Microbial and host‐derived biomarker changes during ligature‐induced and spontaneous peri‐implantitis in the Beagle dog

Monje, Alberto; Eick, Sigrun; Buser, Daniel; Salvi, Giovanni E.

doi:10.1111/jre.12797

Cited by 16 publications

(17 citation statements)

References 38 publications

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“…Radiographic bone loss greater than or equal to 2 mm beyond the crestal bone level from the initial surgery, or greater than or equal to 3 mm apical to the most coronal part of the intraosseous portion of the implant is observed in periimplantitis, with even greater progression than that in periodontitis (273). Similar to periodontitis, peri-implantitis exhibits higher IL-1b levels in diseased tissues, and these changes may persist despite nonsurgical therapy (274)(275)(276). Genetic polymorphisms in IL1B are related to the risk of periimplantitis and contribute to increased clinical parameters, such as peri-implant pocket depth, plaque index, and clinical attachment level (277).…”

Section: Inflammasomes In Peri-implantitismentioning

confidence: 99%

Inflammasomes in Alveolar Bone Loss

Ling

Jiang

2021

Front. Immunol.

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Bone remodeling is tightly controlled by osteoclast-mediated bone resorption and osteoblast-mediated bone formation. Fine tuning of the osteoclast–osteoblast balance results in strict synchronization of bone resorption and formation, which maintains structural integrity and bone tissue homeostasis; in contrast, dysregulated bone remodeling may cause pathological osteolysis, in which inflammation plays a vital role in promoting bone destruction. The alveolar bone presents high turnover rate, complex associations with the tooth and periodontium, and susceptibility to oral pathogenic insults and mechanical stress, which enhance its complexity in host defense and bone remodeling. Alveolar bone loss is also involved in systemic bone destruction and is affected by medication or systemic pathological factors. Therefore, it is essential to investigate the osteoimmunological mechanisms involved in the dysregulation of alveolar bone remodeling. The inflammasome is a supramolecular protein complex assembled in response to pattern recognition receptors and damage-associated molecular patterns, leading to the maturation and secretion of pro-inflammatory cytokines and activation of inflammatory responses. Pyroptosis downstream of inflammasome activation also facilitates the clearance of intracellular pathogens and irritants. However, inadequate or excessive activity of the inflammasome may allow for persistent infection and infection spreading or uncontrolled destruction of the alveolar bone, as commonly observed in periodontitis, periapical periodontitis, peri-implantitis, orthodontic tooth movement, medication-related osteonecrosis of the jaw, nonsterile or sterile osteomyelitis of the jaw, and osteoporosis. In this review, we present a framework for understanding the role and mechanism of canonical and noncanonical inflammasomes in the pathogenesis and development of etiologically diverse diseases associated with alveolar bone loss. Inappropriate inflammasome activation may drive alveolar osteolysis by regulating cellular players, including osteoclasts, osteoblasts, osteocytes, periodontal ligament cells, macrophages, monocytes, neutrophils, and adaptive immune cells, such as T helper 17 cells, causing increased osteoclast activity, decreased osteoblast activity, and enhanced periodontium inflammation by creating a pro-inflammatory milieu in a context- and cell type-dependent manner. We also discuss promising therapeutic strategies targeting inappropriate inflammasome activity in the treatment of alveolar bone loss. Novel strategies for inhibiting inflammasome signaling may facilitate the development of versatile drugs that carefully balance the beneficial contributions of inflammasomes to host defense.

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Section: Inflammasomes In Peri-implantitismentioning

confidence: 99%

Inflammasomes in Alveolar Bone Loss

Ling

Jiang

2021

Front. Immunol.

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“…Even though in the microbiological analysis using real-time PCR, there were no differences between the tested implants regarding the total bacterial counts, during the spontaneous progression phase, hybrid implants presented significantly lower levels of IL-1B. This differential biofilm pathogenicity associated with hybrid implants may be relevant on susceptible patients such as those evaluated in the present study (Monje et al, 2021).…”

Section: Discussionmentioning

confidence: 58%

One‐year outcomes of dental implants with a hybrid surface macro‐design placed in patients with history of periodontitis: A randomized clinical trial

Serrano

Sanz‐Sánchez

Serrano

et al. 2021

J Clinic Periodontology

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Aim: To evaluate the radiological, clinical, and microbiological outcomes of implants with a hybrid surface macro-design in patients with a history of periodontitis. Material and Methods:The study was designed as a 12-month, parallel-arm, randomized controlled trial where patients with a history of treated periodontitis in need of dental implants for single-unit or short-span prosthesis were randomly allocated to a test [implants with a machined titanium surface in the coronal collar (hybrid; HS)] or a control group [conventional implants with moderately rough surface up to the implant shoulder (RS)]. Patients were followed at 3, 6, and 12 months after loading with assessment of radiological, clinical, and microbiological outcomes, as well as patient-related outcome measures (PROMs).Results: Forty patients were randomly assigned to either the RS group (n = 20) or the HS (n = 20) group. At 1 year, the mean marginal bone level changes were 0.22 [standard deviation (SD) 0.36] mm for the HS group and 0.22 (SD 0.29) mm for the RS group, with no significant differences between them (p = .961). Similarly, no significant differences in clinical, microbiological, or PROMs were observed between groups.Conclusions: HS implants demonstrated radiographic, clinical, and microbiological characteristics equal to RS implants in patients with a history of periodontitis.Clinical trial registration: ClinicalTrials.gov (identifier NCT05010382).

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“…The 25 included publications (Albouy et al, 2008, 2009, 2012; Almohandes et al, 2019; Berglundh et al, 2007; Carcuac et al, 2013, 2015, 2020; Cook, & Rust‐Dawicki, 1995; Favero et al, 2020; Fickl et al, 2015; Godoy‐Gallardo et al, 2016; Gotfredsen et al, 2002; Huang et al, 2018; Madi et al, 2013; Martins et al, 2004, 2005; Monje et al, 2019, 2020; Monje, Insua, Monje, et al, 2018; Monje, Insua, Rakic, et al, 2018; Namgoong et al, 2015; Roehling et al, 2019; Tillmanns et al, 1997, 1998) on pre‐clinical in vivo experiments (Table 1)—published between 1995 and 2020—are reporting on 18 different experiments, all involving healthy dogs (5–14 animals per experiment) and the experimentally induced peri‐implantitis model. Implant installation was performed after a healing period of 2–3 months post‐extraction of mandibular teeth.…”

Section: Resultsmentioning

confidence: 99%

What is the influence of implant surface characteristics and/or implant material on the incidence and progression of peri‐implantitis? A systematic literature review

Stavropoulos

Bertl

Winning

et al. 2021

Clinical Oral Implants Res

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Objectives To answer the focused question, ‘In animals or patients with dental implants, does implant surface characteristics and/or implant material have an effect on incidence and progression of peri‐implantitis?’ Material and Methods Pre‐clinical in vivo experiments on experimental peri‐implantitis and clinical trials with any aim and design, and ≥5 years follow‐up, where the effect of ≥2 different type of implant material and/or surface characteristics on peri‐implantitis incidence or severity, and/or progression, implant survival or losses due to peri‐implantitis, and/or marginal bone levels/loss was assessed. Results Meta‐analyses based on data of pre‐clinical experiments, using the ligature induced peri‐implantitis model in the dog, indicated that after the spontaneous progression phase implants with a modified surface showed significantly greater radiographic bone loss (effect size 0.44 mm; 95%CI 0.10–0.79; p = .012; 8 publications) and area of infiltrated connective tissue (effect size 0.75 mm2; 95%CI 0.15–1.34; p = .014; 5 publications) compared to non‐modified surfaces. However, in 9 out of the 18 included experiments, reported in 25 publications, no significant differences were shown among the different implant surface types assessed. Clinical and/or radiographic data from 7605 patients with 26,188 implants, reported in 31 publications (20 RCTs, 3 CTs, 4 prospective cohort, and 4 retrospective studies; 12 with follow‐up ≥10 years), overall did not show significant differences in the incidence of peri‐implantitis, when this was reported or could be inferred, among the various implant surfaces. In general, high survival rates (90–100%) up to 30 years and no clinically relevant differences in marginal bone loss/levels, merely compatible with crestal remodelling, were presented for the various implant types. Conclusion Pre‐clinical in vivo experiments indicate that surface characteristics of modified implants may have a significant negative impact on peri‐implantitis progression, while clinical studies do not support the notion that there is a difference in peri‐implantitis incidence among the various types of implant surfaces. No assumptions can be made regarding the possible impact of implant material on incidence and/or peri‐implantitis progression due to limited information.

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Microbial and host‐derived biomarker changes during ligature‐induced and spontaneous peri‐implantitis in the Beagle dog

Cited by 16 publications

References 38 publications

Inflammasomes in Alveolar Bone Loss

Inflammasomes in Alveolar Bone Loss

One‐year outcomes of dental implants with a hybrid surface macro‐design placed in patients with history of periodontitis: A randomized clinical trial

What is the influence of implant surface characteristics and/or implant material on the incidence and progression of peri‐implantitis? A systematic literature review

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