adhesion and laser sterilization tests were performed using standard operational cabinets in a P1 level laboratory in the Department of Biomedical Engineering, National Yang-Ming University, Taipei, Taiwan.
2.1. Three-Dimensional Peri-Implantitis Model Generation
To simulate the anatomical environments and real relationships between dental implants and adjacent tissues in humans, 3D digital models of dental implants (3 mm, 4 mm and 5 mm diameters; 11.5 mm length) with sandblasted large-grit acid-etched surfaces (Anker SB, Alliance Global Technology Co., LTD. Kaoshiung, Taiwan) were generated. A plastic human adult standard dento-alveolar model (PRO2001-UL-SP-FEM-28, Nissin Dental Product Inc., Kyoto, Japan) was used for reverse engineering and CAD techniques according to our previous study [
26] (
Figure 1a). Three dental implants with 3 mm, 4 mm, and 5 mm diameters were placed at the left mandibular central incisor, first premolar, and first molar positions in the human dento-alveolar model, respectively. Shallow and deep peri-implant intra-bony defects with 2 mm or 6 mm depths, respectively, were then created with 1.8 mm crestal width and 1.5mm apical width around the implants (
Figure 1b and
Table 1). Experimental models constructed with acrylonitrile butadiene styrene (ABS) (ABS-P430, Stratasys, Ltd., Eden Prairie, Minnesota, USA) with peri-implant defects at mandibular incisor, premolar, and molar positions were printed using a 3D printer (Dimension 1200es SST, Stratasys Inc., Eden Prairie, Minnesota, USA) (
Figure 1c). Six groups (three implant positions and two types of intra-bony defect) with five specimens per group were used in the experiments.
Three types of cylindrical suites 7.5 mm in height, 5, 6, or 7-mm in diameter and 1.5 mm in thickness with a 2 mm-wide side key for connection to respective dental implants at the positions of mandibular incisor, premolar, and molar were designed. This permitted the suite to be replaced for individual bacterial adhesion experiments. The dental implant and suite comprised one experimental unit with which bacterial culture experiments were performed (
Figure 2). The shallow (2 mm) and deep (6 mm) peri-implant intra-bony defect digital models and suite models were printed by 3D printer and transferred to ABS dento-alveolar models (
Figure 1b,c and
Figure 2b,c).
2.2. Bacterial Culture and Adhesion on Implants
In a standard operation cabinet, suspensions of Gram-negative Escherichia coli (ATCC®25922™ KWIK-STIK, Microbiologics Inc., St. Cloud, Minnesota, USA) in sterile saline solution were prepared by adjusting the turbidity to an optical density (OD) equivalent to a concentration of 107 colony forming units (CFUs)/mL using a spectrophotometer at a 600 nm wave length (DU800, Beckman Coulter, Fullerton, CA, USA).
Five specimens (implants with 6 mm bone defects and corresponding suites) in each implant group representing the mandibular incisor, premolar, and molar positions were incubated with bacterial suspension solutions at 37 °C for 24 h. Two milliliters of medium were added to centrifuge tubes. The OD of the suspension diluted 10:1 was measured using a spectrophotometer. Plate counts were performed after 5 min of shaking using an ultra-sonicator (Elmasonic P, Elma Group Inc., Pforzheim, Germany) with a frequency 37 kHz at 21 °C. The adhesion rates were calculated using the following formula:
(Nar = bacterial adhesion rate (percentage), Na1 = bacterial adhesion to the implant, Na0 = number of bacteria in the original bacterial solution).
2.3. Erbium-Doped Yttrium, Aluminum and Garnet (Er:YAG) Laser Sterilization of Contaminated Implants
Specimens were assembled into 3D human dento-alveolar models and attached to a simulation manikin (KaVo EWL Dental Simulation Unit Phantom Head, KaVo Dental GmbH, Biberach, Germany) for laser sterilization experiments (
Figure 3). The laser sterilization tests were performed with shallow (2 mm) or deep (6 mm) peri-implant intra-bony defects around textured-surface dental implants placed in three positions (mandibular central incisor, first premolar, and first molar) using 5 specimens per group. Each implant specimen contaminated with bacteria was irradiated with an Er:YAG laser (Er:YAG laser, LightMed Dental Technology Corp., Taiwan) at 100 mJ/10 Hz and 2c.c./min water irrigation in non-contact pulse mode with a chisel-shaped sapphire tip (0.6 × 1.7 mm diameter at the tip) for 60 s (
Figure 3). The application tip was moved across the buccal surface of the implant thread to the lingual and apical surfaces and finally to the root.
The abutment of the implant was placed into a centrifuge tube for bacteria count. Bacteria were counted by plate count after 5 min of shaking using an ultra-sonicator as described above. T-tests were used to evaluate statistical differences between implant positions and bone defect depths.
The Er:YAG dental laser sterilization rate was calculated using the following formula:
(Nsr = sterilization rate, Ns1= bacterial adhesion to the implant after irradiation, Ns0= number of bacteria in the original bacterial solution).
3. Results
To assess the effects of access limitation in the context of peri-implant intra-bony defects and local anatomical structures, a 3D-printed human dento-alveolar model with substitutable implant unit sets (implant and suite) representing shallow or deep peri-implant intra-bony defects was designed by integrating reverse engineering, CAD, and 3D printing techniques. The fabricated peri-implant intra-bony defect ABS model can also be attached to a simulation manikin to mimic clinical treatment scenarios (
Figure 1,
Figure 2 and
Figure 3).
The rate of adhesion of Gram-negative
Escherichia coli to the investigated implant surfaces ranged from 1% to 3% (1.76
1.25% on the 3 mm implant, 2.19
0.75% on the 4 mm implant and 2.66
1.26% on the 5 mm implant, respectively) (
Table 2). The results of laser irradiation experiments showed that sterilization rates with shallow (2 mm) peri-implant bony defects were 99.6 ± 0.5%, 99.3 ± 0.41%, 93.8 ± 7.65% at mandibular incisor (3 mm), premolar (4 mm) and molar (5 mm) positions, respectively (
Table 3). Similarly, the corresponding sterilization rates with deep (6 mm) intra-bony defects were 99 ± 1.35%, 99.1 ± 0.98% and 97.14 ± 2.57%, respectively (
Table 3). However, no significant differences (
p > 0.05) in sterilization rates were found between implant positions and bone defect depths.
4. Discussion
This study established an in vitro model mimicking clinical peri-implant intra-bony defects. We investigated the effects of access limitation and the bactericidal effectiveness of Er:YAG laser irradiation in shallow and deep peri-implant defects at different tooth positions. Most previous in vitro studies investigating the effects of bacterial adhesion and the cleaning effects of different instruments have used titanium discs instead of root-form dental implants [
19,
20,
21,
22,
27,
28]. Other studies utilized root-form dental implants embedded in resin blocks [
23]. The effects of implant surface topography and surrounding bony defects on the efficacy of cleaning contaminated implant surfaces cannot be accurately evaluated using these models. Utilizing designable, re-printable 3D models with replaceable suites, the present study showed effective sterilization using Er:YAG laser irradiation with both shallow and deep peri-implant intra-bony defects at different positions and diameters of dental implants.
The effectiveness of laser irradiation on contaminated implant surfaces in a peri-implant defect may be influenced not only by the bony defect configuration, but also by peri-implant tissues in clinical or in vivo studies. Authors of a systematic review regarding periodontal and peri-implant wound healing following laser therapy stated that non-surgical therapy may not be sufficient for the healing of peri-implantitis sites [
29]. The authors also found that the erbium lasers are advantageous in peri-implant surgery because of their favorable bone healing potential. Renvert et al. reported that surgical therapy is a predictable method for treating peri-implantitis but laser treatment of the exposed implant surface during surgery was not shown to be beneficial [
30]. Considering the limited information currently available and the wide heterogeneity of clinical studies, superiority of laser treatment over conventional treatment of peri-implantitis has not been conclusive, although surgical laser therapy of peri-implantitis is able to achieve clinical improvement [
31]. Controversial data may be reported because of the inherent heterogeneity in clinical and in vivo studies, although these studies are critical for the evaluation of implant cleaning procedures. The effectiveness of laser irradiation on the implant surface in non-surgical therapy may be significantly influenced by peri-implant soft tissues. Effects of peri-implant bony defect configurations on surgical therapy after flap reflection are expected to be greater than those of peri-implant soft tissues. To investigate the effects of the peri-implant soft tissues on the effectiveness of laser irradiation in non-surgical treatment, the models currently described mimicked surgical treatment situations for peri-implantitis with shallow and deep intra-bony defects. By integrating CAD and 3D-printing techniques to construct a standard in vitro laser treatment platform, this study provides an integrated process to investigate the effects of access limitation and defect configurations on the effectiveness of cleansing contaminated implant surfaces.
The present study investigated the sterilization effect of Er:YAG laser irradiation in shallow and deep peri-implant intra-bony defects that simulate clinical situations. Er:YAG laser irradiation effectively sterilized implants with both shallow and deep peri-implant bony defects in these models at mandibular incisor, premolar, and molar positions. There was no significant difference of sterilization effects between shallow and deep intra-bony defects using Er:YAG laser irradiation. A slightly lower sterilization rate was observed with the wider implants in the mandibular posterior region; however, these results were not statistically significant. Few studies have investigated the influence of defect configurations on implant surface decontamination. Schwarz et al. investigated two surface debridement/decontamination methods with intra-bony (class Ib, Ic, Ie) and supra-bony (class II) defects in patients with peri-implantitis [
32,
33,
34]. Although these studies failed to demonstrate a significant impact of the surface decontamination method [
32,
34], a potential impact of defect configuration on clinical outcome following combined surgical therapy for advanced peri-implantitis lesions was identified [
33]. The results of this study coincided with literature indicating that the decontamination effects of Er:YAG lasers were similar in different peri-implant intra-bony defect configurations with a proper contact tip and parameter settings [
32,
34]. In the present study, shallow (2 mm) and deep (6 mm) peri-implant intra-bony defects were created with similar crestal apical widths of 1.8 mm and 1.5 mm, respectively (
Figure 1a,
Table 1). Considering the similar macro- and micro-topography of the implant models and similar dimension of intra-bony defects, the differences in sterilization rates between the three types of implant specimens may have been related to differences in implant surface area, the position of implants in the dental arch or access limitation by local anatomic structures including the buccal cheek. Further investigations are necessary to evaluate the effects of implant positions in dental arches and adjacent dental/facial anatomic features.
Although the clinically beneficial effects of mechanical and chemical interventions to disrupt peri-implant biofilms demonstrate convincingly that microorganisms are involved in the disease process, there is no evidence for the existence of one or a limited number of specific pathogens causing peri-implantitis. Previous microbiological findings in an experimental peri-implantitis model mimicking natural disease progression supported the notion that large variation in microbial profiles makes interpretation of a correlation between disease progression and specific microbes difficult [
35]. In the current study, Gram-negative
Escherichia coli was used to investigate bacterial adhesion and effects of laser decontamination on titanium implant surfaces. Although the biofilm compositions on contaminated implant surfaces in peri-implant diseases are complex and dominated by Gram-negative anaerobes [
6,
35,
36], several in vitro studies utilized single species bacterial biofilms for the investigation of implant surface contamination [
18,
19,
22].
The adhesion rate of Gram-negative
Escherichia coli on the investigated implant surfaces prior to Er:YAG irradiation ranged from 1% to 3% (
Table 2). Although these percentages seem low, the number of adhering bacteria reached 10
6 CFU/mL, which was equivalent to that described in the literature [
27,
28]. Studying the effect of surface roughness of titanium implants on the adhesion and removal of bacterial contamination, Chen et al. found no significant difference in
Escherichia coli bacterial adhesion among surfaces of varying roughness, except in 50 μm and 250 μm Al
2O
3 sandblasting groups at 12 h of culture [
27]. The cleaning modalities investigated did not induce significant surface alterations. However,
Escherichia coli adhesion was significantly reduced by air-powder abrasion and Er:YAG laser debridement in comparison to plastic curettage. The authors concluded that laser debridement could be a useful cleaning method for peri-implantitis therapy. Another in vitro study investigated bacterial adhesion on smooth and rough titanium disc surfaces after treatment with four different instruments using single species
Streptococcus sanguinis (American Type Culture Collection 10556) bacterial suspensions [
28]. The authors found that smooth titanium surfaces were altered significantly by metal curettage, yet there were no significant rough surface alterations before and after treatment with Er:YAG laser irradiation, plastic curettage, metal curettage, or air-powder abrasion. The findings of the present study were in line with the literature, showing that significant effectiveness of sterilization by Er:YAG laser irradiation could be achieved on
Escherichia coli-contaminated rough titanium implant surfaces.
In the present study, clinical situations were simulated by real implant fixture placement in a 3D-printed standard human adult dento-alveolar model attached to a simulation manikin. However, effects of saliva and blood could not be simulated under the present experimental conditions. Considering the limitations of this model, it was difficult to determine whether implant diameter or access limitation caused a non-significant lower sterilization rate in wider implants at the mandibular posterior region. We concluded that effective sterilization rates could be achieved with Er:YAG laser irradiation with a proper contact tip and parameter settings irrespective of the depth and configuration of peri-implant intra-bony defects. Further studies are necessary to investigate similar effects on biofilms or multiple-species bacterial cultures. The use of integrated CAD and 3D-printing techniques to construct an in vitro laser standard treatment platform with different intra-bony defect configurations is demonstrated herein. Furthermore, these models were reverse-engineered from real peri-implantitis cases to visualize and simulate treatment procedures prior to surgery.