Definition, etiology, prevention and treatment of peri-implantitis – a review

One of the main aims of peri-implant therapy is to detoxify the contaminated implant surface. In the presence of peri-implant mucositis, non-surgical methods are appropriate and sufficient for detoxification. These include mechanical implant cleaning with titanium or plastic-curettes, ultrasonics or air polishing. Moreover, photodynamic therapy as well as local antiseptic medication (chlorhexidinglukonate, hydrogen peroxide, sodium percarbonate, povidone-iodine) may support the antimicrobial therapy.

In two randomized clinical trials Heitz-Mayfield et al. and Hallström et al. were not able to prove any benefits in reduction of pocket depth, plaque index or purulency when adjuvant antimicrobial therapy (chlorhexidine and azithromycine) was used in addition to mechanical therapy only [50, 51]. Reductions of the bleeding index were explained by the general improvement of oral hygiene with reference to the potential importance of guidelines and treatment protocols [50‐52]. The establishment of an adequate oral hygiene should, therefore, be considered as key issue of the prevention of peri-implant infections. Besides, a maintenance program with regular evaluation of the peri-implant probing depths, supportive professional implant cleaning and oral hygiene training should be integral part of every post-operative care after implant insertion [2, 6].

Most of the published strategies for peri-implantitis therapy are mainly based on the treatments used for teeth with periodontitis. The reason is that the way of bacterial colonization of dental and implant surfaces follow similar principles, and it is commonly accepted that the microbial biofilm plays an analogous role in the development of peri-implant inflammation [53]. For the treatment of peri-implantitis, both conservative (non-surgival) as well as surgical therapies can be applied. Thereby, the surgical treatments can be done using resective or regenerative approaches [54‐59].

In addition to medication and manual treatment (e.g. with curettes, ultrasonic and air polishing systems) innovative techniques such as laser-supported and photodynamic therapy methods are recently described as conservative therapy options.

Basic manual treatment can be provided by teflon-, carbon-, plastic- and titanium curettes (Figure 2).

Due to the fact that therapy with conventional curettes is able to modify the implant surface and can roughen the surface, it has been recommended that the material of the tip should be softer than titanium [60, 61]. It is possible to reduce bleeding on probing scores by cleaning with piezoelectric scalers as well as with hand instruments, and no differences have been found between these methods concerning reduction of bleeding on probing, plaque index and probing depths after at least 6 months [62, 63].

As to the above-mentioned methods, the efficacy of ultrasonic curettage seems to underly the use of air polishing systems (Figure 3) [5, 62, 64‐68]. Persson et al. and Renvert et al. experienced significantly lower numbers of bacteria with partial reduction of plaque and bleeding scores after mechanical curettage, while Schwarz et al. reported 30%-40% less residual biofilm areas by using ultrasonic methods [5, 63, 66]. Depending on the surface topography of the implants, Louropoulou et al. recommend different therapeutic methods (Table 3).

The results of air polishing systems are depending on the used medium and are significantly better in the following order: hydroxylapatite/tricalcium phosphate > hydroxylapatite > glycine > titanium dioxide > water and air (control group) > phosphoric acid [64].

An abrasive air polishing medium can modify the surface of implants. After air powder treatment cell attachment and cell viability still showed sufficient levels, but cell response was decreased compared with sterile surfaces [64, 65, 67]. The extent of re-osseointegration of titanium implants after air polishing therapy has been reported between 39% and 46% with increased clinical implant attachment and pocket depth reduction [65]. The occurrence of bleeding on probing, one of the qualitative parameters in the presence of a peri-implantitis, could be significantly reduced [67].

There are numerous in vitro and in vivo studies on the application of medicaments as part of the treatment of mucositis and peri-implantitis. However, due to differences in the design of all studies, comparison of these studies is difficult. The following therapies can be distinguished:

In a review by Javed et al., summarizing nine studies, systemic and local antibiotic applications (e.g. tetracycline, doxycycline, amoxicillin, metronidazole, minoxicycline hydrochloride, ciprofloxacin, sulfonamides + trimethoprim) led to significant reductions of pocket depths in a period between one and six years [69]. Moura et al. noticed the same for resorbable doxicycline releasing nanospheres in local application over a period of 15 months [70]. Leonhardt et al. noticed an overall success rate of 58% when treating peri-implantitis with surgical debridement and the use of various antibiotics and combinations of them (including clindamycin, amoxicillin + metronidazole, tetracycline, ciprofloxacin) [71].

Astasov-Frauenhoffer et al. were able to prove complete growth-inhibiting effects of amoxicillin and metronidazole on Streptococcus sanguinis, Porphyromonas gingivalis and Fusobacterum nucleatum apart from each other, but the combination was found to be more efficient than metronidazole alone [72]. Comparing local antibiotic therapy with photodynamic therapy, Bassetti et al. presented no differences in reduction of pocket depths or reduction of the number of bacteria in the periodontal pockets [73]. Grapefruit juice, known as antioxidant, had only a bacteriostatic effect against Streptococcus aureus[74]. But is has to be considered that depending on the type, bacteria demonstrate different high resistances against antibiotics (Table 4). Submucosal biofilm specimens were cultured from patients with peri-implantitis and after in vitro testing for susceptibility especially the combination of amoxicillin and metronidazole showed significant lower resistances (6.7%) [22].

Application of chlorhexidine resulted in the reduction of pocket depths, a higher implant adhesion and general weakening of inflammation measured by the level of the inflammatory markers IL-1 beta, VEGF and PGE-2 in various studies [75‐77]. Compared to minocycline microsphere application repeated every three months [78], the treatment with 1% chlorhexidine gel resulted in significantly less reduced pocket depths after 12 months. Concerning tissue engineering, Lan et al. demonstrated a continuous release-kinetic of metronidazole for 30 days using a Poly-ϵ-Caprolacton/Alginat-ring [79]. Hou et al. incorporated fluorouracil into cylindrical poly-ϵ-caprolactone-implants of different diameters [80].

Local or systemic antibiotics are an additional therapy option. In combination with other conservative or surgical treatments it results in more efficient reductions of clinical peri-implantitis symptoms [81]. Just administration of antibiotics is no treatment option.

By means of a bactericide mode of action, CO₂, Diode-, Er:YAG- (erbium-doped: yttrium-aluminum-garnet) and Er,Cr:YSGG- (erbium, chromium-doped: yttrium-scandium-gallium-garnet) lasers are used in the treatment of peri-implant diseases with increasing frequency. Minimal absorption and reverberations must be ensured with the purpose to protect implant and tissue. Er:YAG and Er,Cr :YAG with a wavelength of 3 microns can reduce biofilms up to 90% but in contrast to most mechanical therapies any biological compatibilities and cell stimulatory properties can’t be re-induced [5, 82, 83]. Treatment with a CO₂ 308 nm excimer laser, however, led mainly and efficiently to satisfactory results in an anaerobic bacteria spectrum [84].

In comparison to mechanical methods (plastic curettes), treatments with an Er:YAG laser led to significantly better results in terms of bleeding at peri-implantitis. However, both methods showed no significant differences in changes of pocket depths, clinical attachment level, plaque index and gingival recessions, although in both groups these parameters were improved [85].

Persson et al. examined the effectiveness of Er:YAG lasers compared to an air polishing system in a randomized clinical trial with 42 patients over 6 months [86]. Except for different reducing effects on specific bacteria strains after one month (Er:YAG: Fusobacterium nucleatum; air polishing system: Pseudomonas aeruginosa, Staphylococcus aureus and Peptostreptococcus anaerobius) there were no long term-reducing effects shown after 6 months. In a recent study Mailoa et al. showed that laser therapy resulted in similar reductions of probing depths when compared to other decontamination methods [87]. Although there is only few data in comparison to manual and surgical therapy, laser therapy as a treatment option has to be considered as an adjunct. Further studies are needed to evaluate the profit of laser therapy in peri-implantitis treatment.

Photodynamic therapy generates reactive oxygen species by multiplicity with help of a high-energy single-frequency light (e.g. diode lasers) in combination with photosensitizers (e.g. toluidine blue). In a wave length range of 580 to 1400 nm and toluidine blue-concentrations between 10 and 50 ug/ml, photodynamic therapy generates bactericide effects against aerobic and anaerobic bacteria (such as Aggregatibacter actinomycetemcomitans, Porphyromonas gingivalis, Prevotella intermedia, Streptococcus mutans, Enterococcus faecalis) [5, 88, 89]. The only prospective randomized clinical trail by Basseti et al. covered 12 months of follow-up. After manual debridement by titanium curettes and glycine air powder treatment half of the patients received adjunctive photodynamic therapy and the other half received minocycline microspheres into implant pockets. After 12 months, the number of periopathogenic bacteria and level of IL-1β decreased significantly in both groups without significant differences between them [73]. In a study by Deppe et al. regarding to the effectiveness of phototherapy on a moderate and severe peri-implantitis, both clinical attachment and bleeding index were significantly reduced suggesting that severe cases still resulted in bone resorption [90].

As a recommendation, photodynamic therapy has to be considered as an additional treatment option. Due to the fact that it is a relatively new approach, the data is rare and there are no long-term-studies available. Further evaluations and prospective clinical trials are needed for evaluation.

The surgical therapy combines the concepts of the already mentioned non-surgical therapy with those of resective and/or regenerative procedures. The indication for the appropriate treatment strategy has been demonstrated in patient studies leading to the development of the “cumulative interceptive supportive therapy (CIST)” concept [91‐93]. In 2004 it was modified and called AKUT-concept by Lang et al. (Table 5) [93]. The basis of this concept is a regular recall of the implanted patient and repeated assessment of plaque, bleeding, suppuration, pockets and radiological evidence of bone loss.

A further commonly accepted concept by Zitzmann et al. is referred to systematic periodontitis therapy. During the initial phase oral hygienic conditions have to be improved and mechanical cleaning and local antiinfective treatments are applied, if necessary. If non-surgical treatment fails, surgical intervention with open debridement and resective or regenerative therapy is recommended [3]. The concept of Schmage follows the CIST-protocol but recommends always mechanical and local disinfective treatments in stage A and B. Intervention should be performed if probing depths exceed 5 mm or are progressive as well as under occurrence of local inflammation signs [94].

In analogy to periodontitis, resective surgery has been shown to be effective in reduction of BOP, probing depths and clinical signs of inflammation. The basic principles include the elimination the periimplant osseous defect using ostectomy and osteoplasty as well as bacterial decontamination (Figures 4 and 5). Additionally, smoothening and polishing of the supracrestal implant surface (implantoplasty) may be applied.

Serino et al. showed that in patients with active peri-implant disease surgical pocket elimination and bone re-contouring in combination with plaque control before and after surgery represents an effective treatment. Two years after open reduction of inflammated peri-implant soft tissue and osseous surgery 48% of the patients had no signs of peri-implantitis and 77% of the patients had no implants with pocket depths ≥ 6 mm with bleeding and/or suppuration [56].

In a radiographic study with 3 years follow-up, Romeo et al. showed that the marginal bone loss after resective surgery with implantoplasty was significantly lower than after resective therapy only [55]. The group with additional implantoplasty also had significantly lower probing pocket depths, probing attachment levels and modified bleeding indices after 24 months [54].

Adjuvant implant surface decontamination with antimicrobial substances led to an initially less anaerobic bacteria contamination, but did not improve the clinical outcome [75].

Resective surgical therapy for peri-implantitis is a recommendable therapy option. Ostectomy and osteoplasty combined with implantoplasty represent an effective therapy to reduce or even stop peri-implantitis progression. Nevertheless, due to the increased postoperative recessions, this procedure is not suitable for every situation, especially in highly esthetic sensitive areas.

Resective surgical therapy may result in re-osseointegration in only minor superficial defects. From functional, esthetic and long-time-survival point of views, full regeneration and re-osseointegration is aspired. In animal models it was possible to regenerate experimentally induced defects using various graft materials and/or resorbable membranes following the principles of guided bone regeneration (GBR) (Figures 6, 7, 8, 9 and 10).

In a study by Hürzeler et al. in 1997 in dogs, there was no significant difference between the application of membranes only versus membranes in combination with bone grafts (canine demineralized freeze-dried bone or hydroxyapatite) in terms of bone regeneration. However, the combination resulted in a greater amount of re-osseointegration [95]. No statistical differences in re-osseointegration could be demonstrated after treatment with GBR using a e-PTFE reinforced membrane compared to sites without this membrane [96]. The treatment resulted in 60–80% bone fill of the bony defect, but the absolute amount of re-osseointegration was small (between 0.1 - 0.6 mm).

In contrast to debridement with surface decontamination, in most of all animal studies regenerative methods were reported as more efficient. In general, GBR alone and bone fill alone have been shown to be more effective than debridement alone regarding to bone regeneration and re-osseointegration. The results of studies using a combination of membranes and bone graft materials were superior to those using membranes or bone grafts alone and tend to give the best results, However, there is a high variability in the amount of bone fill due to different investigation protocols and measurements [97‐99] and not in all studies there was a benefit for these treatments compared to debridement alone [100‐102]. The role of submerged healing in peri-implantitis has not been solved clearly. Although Singh et al. demonstrated in 1993 greater bone regeneration and re-osseointegration during submerged healing, Grunder et al. found no differences between either healing method [103, 104].

Additionally, there are numerous studies regarding the treatment of peri-implantitis in humans under regenerative aspects. In a retrospective study of Lagervall et al. with 150 patients (382 implants) the most widely used operative intervention was the periodontal flap with osteoplasty (47%), followed by the use of bone replacement materials (20%). A cumulative success rate of 69% was recorded for both procedures, which was significantly lower in patients with risk factors such as smoking, periodontal disease and poor oral hygiene [29]. Regarding to a “regenerative” approach, autologous, allogenic and xenogenic bone replacement materials are often used for augmentation in bone defects used with or without collagen membrane. Allogenic and xenogenic grafts may be almost equivalent to autogenous material [105‐107]. Schwarz et al. treated 22 patients randomly with access flap surgery and the application of nanocrystalline hydroxyapatite in contrast to xenogenic bone material with collagen membrane. No significant differences were determined between the groups, but 6 months after surgery both treatments resulted in clinically relevant reductions in probing depths and gains of clinical attachment level [108]. Roos-Jansåker et al. came to similar results using a coralline xenograft [19]. In another study bovine-derived xenogenic material was compared with autogenous bone as filling material for infracrestal defects. The xenograft provided radiologically more bone fill and decreases in pocket depths, while bleeding on probing and suppuration were observed at both procedures [109]. In a prospective study, 36 cases of peri-implant bone loss were treated after local disinfection and removal of granulation tissue with a 1:1 mixture of autologous bone and a xenogenic bone graft. The result was a mean radiologically reduction of 3.5 mm from 5.1 mm one year after treatment with an average reduction of probing depths of 4 mm [59]. In a recent prospective case series a combined resective and regenerative approach including a bovine bone mineral and a collagen membrane infracrestally and implantoplasty supracrestally showed a significant peri-implant probing depth reduction and an increased radiographic defect fill after 12 months of follow-up [110]. In another study of Schwarz et al. defect cleaning with either Er:YAG laser or plastic curettes/cotton pellets with saline was combined with regenerative surgical procedures (xenogenic bone substitute and collagen membrane). Thereby, the clinical outcome did not differ according to the chosen method of surface debridement [111].

In purpose of bone regeneration various approaches have been described with various success rates. There is a tendency that xenograft materials in combination with a resorbable membranes might have advantages in terms of re-osseointegration. Nevertheless, because of the lack of prospective randomized clinical studies there is no evident data concerning the long-time stability of such “defect fillings”.