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Peri-implantitis

Peri-implantitis is an inflammatory disease affecting the soft and hard peri-implant tissues in partially or completely edentulous patients who have osseointegrated dental implants, characterized by progressive loss of supporting beyond the physiological dimensions of , clinical signs of , and increased probing depths. It is distinguished from the precursor condition peri-implant mucositis, which involves reversible limited to the peri-implant mucosa without bone loss. This condition poses a significant challenge in implant dentistry, as untreated cases can lead to implant failure, pain, and the need for complex rehabilitative interventions. As per the 2025 AO/AAP consensus on prevention and management of peri-implant diseases, updated epidemiological data underscores its prevalence and the need for evidence-based strategies. The etiology of peri-implantitis is primarily infectious, driven by the accumulation of bacterial biofilms on implant surfaces, analogous to the pathogenesis of periodontitis. Key pathogens include anaerobic bacteria such as Porphyromonas gingivalis and other Gram-negative species, which trigger an inflammatory response leading to tissue destruction. Established risk factors encompass a history of periodontal disease (doubling the risk and up to 14-fold increase in aggressive forms), smoking (nearly twice the likelihood, with dose-dependent effects), poor oral hygiene and plaque control (eight-fold increased risk), lack of regular supportive maintenance therapy (20% incidence in non-compliant patients within five years), diabetes or hyperglycemia (46% higher risk), and obesity. Additional contributing elements include implant design factors like surface roughness and prosthetic misfit, as well as iatrogenic issues such as excess cement. Potential risk factors under investigation include genetic predispositions (e.g., IL-1 polymorphisms) and occlusal overload, though evidence remains inconsistent. Prevalence estimates for peri-implantitis vary by population and study design but indicate a substantial clinical burden, with recent cross-sectional data reporting 15.15% for peri-implantitis and 49.5% for peri-implant at the patient level. Recent comprehensive reviews estimate approximately 21% of patients and 18% of implants are affected with peri-implantitis overall, with incidence rates ranging from 0.4% to 43.9% within three to five years post-placement, particularly higher in those without regular (16.7-35.5%). relies on clinical parameters such as , suppuration, probing depths ≥6 mm, and radiographic confirmation of loss ≥3 mm apical to the implant platform. Management strategies progress from non-surgical approaches like mechanical , , and systemic antibiotics (e.g., amoxicillin plus ) for early lesions to surgical options including resective techniques (implantoplasty, ostectomy) or regenerative procedures ( with membranes) for advanced disease, guided by protocols such as the Cumulative Interceptive Supportive (CIST). Prevention focuses on meticulous patient selection, pre-implant periodontal , , rigorous plaque control, and scheduled professional maintenance every three to six months, especially for high-risk individuals.

Overview

Definition

Peri-implantitis is defined as a biofilm-associated pathological condition occurring in the tissues around dental implants, characterized by in the peri-implant and progressive loss of supporting bone beyond initial . This inflammatory disease affects both soft and hard tissues surrounding functional implants, distinguishing it from non-pathological adaptive changes. The condition was first described in the late 1980s, with the term "peri-implantitis" introduced to denote an infectious process akin to periodontitis around implants. A formal definition was established at the 1993 First European Workshop on Periodontology (proceedings published in 1994), where Albrektsson and Isidor characterized it as an inflammatory reaction associated with the loss of supporting bone in tissues surrounding a functional implant. According to the classification from the 2017 World Workshop on the Classification of Periodontal and Peri-Implant Diseases and Conditions, peri-implantitis is diagnosed by the presence of probing depths ≥6 mm accompanied by , along with radiographic loss ≥3 mm apical to the implant platform in the absence of baseline radiographs. This threshold was reaffirmed in the 2023 European Federation of Periodontology (EFP) S3 level clinical practice guideline, which maintains the 2017 criteria while emphasizing initiation. Peri-implantitis differs from normal post-implant bone remodeling, which typically involves 1-2 mm of crestal bone loss in the first year after loading, followed by minimal annual changes of ≤0.2 mm for implant success. In contrast, peri-implantitis exhibits progressive bone destruction exceeding these physiological limits, often leading to angular bone defects.

Prevalence

Peri-implantitis affects a substantial proportion of patients with dental implants, with meta-analyses estimating an overall patient-level prevalence of 19% to 22% for implants in function for at least 5 years. This figure is derived from systematic reviews aggregating data across diverse cohorts, where prevalence at the implant level is typically lower, around 12% to 13%. The condition is notably more prevalent in patients with a history of periodontitis, with rates reaching up to 37% in affected individuals compared to lower baseline figures in those without prior periodontal disease. Incidence rates for peri-implantitis are estimated at approximately 1.1% per year at the patient level, based on cumulative data showing 22% development over 20 years of implant function in systematic reviews up to 2025. Shorter-term data indicate 12% incidence within 5 years and 14% within 10 years, highlighting a progressive accumulation over time. Demographic variations influence prevalence, with males showing an odds ratio (OR) of 1.28 for peri-implantitis compared to females, though not always statistically significant across studies. Smoking elevates risk substantially, with an OR of 2.27, while diabetes mellitus is associated with an OR of 2.31. Regional differences are evident, with prevalence reported at around 19.5% in Europe and up to 23.9% in Asian populations such as Japan, per meta-analytic data. These disparities may reflect variations in oral hygiene practices, access to maintenance care, and study methodologies. The recognition of peri-implantitis has increased with extended implant longevity, as follow-up studies now commonly exceed 20 years, revealing higher cumulative rates than earlier short-term assessments. This trend underscores the importance of long-term monitoring, particularly in at-risk groups where factors like poor oral hygiene exacerbate occurrence.

Clinical features

Signs

Peri-implantitis manifests through distinct clinical signs observable during periodontal examination, primarily involving and tissue changes around the . (BOP), defined as bleeding occurring within 30 seconds at more than one site around the implant, serves as a primary indicator of mucosal and is a cornerstone of when exceeding baseline levels. Suppuration on probing or palpation, indicating purulent exudate from the peri-implant sulcus, is another key sign associated with advanced and tissue breakdown. Increased probing pocket depths, typically ≥6 mm and often accompanied by horizontal or vertical attachment loss, reflect deepening of the peri-implant beyond healthy norms of 3-4 mm. Mucosal swelling and further contribute to these clinical findings, with the soft tissue appearing edematous and retracted from the implant neck. Visible alterations in the peri-implant tissues include redness or of the mucosa, signaling active inflammatory response, and frequent plaque accumulation at the implant-abutment interface, which exacerbates the condition. Progression of peri-implantitis is evidenced by ongoing attachment loss, quantitatively assessed via changes in probing attachment level (PAL), where losses greater than 2 mm from baseline correlate with disease advancement. These are reported in 80-90% of confirmed peri-implantitis cases according to 2025 systematic reviews synthesizing clinical data. Radiographic evidence of bone loss often confirms these clinical observations, though detailed protocols are addressed elsewhere.

Symptoms

Patients with peri-implantitis commonly report or tenderness around the implant site, which may manifest as discomfort during chewing or brushing. In advanced cases, implant mobility becomes noticeable, affecting stability and function, while halitosis can arise from ongoing and bacterial accumulation. Occasional loosening of the prosthesis may also occur, contributing to further unease. The condition often remains in early stages, with many patients perceiving their implants as healthy despite underlying progression; studies indicate that up to 91.7% of affected implants show no subjective symptoms initially. As peri-implantitis advances, symptoms typically progress to functional discomfort, though systemic manifestations like fever are rare and usually absent. Peri-implantitis impacts through functional impairments, such as difficulty , with approximately 32% of patients reporting limitations in food choices due to pain or instability. Surveys highlight chewing discomfort as a significant concern, contributing to moderate overall oral health-related reductions, particularly in psychological and functional domains. Unlike acute infections, which present with sudden, abscess-like symptoms including severe pain and swelling, peri-implantitis typically features chronic, low-grade symptoms that develop gradually and may go unnoticed until bone loss is substantial. This distinction underscores the importance of regular monitoring, as suppuration may occasionally accompany symptoms but is more commonly an objective sign.

Diagnosis

Diagnosis of peri-implantitis is based on the 2017 World Workshop consensus criteria, which require the combination of clinical signs of (bleeding on probing and/or suppuration), increased probing depths, and radiographic evidence of bone loss beyond physiological remodeling.

Clinical methods

Clinical of peri-implantitis involves hands-on of peri-implant soft tissues to detect and attachment loss. Probing depth (PD) measurement is a technique, performed using a slender periodontal with millimeter markings inserted gently around the implant at a minimum of six sites (mesial, distal, buccal, lingual, and two intermediates) under standardized force of approximately 0.25 N to avoid tissue trauma. A PD of ≥6 mm, especially when accompanied by (BOP), indicates peri-implantitis, with comparisons to baseline PD values from implant placement or prosthetic loading essential for detecting progressive deepening. Bleeding and suppuration assessments are integrated into the probing process to gauge inflammatory status. BOP is recorded if bleeding occurs within 30 seconds of probe withdrawal, with the BOP index expressed as the percentage of bleeding sites; BOP at ≥50% of sites shows high predictive value for peri-implant pathology. Suppuration, the expression of pus upon gentle probing, signals advanced infection and is present in up to 28% of peri-implantitis cases, often correlating with deeper pockets and bone loss. These metrics help distinguish active disease from reversible mucositis. Peri-implant attachment level (PAL) evaluation quantifies cumulative changes, calculated as the distance from a fixed implant reference (e.g., the smooth collar or shoulder) to the probeable base of the pocket, equivalent to plus any mucosal . Changes in PAL from baseline measurements provide a reliable index for monitoring over time despite challenges posed by the non-keratinized mucosa. Adjunctive tools enhance clinical assessment by targeting biofilm and stability. Plaque index scoring, such as the modified plaque index (mPI), rates supragingival and subgingival from 0 (none detectable) to 3 (abundant soft/heavy ), with scores ≥2 associated with increased risk. Mobility testing employs devices like the Periotest, which delivers controlled percussion taps and yields a value from -8 (high ) to +50 (high ); abnormal readings (>+10 in osseointegrated implants) indicate potential compromise, though it is less sensitive for early detection. These methods support comprehensive diagnosis when used alongside probing.

Radiographic methods

Radiographic methods play a crucial role in the of peri-implantitis by providing objective evidence of loss around dental , complementing clinical assessments such as probing depths. intra-oral radiographs, including periapical and bitewing projections, are the primary modality for initial and routine evaluation of marginal levels. These two-dimensional images allow for the measurement of vertical loss, with peri-implantitis indicated by bone levels ≥3 mm apical to the most coronal portion of the intraosseous implant component when data are unavailable, particularly in with clinical signs of . radiographs are recommended within 3 months after delivery to document initial bone-to-implant contact following physiological remodeling, enabling subsequent comparisons for progressive changes. Advanced imaging techniques, such as cone-beam computed tomography (CBCT), offer three-dimensional visualization superior to conventional for detailed assessment of peri-implant defects. CBCT facilitates precise evaluation of both vertical and horizontal loss, as well as the detection of dehiscences and fenestrations, which are often underappreciated in two-dimensional views. Studies have demonstrated that CBCT provides higher diagnostic accuracy and reliability for classifying and measuring peri-implant defects compared to intra-oral imaging. However, its use must balance benefits against a higher effective dose, typically 50-200 μSv depending on , versus 5-10 μSv for intra-oral radiographs, with low-dose protocols recommended to minimize in routine cases. Diagnostic thresholds for peri-implantitis based on emphasize progressive loss beyond expected physiological remodeling. After the first year of loading, annual loss exceeding 0.2 is considered indicative of progression, aligning with established criteria adapted for peri-implant . In the absence of serial records, a static loss of ≥3 from the expected level at 90% of the first bone-to-implant contact serves as a for confirming peri-implantitis when combined with clinical . These thresholds correlate with clinical probing findings, where radiographic supports the interpretation of depths ≥6 as pathological. Limitations of radiographic methods include artifacts from metal , particularly beam hardening in CBCT, which can obscure interfaces and reduce diagnostic accuracy near implant surfaces. To mitigate this, serial imaging at intervals of 6-12 months is advised for at-risk patients to track changes over time, rather than relying on single assessments. Overall, while is essential for structural evaluation, it should be integrated with clinical examination for comprehensive .

Pathophysiology

Etiology

Peri-implantitis is primarily caused by the accumulation of bacterial on implant surfaces, which disrupts microbial and leads to in the peri-implant sulcus. This polymicrobial biofilm, dominated by , initiates an inflammatory cascade that progresses to tissue destruction around the implant. Key pathogens associated with this condition include , , and , which are detected at higher prevalence in peri-implantitis sites compared to healthy implants or periodontitis lesions. These organisms contribute to by forming complex communities that evade host defenses and promote persistent infection. The dynamics of biofilm formation in peri-implantitis mirror those in periodontitis, involving subgingival plaque maturation through initial colonization by early colonizers followed by late anaerobes, but occur at an accelerated rate due to the unique properties of implant surfaces. Moderately rough implant surfaces, characterized by average roughness values (Ra) exceeding 1.5 μm—such as those achieved through and acid-etching—enhance bacterial and biofilm stability by increasing surface area and providing micromechanical retention sites. This topography not only promotes but also facilitates deeper biofilm penetration into peri-implant pockets (≥5 mm), rendering the infection more resistant to mechanical disruption compared to natural tooth surfaces. The host to this triggers a robust inflammatory reaction, characterized by the release of pro-inflammatory cytokines such as interleukin-1β (IL-1β) and tumor necrosis factor-α (TNF-α) from recruited immune cells like macrophages and neutrophils. These cytokines amplify the inflammatory milieu in peri-implant crevicular fluid, with IL-1β levels elevated up to threefold in affected sites, correlating with probing depth and bone loss. TNF-α, often higher in peri-implantitis than in periodontitis, further promotes osteoclastogenesis by upregulating receptor activator of nuclear factor kappa-B ligand () and downregulating (OPG), leading to accelerated around the implant. According to the 2024 Academy of Osseointegration/American Academy of Periodontology (AO/AAP) consensus (proceedings published 2025), microbial remains the primary etiological factor in peri-implant diseases, with 91% expert agreement on its central role in disease initiation and progression. While mechanical factors such as overload from prosthetic design may contribute secondarily by altering local tissue stresses, the consensus emphasizes control as the cornerstone for addressing .

Progression

Peri-implantitis typically initiates as a reversible inflammatory condition resembling peri-implant , characterized by around the implant without radiographic loss beyond the expected post-surgical remodeling. This arises from bacterial accumulation at the implant-abutment interface or mucosal margins, leading to localized gingival with but no apical extension of the inflammatory . If untreated, it progresses to the destructive of peri-implantitis, often beginning 1-2 years after implant placement, where progressive suppuration and probing depths exceeding 5 mm emerge alongside initial marginal loss greater than 0.5 mm. In the progression stage, bone loss accelerates, typically manifesting as vertical or horizontal defects apical to the implant platform, with rates of 0.2-0.5 mm per year in untreated cases based on longitudinal studies spanning up to 10 years. Advanced peri-implantitis involves crater-like intrabony defects with more than 50% loss relative to length, resulting in implant mobility, suppuration, and potential failure due to compromised . This temporal evolution underscores the disease's irreversible nature once involvement occurs, distinguishing it from the reversible precursor. The primary mechanisms driving progression include the apical migration of the junctional epithelium, which disrupts the mucosal barrier and allows deeper penetration into peri-implant sulci. This migration facilitates pocket deepening (often >6 mm), promoting further bacterial ingress and chronic inflammation that erodes supporting bone through activation. Concurrently, loss of occurs as inflammatory mediators weaken the bone-implant interface, leading to progressive vertical rather than the horizontal patterns seen in periodontitis. Histopathologically, peri-implantitis lesions exhibit a dense inflammatory infiltrate dominated by cells and lymphocytes, with notable contributions from neutrophils and macrophages, contrasting with the more lymphocyte-heavy profiles in . This cellular response upregulates receptor activator of nuclear factor kappa-B ligand () expression, primarily from B cells and fibroblasts, which stimulates osteoclastogenesis and alveolar via the /RANKL/OPG pathway. Vascular proliferation and breakdown further exacerbate the destructive process, forming larger lesions than those in .

Risk factors

Established factors

A history of periodontitis is a well-established for peri-implantitis, with meta-analyses reporting an (OR) of 2.92 (95% CI: 2.05–4.13) for patients with a prior compared to those without. This elevated risk arises from residual periodontal pockets that serve as microbial reservoirs, facilitating the colonization of around implants and contributing to inflammatory progression similar to mechanisms in the disease's . Smoking is another confirmed risk indicator, associated with an OR of 2.27 (95% CI: 1.68–3.06) for peri-implantitis development. use impairs , promotes formation on implant surfaces, and exacerbates through and other cytotoxic components. The risk is dose-dependent, with smokers consuming ≥10 cigarettes per day showing significantly higher marginal bone loss and disease incidence compared to lighter smokers or non-smokers. Uncontrolled diabetes, defined by HbA1c levels >8%, increases the likelihood of peri-implantitis with an OR of 2.31 (95% CI: 1.59–3.32), based on observational data from systematic reviews. in these patients compromises immune responses, particularly function, leading to delayed healing and heightened susceptibility to around implants. Poor , characterized by inadequate daily plaque control, is strongly linked to accumulation and peri-implantitis onset. This factor directly contributes to microbial and progressive tissue destruction by allowing unchecked plaque maturation on abutments and prostheses. Lack of regular maintenance care, such as intervals exceeding 6 months, increases the risk of peri-implantitis approximately 3.75-fold, with a prospective study reporting 41.6% incidence in irregular attendees compared to 11.1% in compliant patients over 11 years. Infrequent professional monitoring fails to address early signs of , allowing and buildup to advance unchecked. Alcohol consumption exceeding 14 units per week has been identified as a significant risk indicator for peri-implantitis in the 2025 AO/AAP consensus, with an OR of 2.07 (95% CI 1.49-2.85) for heavy drinkers, potentially due to impaired immune function and oral hygiene. This association highlights alcohol's contribution to systemic factors that may aggravate local inflammatory processes around implants.

Potential factors

Genetic predispositions, particularly polymorphisms in the IL-1 gene cluster such as IL-1A (-889) and IL-1B (+3954), have been associated with an increased risk of peri-implantitis in preliminary studies, with a reporting an (OR) of 2.34 (95% CI 1.03-5.33) for the composite . These genetic variations may contribute to heightened inflammatory responses around implants, though further research is needed to confirm their role beyond initial associations. Obesity and metabolic syndrome represent emerging risk factors for peri-implant diseases, including mucositis, particularly in individuals with a greater than 30, which is linked to through elevated pro-inflammatory cytokines. Clinical studies indicate that obese patients exhibit greater marginal bone loss, deeper probing depths, and higher compared to those with normal BMI, underscoring the role of hyper-inflammatory states in disease progression. Occlusal overload, characterized by excessive forces causing micro-movements at the implant site, shows mixed evidence as a for peri-implantitis, with clinical studies reporting ORs ranging from 1.2 to 2.71 in cases involving , though animal models often demonstrate no direct causation without plaque accumulation. The conflicting preclinical and clinical data suggest that overload may act as an aggravating factor rather than a primary initiator, necessitating patient-specific occlusal assessments. Implant design differences, particularly cement-retained versus screw-retained restorations, pose a niche through excess retention, which is more prevalent in cemented prostheses and identified as a possible indicator for peri-implant diseases with associations in 33% to 100% of affected cases. Subgingival margins increase the likelihood of undetected residue, promoting bacterial harboring and , whereas screw-retained designs mitigate this by avoiding altogether.

Comparison to peri-implant mucositis

Key similarities

Peri-implantitis and peri-implant mucositis are both plaque-induced inflammatory conditions affecting the tissues surrounding dental implants, sharing a common rooted in bacterial accumulation that disrupts host-microbe at the implant-mucosa . This formation triggers an inflammatory response in the soft tissues, analogous to the progression from to periodontitis in natural teeth. Clinically, both conditions present with similar signs of mucosal , including (BOP), presence of plaque, redness, swelling, and potential suppuration. These shared features make early differentiation challenging without radiographic assessment, as the inflammatory response in peri-implant mucositis mirrors the initial changes seen in peri-implantitis. The microbiota involved in both diseases overlaps significantly, dominated by bacterial biofilms that include periodontal pathogens such as the red complex bacteria (, , and ). This dysbiotic microbial community contributes to the inflammatory infiltrate of T- and B-lymphocytes observed histologically in affected tissues. In their early stages, both conditions are potentially reversible through effective plaque control and hygiene measures, with peri-implant resolving upon removal, thereby preventing progression to peri-implantitis. However, untreated peri-implant serves as a precursor, with studies indicating progression to peri-implantitis in up to 44% of cases over 5 years without supportive therapy. Recent guidelines emphasize this link, noting the potential for progression if not addressed.

Key differences

Peri-implantitis differs from peri-implant primarily in its involvement of supporting , representing a more advanced and irreversible stage of peri-implant . While peri-implant is confined to reversible of the soft tissues surrounding , peri-implantitis features progressive marginal loss exceeding 3 mm apical to the original bone-to-implant contact, as confirmed by radiographic assessment. This destruction in peri-implantitis extends into the implant body and threads, distinguishing it from the absence of radiographic changes in beyond initial post-surgical remodeling. Clinically, probing depths provide another key differentiator, with peri-implantitis typically presenting depths of ≥6 mm accompanied by mucosal and suppuration, compared to shallower depths of ≥4 mm or increases from baseline in , primarily due to gingival swelling rather than attachment loss. Radiographic evidence of bone loss is essential for diagnosing peri-implantitis to confirm the extent of destruction, whereas for , radiographs serve mainly to exclude bone involvement when clinical signs like and are present. Both conditions share initial inflammatory signs such as , but the progression to bone loss marks the critical divergence in peri-implantitis. Regarding reversibility, peri-implant mucositis can be fully resolved through non-surgical interventions like mechanical debridement and improved , often within weeks to months, restoring health to baseline levels. In contrast, peri-implantitis involves irreversible , where treatments aim only to halt further progression rather than regenerate lost , necessitating surgical or adjunctive approaches for control. The severity and further underscore these differences, as peri-implantitis is associated with a substantially higher of due to ongoing and , with reported rates of 10–20% at the patient level indicating its clinical and potential for rapid deterioration if untreated. Peri-implant , while more (around 40–50%), carries a much lower of progression to (<5%), as its reversible nature allows effective management without compromising implant stability.

Prevention

Patient-level strategies

Patients can prevent peri-implantitis through consistent oral hygiene practices tailored to implant anatomy. Twice-daily brushing with a soft-bristled manual or powered toothbrush is recommended to remove supragingival plaque, while daily use of interdental aids such as floss or appropriately sized interproximal brushes is essential for cleaning hard-to-reach areas around implants and abutments. As an adjunct, short-term use of 0.2% chlorhexidine (CHX) mouthrinse may help reduce biofilm formation, particularly during initial healing or maintenance phases, though its long-term efficacy in prevention remains under evaluation. Lifestyle modifications play a critical role in mitigating modifiable risk factors. Smoking cessation is strongly advised, as current smoking doubles the odds of peri-implantitis (OR 2.27, 95% CI 1.68–3.06), and quitting can substantially lower this elevated risk through validated interventions like counseling or pharmacotherapy. For patients with diabetes, maintaining glycemic control with HbA1c levels below 7% is associated with an 84% lower risk of peri-implantitis (OR 0.16, 95% CI 0.03–0.96) compared to poor control, which more than doubles the odds (OR 2.31, 95% CI 1.59–3.32). Dietary habits and self-monitoring further support prevention by limiting biofilm-promoting conditions. Patients should minimize consumption of sugary foods, which enhance plaque formation and bacterial adhesion around implants, thereby increasing inflammation risk. Regular self-examination for early signs of peri-implant issues, such as bleeding on probing or loosening, allows for prompt professional intervention. Patient education is foundational, emphasizing differences in implant care from natural teeth, including the need for lifelong adherence to supportive peri-implant care (SPIC). According to the 2023 European Federation of Periodontology (EFP) S3-level guidelines, counseling should occur before implant placement and be reinforced periodically to highlight the importance of home care and regular monitoring. High compliance with these strategies significantly reduces peri-implantitis incidence. Cohort studies show that adherence to SPIC protocols lowers the risk by approximately 58% (OR 0.42, 95% CI 0.24–0.75), with regular home hygiene and professional visits minimizing disease progression over long-term follow-up.

Professional strategies

Professional strategies for preventing peri-implantitis center on clinician-led interventions during scheduled recall visits, emphasizing supportive peri-implant care (SPIC) to maintain tissue health and mitigate disease progression. Regular maintenance is typically scheduled at 3- to 6-month intervals, adjusted based on individual risk profiles, and includes professional mechanical debridement to remove supra- and sub-mucosal plaque and calculus, plaque scoring via indices such as the , and reinforcement of patient hygiene techniques to ensure compliance. Debridement methods prioritize non-abrasive tools like ultrasonic scalers with plastic tips or air-polishing devices using glycine or erythritol powders, which effectively disrupt biofilm without damaging implant surfaces. Risk assessment during these visits involves systematic screening for modifiable factors, such as smoking or poor glycemic control, using validated tools like the Implant Disease Risk Assessment (IDRA), an octagonal diagram evaluating parameters including history of periodontitis, bleeding on probing percentages, probing depths, bone loss-to-age ratio, therapy compliance, and prosthesis design. This enables tailored counseling, such as smoking cessation advice, to lower disease susceptibility before issues escalate. Early intervention targets peri-implant mucositis to halt progression to peri-implantitis, with prompt non-surgical treatment recommended within 2-3 months of detection, utilizing air polishing or ultrasonic instrumentation combined with antiseptics like to resolve inflammation. Outcomes are re-evaluated at 6-12 weeks, adjusting protocols if bleeding on probing or probing depths exceed thresholds (e.g., >5 mm with multiple sites affected). Monitoring protocols incorporate circumferential probing with a 0.5-mm probe at 0.2 N force to measure (BOP) and probing depths at every recall, alongside annual radiographs to track marginal bone levels. The 2024 Academy of /American Academy of (AO/AAP) consensus advocates more frequent monitoring, such as quarterly visits, for high-risk patients (e.g., those with uncontrolled or prior periodontitis) to enable timely adjustments. Long-term cohort studies demonstrate that adherence to risk-based SPIC significantly lowers peri-implantitis incidence, with reductions of 60% to 80% compared to irregular or absent , alongside improved implant survival rates. These strategies complement patient-level hygiene efforts by providing expert oversight and intervention.

Management

Non-surgical approaches

Non-surgical approaches to peri-implantitis management focus on controlling and through minimally invasive techniques, typically as the initial step for mild to moderate cases with probing depths up to 6 mm and no significant bone loss beyond the first thread. These methods aim to reduce bacterial load and (BOP) without incision, often involving repeated sessions every 3-6 months alongside patient reinforcement. Mechanical debridement forms the cornerstone, utilizing hand instruments such as or plastic curettes for supra- and submucosal cleaning, combined with ultrasonic or sonic scalers equipped with non-metallic tips to avoid damaging the implant surface. This approach effectively removes supragingival and subgingival plaque and , leading to reductions in probing pocket depth (PPD) of 0.2-1.8 mm and BOP of 5.3-57.1% at 6-12 months follow-up. Adjunctive antiseptic agents, such as local application of 0.12-0.2% gluconate via or gel, or subgingival delivery, provide short-term support to mechanical debridement, though evidence for superior outcomes over debridement alone remains limited and inconsistent. (PDT), involving photosensitizers activated by light (e.g., laser at 660 nm), has been explored as an adjunct but shows no significant additional PPD or BOP reductions in meta-analyses. Systemic antibiotics, such as amoxicillin (500 mg) combined with (400-500 mg) three times daily for 7-10 days, are used adjunctively in moderate cases with suppuration or deeper pockets, demonstrating PPD reductions of approximately 1.56 mm and a threefold increase in success odds compared to alone; however, routine use is not recommended due to risks of and variable long-term efficacy. Laser therapy, particularly Er:YAG lasers (2940 nm ) in contact or non-contact modes, serves as a non-contact adjunct for surface , achieving up to 99% bacterial reduction through photothermal and photomechanical effects without altering topography. Clinically, it yields modest PPD reductions of 0.28 mm when added to , with no superior BOP improvements over other adjuncts. Overall, non-surgical treatments achieve resolution in 40-60% of cases, with PPD ≤5 mm and no BOP at re-evaluation sites, but radiographic gain is minimal (0-1 mm) and disease progression may necessitate escalation to surgical options in persistent cases.

Surgical approaches

Surgical approaches are indicated for advanced peri-implantitis cases where non-surgical methods have failed, involving invasive procedures to access, debride, and reconstruct peri-implant defects. These techniques aim to eliminate , reduce depths, and promote tissue reattachment or regeneration, with selection based on defect , loss pattern, and factors. No single method of surface has been identified as the gold standard. Access flap surgery involves raising a full-thickness mucoperiosteal flap, often with vertical releasing incisions, to expose the implant surface for thorough debridement and detoxification. Decontamination methods include mechanical instrumentation combined with chemical agents such as citric acid or tetracycline to remove bacterial deposits. The flap is then repositioned and sutured coronally to facilitate soft tissue healing, resulting in significant reductions in probing depth (mean 2.5-3.0 mm) and bleeding on probing. This approach is particularly suitable for intrabony defects and shows less marginal bone loss compared to more aggressive resective methods (0.58 mm at 6 months). Resective therapy focuses on eliminating deep pockets through osseous recontouring, such as ostectomy or osteoplasty, often combined with apical flap positioning to create a favorable architecture. It is indicated for cases with predominant bone loss or shallow, non-contained defects where regeneration is unlikely. Procedures may include reduction around the implant to reduce pocket depths below 5 mm, achieving up to 75% in probing depth and 73% in in some cohorts. Marginal level improvements of up to 4.9 mm have been reported, though greater implant surface exposure may occur post-healing. Regenerative procedures employ guided bone regeneration (GBR) to reconstruct vertical and horizontal bone defects, using autogenous, allograft, or synthetic grafts (e.g., xenografts or porous granules) often covered by resorbable or non-resorbable membranes. Indicated for contained intrabony defects with at least three bony walls and depths ≥3 mm, these approaches promote new formation through a submerged . Clinical outcomes include mean probing depth reductions of 2.88 mm and marginal level gains of 1.14 mm with allografts, with treatment success rates ranging from 11.1% to 78.3% over 1-5 years based on criteria like closure and absence of . Vertical gain achieves 50-70% defect fill in favorable cases, though complete of suppuration is limited. Implantoplasty serves as an adjunctive technique to modify exposed threads in supracrestal or subcrestal defects, involving smoothing with diamond or burs to create a macroscopically rough but bacteriologically inert surface. This reduces bacterial adhesion and formation by altering the surface microstructure, often combined with polishing to a 0.2-0.6 μm roughness. Studies demonstrate significant improvements in probing depth (mean reduction 2.5 mm), scores, and suppuration resolution, with survival rates exceeding 90% at 2 years when integrated into flap or resective surgeries. Caution is advised for narrow-diameter implants due to risk. As of 2025, guidelines emphasize combined surgical approaches, integrating flap , regeneration, and implantoplasty tailored to defect type, yielding superior outcomes over non-surgical alone with improved resolution and bone stability at 1-year follow-up. Recent randomized trials confirm these strategies achieve 88.6% implant survival and reduced recurrence odds, particularly with adjunctive supportive every 3-6 months.

Adjunctive therapies

Adjunctive therapies in peri-implantitis management involve supportive interventions that enhance the efficacy of primary non-surgical or surgical treatments by targeting microbial, inflammatory, or regenerative aspects of the disease. These therapies are typically integrated with mechanical to optimize outcomes without serving as standalone procedures. Local antibiotics, such as delivered via microspheres (e.g., Arestin) or ointment (e.g., Periocline), provide sustained release into peri-implant pockets for up to 12 months, effectively reducing bacterial load at the site of . Clinical trials demonstrate that this approach significantly decreases probing pocket depth (PPD) by approximately 1-2 mm and (BoP) when used adjunctively with nonsurgical therapy, with benefits observed at 4-6 months post-treatment. Host modulation therapy employs sub-antimicrobial dose () at 20 mg twice daily for 3-9 months to inhibit matrix metalloproteinases (MMPs), particularly MMP-8, thereby reducing excessive collagenase activity, tissue degradation, and around implants. This systemic approach promotes osteoblastic activity while minimizing osteoclast-driven bone loss, leading to clinical attachment gains, reduced pocket depths, and no further attachment loss compared to alone in randomized controlled trials. Probiotics, including oral strains like Lactobacillus reuteri administered via lozenges for 30 days alongside mechanical therapy, modulate the peri-implant microbiota by exerting anti-inflammatory effects and inhibiting key pathogens. Triple-blind randomized trials show significant reductions in Porphyromonas gingivalis bacterial load (P = 0.031) and improvements in BoP and PPD over 90 days in peri-implantitis cases, though effects on other pathogens like Aggregatibacter actinomycetemcomitans are more limited. Platelet-rich fibrin (PRF), an autologous preparation rich in growth factors, augments healing in regenerative peri-implantitis cases by enhancing soft and repair when combined with materials like xenografts. Randomized controlled trials indicate that PRF use results in greater PPD reductions (up to 2-3 mm), clinical attachment level gains, and BoP decreases (e.g., 24% at 6 months) compared to open flap alone. A 2025 systematic review and of 11 randomized controlled trials confirms that adjunctive local and systemic antibiotics improve non-surgical outcomes in peri-implantitis, achieving greater PPD reductions (mean difference ~0.6 mm) and BoP decreases (up to 44% additional reduction) compared to mechanical debridement alone, though long-term varies due to .

Prognosis

Success rates

Treatment for peri-implantitis is commonly defined as the absence of progressive bone loss (less than 0.5 mm per year), a reduction in probing depth of at least 2 mm, and resolution of inflammatory signs such as . Short-term rates following treatment are approximately 46–50% at 1 year, primarily based on reductions in clinical parameters like probing depth and , but these rates decline to 27–35% at 5 years due to recurrence and ongoing bone loss in a subset of cases. Implant survival after peri-implantitis is reported at 70% to 90%, with higher rates observed in cases of early where loss is limited. A of long-term surgical outcomes confirms an overall implant survival rate of 88.6% (range: 75%–100%), with resolution achieved in 58.6% of cases (range: 30.4%–97.7%). rates differ by approach: non-surgical and surgical therapies yield complete resolution in less than 50% of implants. Long-term studies with at least 12-month follow-up demonstrate a recurrence rate of approximately 44%, often linked to residual deep pockets and inadequate , underscoring the need for ongoing supportive therapy to sustain outcomes.

Influencing factors

The prognosis of peri-implantitis is influenced by several key variables, including disease severity at the time of . Early-stage peri-implantitis, characterized by less than 25% of the implant fixture length, demonstrates higher rates of approximately 71%, with a mean time of nearly 10 years following surgical management. In contrast, advanced stages with exceeding 50% exhibit substantially lower rates of about 21%, accompanied by a mean time of roughly 5.7 years, highlighting the challenges in managing extensive defects. Patient compliance with post-treatment maintenance plays a critical role in modulating outcomes. Full adherence to supportive significantly reduces disease progression, with studies reporting improved long-term stability in compliant individuals compared to erratic or non-compliant patients (P=0.019). Non-compliance elevates the risk of recurrence, contributing to progression in up to 63% of cases overall. Control of modifiable risk factors markedly affects prognosis. Smoking adversely influences treatment results, with current smokers experiencing higher rates of disease progression (P=0.023), whereas cessation can mitigate these effects and enhance clinical parameters over time. For patients with , effective glycemic management is essential; well-controlled cases (HbA1c <8%) achieve implant survival rates comparable to non-diabetic individuals, while poorly controlled increases peri-implantitis risk and bone loss. The timing of intervention also shapes success. Early detection and treatment of peri-implantitis prevent escalation from to irreversible bone loss, leading to more favorable resolutions through non-surgical or minimally invasive approaches. Implant site characteristics further modify , with mandibular locations generally outperforming maxillary ones due to higher and thicker cortical plates. Mandibular implants show early failure rates of 1.96%, compared to 3.14% in the (risk ratio 1.41, 95% CI 1.19–1.67), resulting in approximately 10% higher overall success in the .

Current research

Diagnostic innovations

Recent advancements in peri-implantitis diagnostics emphasize non-invasive, precise tools to enable earlier detection and improve prognostic outcomes. detection in has emerged as a promising approach, with elevated salivary levels of matrix metalloproteinase-8 (MMP-8) and interleukin-6 (IL-6) observed in patients with peri-implantitis compared to healthy states, reflecting inflammatory and tissue degradation processes. These biomarkers offer potential for routine monitoring in at-risk patients, surpassing traditional clinical probing in sensitivity for early-stage identification, though specific diagnostic protocols require further validation. Digital imaging techniques have been revolutionized by (AI) integration with cone-beam computed tomography (CBCT), facilitating automated quantification of peri-implant bone loss. AI models, such as those employing convolutional neural networks (CNNs), demonstrate high accuracy in detecting peri-implant bone defects, with one 2025 system achieving an area under the curve (AUROC) of 94.2% for peri-implantitis diagnosis, outperforming specialists (85.6%) and reducing inter-observer variability. For instance, AI-based radiographic analysis streamlines diagnostics and supports longitudinal tracking of disease progression in complex cases. Microbial diagnostics via (PCR)-based subgingival sampling provide detailed pathogen profiling essential for peri-implantitis characterization. Techniques like 16S rRNA gene sequencing identify dysbiotic microbial communities, revealing distinct profiles in peri-implant sites compared to periodontal lesions, with over 500 operational taxonomic units (OTUs) detectable per sample. These methods enable targeted identification of key pathogens such as Porphyromonas gingivalis and Tannerella forsythia, aiding in risk stratification and personalized management. Recent applications in 2024-2025 studies underscore their utility in early detection, with sequencing resolving communities at strain levels for improved diagnostic resolution. Chairside tests utilizing fluorescence devices offer rapid, in-office biofilm detection, complementing radiographic evaluations. Devices like DIAGNOdent, adapted for peri-implant use, detect subgingival calculus and through at 655 nm, achieving detection accuracies comparable to probing for early inflammatory signs. visualize accumulation in real-time, displaying red fluorescence indicative of bacterial presence, which facilitates immediate intervention and outperforms in . These portable tools reduce diagnostic time and enhance chairside decision-making. The 2025 consensus from the Academy of Osseointegration (AO) and American Academy of Periodontology (AAP) advocates incorporating advanced diagnostics, including biomarkers and microbial profiling, into routine screening protocols for high-risk patients, such as those with a history of periodontitis. This integration builds on traditional methods like clinical probing and by emphasizing approaches for more accurate, timely peri-implantitis identification.

Therapeutic developments

Recent advancements in peri-implantitis therapy have focused on innovative protocols and biologics to enhance , regeneration, and beyond conventional methods. These developments aim to improve by targeting persistence, bone loss reversal, and host immune responses, with promising results emerging from preclinical and early clinical investigations. The Ten-Second Technique (TST) represents a novel protocol involving the application of Hybenx® gel for 10 seconds followed by air polishing with , achieving significant reduction in surface contamination and bacterial biofilms on implant surfaces in in-vitro studies conducted in 2025. Scanning electron microscopy confirmed complete removal of deposits, with substantial decreases in carbon content indicative of bacterial remnants (p < 0.05), supporting its potential for rapid in clinical settings. Regenerative biologics, including stem cell-enhanced grafts combined with growth factors such as bone morphogenetic protein-2 (), have demonstrated enhanced bone formation in peri-implant defects. In preclinical models, BMP-2 using periodontal ligament stem cells promoted re-osseointegration, while recent mRNA-based BMP-2 approaches facilitated peri-implant bone regeneration. These biologics show potential for defect repair in peri-implantitis. Antimicrobial innovations utilizing -delivered antibiotics enable sustained local release to combat persistent infections. In animal models of peri-implantitis, bacteria-responsive systems loaded with agents like or effectively eradicated biofilms, reducing infection recurrence by approximately 50% compared to controls through prolonged and targeted bacterial disruption. These approaches minimize systemic exposure while enhancing . Systemic host-modulating therapies, such as anti-RANKL agents like , are under investigation for preserving peri-implant bone in pilot studies. In patients initiating post-implant placement, evaluations revealed maintained peri-implant tissue stability and reduced bone resorption, with no adverse effects on observed over follow-up periods. These findings suggest potential adjunctive benefits in modulating activity during treatment. Ongoing clinical trials, including the 2025-completed NCT05711407 study, have explored MMP-8 guided to personalize peri-implantitis by inflammatory biomarkers for tailored interventions. Meta-analyses of adjunctive indicate approximately 20% in disease resolution rates, particularly with local antibiotics, underscoring the value of combined approaches in enhancing overall outcomes.