Peri-Implantitis Clinical Trial
Official title:
The Effect of Ozone Therapy as an Adjunct to the Surgical Treatment of Peri-implantitis: A Randomized Controlled Clinical Trial
Decontamination procedure is a challenging factor that affects the success of surgical regenerative therapy (SRT) of peri-implantitis. The purpose of the present study was to determine the impact of additional ozone therapy for the decontamination of implant surfaces in SRT of peri-implantitis. A total of 21 patients with moderate or advanced peri-implantitis were randomly allocated to the test group (ozone group) with the use of sterile saline with additional ozone therapy or the control group with sterile saline alone for decontamination of the implant surfaces in SRT of peri-implantitis. Clinical and radiographic outcomes were evaluated at baseline and 6 months postoperatively
Peri-implant diseases are described as inflammatory processes in the tissues surrounding
implants in response to mainly microbial biofilms on the surface of the implants (Zitzmann
and Berglundh 2008). Peri-implant mucositis is described as an inflammatory reaction
triggered by microbial biofilms without any loss of peri-implant bone, while
peri-implantitis is characterized by bleeding when probed and/or suppuration with further
loss of the peri-implant bone (Lindhe and Meyle 2008; Lang and Berglundh 2011).
Since microbial biofilms play a major role in the etiology (Becker et al. 1990; Quirynen et
al. 2002), it has been considered that elimination of microbial pathogens is mandatory in
the treatment of peri-implant diseases (Mombelli and Lang 1994; Schwarz et al. 2006). The
objectives of peri-implantitis therapy are implant surface decontamination to resolve
inflammation resolution while preserving the implant supporting tissues (Lindhe and Meyle
2008; Heitz-Mayfield and Lang 2010).
Several implant decontamination methods have been suggested, including mechanical
debridement, chemical therapy (applications of root conditioners, disinfectants, and local
and systemic antibiotic therapy) (Heitz-Mayfield et al. 2012; Wohlfahrt et al. 2012) and
surgical procedures aiming to remove bacteria, and smooth, decontaminate and detoxify the
implant surface (Froum et al. 2012; Schwarz et al. 2013). However, there is as yet no
consensus on the most effective protocol for implant surface detoxification (Suarez et al.
2013).
Ozone has a strong oxidation effect with remarkable antimicrobial potential and can be used
as a disinfectant in clinical applications of dentistry (Iliadis and Millar 2013). A
previous study reported that ozone has powerful antimicrobial activity in response to
anaerobic periodontal pathogenic microorganisms and may have the potential to be used as an
adjunctive tool in non-surgical periodontal therapy in periodontitis patients (Eick et al.
2012). Ozone therapy can promote haemostasis, enhance the release of growth factors and
local oxygen supply, upregulate cellular antioxidant enzymes and inhibit bacterial
proliferation (Ozdemir et al. 2013). However, current literature has little information
regarding the antimicrobial activity of ozone in the treatment of peri-implant diseases. A
previous randomized, clinical study showed that ozone therapy reduced inflammation in the
treatment of peri-implant mucositis (McKenna et al. 2013). Another in-vitro trial reported
that in the reduction of adherent bacteria on titanium, gaseous ozone showed selective
efficacy without any adverse effect on the surface structures of the titanium surfaces or
the adhesion and proliferation of osteoblastic cells (Huser-Gerspach et al. 2012).
Non-surgical therapy alone has been reported to be inadequate for the treatment of moderate
and severe forms of peri-implantitis and therefore surgical therapy is frequently required
(Lindhe and Meyle 2008). The goals of surgical therapy of peri-implantitis are mainly to be
able to access areas for mechanical debridement and implant surface decontamination and to
reconstruct the anatomic conditions to improve plaque control and to eliminate the
pathological peri-implant pockets (Esposito et al. 2012; Roos-Jansaker et al. 2014). This
can be achieved with resection or with procedures of bone regeneration such as guided bone
regeneration (Roos-Jansaker et al. 2003; Schou et al 2004; Sahrmann et al. 2011).
Studies have evaluated the combination of various regenerative biological agents and
techniques for surgical regenerative therapy (SRT) of peri-implantitis and clinical and
radiological improvements following different bone augmentation procedures have been
reported (Claffey et al. 2008; Schwarz et al. 2009; Roos-Jansaker et al. 2011; Renvert et
al. 2012). A long-term, clinical study demonstrated that vertical peri-implant bone defects
(PBDs) may be actively treated by regenerative surgical means, using a bone substitute alone
or in combination with a membrane (Roos-Jansaker et al. 2014).
Platelet concentrates are preferred in periodontal surgical procedures for the purpose of
accelerating angiogenesis, stimulating the activity of osteoblasts and fibroblasts, and
obtaining regeneration of hard and soft tissues, including stem cells and growth factors
(Del Fabbro et al. 2011). These materials can be used alone or in combination with bone
grafts or barrier membranes. In studies employing bone grafts with the use of platelet rich
fibrin (PRF) or PRF alone around PBDs it has been reported that PRF leads to increased new
bone formation and a higher bone to implant contact ratio (Lee et al. 2012; Simsek et al.
2016). A recent study reported that treatment of peri-implantitis using PRF was clinically
more effective than with access flap surgery alone. It was also concluded in the study that
PRF improves the outcomes of surgical peri-implantitis treatment (Hamzacebi et al. 2015).
There have been recent developments of various techniques using platelet concentrate to
provide different rates of platelets, leukocytes, growth factors, stem cells and fibrin
matrix. Sacco developed concentrated growth factors (CGF) as a therapeutic protocol obtained
by separating the venous blood centrifuged using a special device in the same manner as PRF
(Rodella et al. 2011). It was also argued that centrifugation at a different speed provides
a larger, denser fibrin matrix compared to PRF, which results in improved regenerative
capacity and greater versatility (Sohn et al. 2009). Some recent studies have reported that
CGF accelerates new bone formation related to guided bone regeneration (Sohn et al. 2011;
Kim et al. 2014).
The purpose of this randomized, controlled clinical study was to evaluate the clinical and
radiological results of implant surface decontamination using sterile saline alone or in
combination with ozone therapy applied as surgical regenerative treatment for
peri-implantitis.
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Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Treatment
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