The role of non-steroidal anti-inflammatory drugs as adjuncts to periodontal treatment and in periodontal regeneration

Periodontal diseases are notably the most common and prevalent chronic diseases in the world [1]. They include a spectrum of inflammatory conditions encompassing gingivitis and periodontitis; the latter is a non-communicable, multifactorial chronic inflammatory infectious disease characterized by clinical attachment loss and alveolar bone destruction, which can result in tooth migration, drifting, tooth hypermobility, tooth loss, and ultimately masticatory dysfunction [2]. Periodontitis has been the major cause of tooth loss in the adult population worldwide that negatively impacts quality of life and accounts for the huge socio-economic impact and healthcare costs globally [3]. The causes of periodontitis have been extensively investigated, and its initiation and progression has been attributed to the uncontrolled accumulation of dental biofilm, which interacts with the individual susceptibility profile [4]. Genetics, tobacco and alcohol use, diabetes, obesity, poor nutrition, physical inactivity and impaired host responses have all been associated with an increased risk of periodontitis [5]. Periodontal therapy varies based on a proper diagnosis of disease severity, extent, rate of progression, risk factors, complexity of management, and interrelationship with general health [6]. According to the European Federation of Periodontology (EFP) S3 level clinical practice guideline for periodontitis [7], the fundamental cornerstones of periodontal therapy involves 4 sequential steps: Step 1—Behavior change and risk factor control; Step 2—Cause-related therapy; Step 3—Surgical interventions and Step 4—Supportive care; which are delivered in a stepwise incremental approach depending on the disease stage. The essence of the first step of therapy is both preventive and therapeutic which aims to control systemic and local risk factors. The second step of cause-related therapy targets the control of subgingival biofilm and calculus via subgingival mechanical instrumentation, namely non-surgical periodontal therapy (NSPT), and may also include the use of adjunctive physical or chemical agents, local or systemic adjunctive host-modulating agents or antimicrobials. For areas that are not responding favorably to cause-related therapy, surgical interventions may be indicated to facilitate access to root surface debridement, to regenerate or resect intra-bony or furcation periodontal defects [8, 9]. The recent advances in biological materials, therapeutic agents, and surgical techniques for regenerative periodontal therapy has enabled its success in restoring lost periodontal tissue and changing tooth prognosis [10]. While standard NSPT and supportive periodontal maintenance by means of scaling and root surface debridement remain the “gold-standard” treatment for Stage I-III periodontitis [7], there still exist patients or sites with poor response to NSPT and long-term supportive maintenance efforts that may be attributed to sustained dysbiosis, periodontopathic bacteria tissue invasion, or a non-resolving chronic inflammatory response [11]. Hence, there has been a constant pursuit for adjunctive therapies to boost the outcomes of periodontal therapy.

Even though biofilms are initiators of periodontal disease, the unique individual susceptibility profile reflected in the host’s immunoinflammatory response plays an important role in periodontal tissue destruction through the local synthesis and secretion of immunological factors, and will impact the treatment responses to all four steps of periodontal therapy [12, 13]. Therefore, various host modulators have been proposed as adjuncts to conventional periodontal treatment. Among these host modulators, non-steroidal anti-inflammatory drugs (NSAIDs) are the most well-known and broadly prescribed [14]. Their pharmacological function is based on the blocking of cyclooxygenase (COX), which was discovered in the late 1980s and exists as two isoforms [15] (Fig. 1). COX-1 is the constitutive isoform and produces basal levels of prostaglandins (PGs), which control platelet activation and protect the lining of the gastrointestinal tract; COX-2 is the inducible isoform and is released in response to inflammatory stimuli such as hypoxia, interleukin (IL)-1, interferon (IFN)-γ, and tumor necrosis factor (TNF)-α, leading to swelling and pain at the inflammation site [16]. Both COX isoforms can transform arachidonic acid in the plasma membrane into PGG₂, which is reduced to PGH₂ by a subsequent peroxidase reaction. PGH₂ is then converted to biologically active primary PGs: PGD₂, PGE₂, PGF₂ \(\alpha\), PGI₂, and thromboxane A₂ (TxA₂) [15].

NSAIDs are classified into four categories based on their affinity and/or selectivity for COX isoenzymes (Table 1). The first category comprises compounds with potential to produce complete inhibition of both COX-1 and COX-2 and is exemplified by aspirin, indomethacin, diclofenac, naproxen, and ibuprofen. The second category of compounds consists of preferential COX-2 inhibitors (5- to 50-fold selectivity) and includes meloxicam, celecoxib, nimesulide, and etodolac. The third category comprises compounds with strong selectivity (> 50-fold) for COX-2, such as diisopropyl fluorophosphate, L-745337, rofecoxib, and NS398. The fourth category of compounds has low affinities for both COX-1 and COX-2 and comprises compounds such as sulfasalazine, sodium salicylate, and nabumetone [17, 18]. Notably, aspirin is unique in that it is an irreversible inhibitor of COXs, whereas all of the other NSAIDs exhibit some degree of reversible inhibition [19].

NSAIDs can inhibit PG synthesis and consequently exert analgesic, anti-pyretic, and anti-inflammatory effects. Therefore, they are indicated to relieve pain and fever and treat inflammation in rheumatic, osteoarthritic, and other diseases. In addition, they can be used to prevent cardiovascular events, premature labor, and perturb the microenvironments of tumors [20, 21]. However, some nonspecific cytotoxic effects of NSAIDs can be detrimental to the human body; such complications should not be ignored [22].

In this review, we summarize laboratory and clinical evidence for the utility of NSAIDs in the conventional treatment of periodontitis, which includes both surgical and non-surgical periodontal treatment, but without regenerative approaches, and in periodontal tissue engineering and regeneration. In the first part of the review, we discuss the role of PGs in periodontitis and the administration of NSAIDs during cause-related non-surgical or surgical therapies. In the second part of the review, we describe the combination of NSAIDs with current periodontal regeneration techniques.

Non-surgical and access flap periodontal surgeries in anatomically challenging areas are effective procedures for mechanically removing biofilms and thereby relieve local inflammation in patients with periodontal diseases. These techniques aim to remove infectious substances, halt disease progression, and restore periodontal health; however, healing is mainly by repair and not regeneration of lost periodontal tissues [96]. To regenerate new supportive apparatus for teeth, strategies such as, minimally invasive surgical techniques in periodontal regeneration [97, 98] in combination with biologics, guided tissue regeneration (GTR), bone replacement grafts, and periodontal tissue engineering have been developed [99]. GTR involves placing an absorbable or non-absorbable membrane above the area to be restored. This prevents the undesired migration of epithelial cells and gingival fibroblasts and promotes the growth of bone progenitor cells [100]. The benefits of GTR have been adequately discussed in previous reviews, such as decreased PPD, increased gains in attainment level, and the formation of new bone [101, 102].

Currently, bone replacement grafts, biologics such as amelogenins and various biomaterials can be utilized either by themselves or as scaffolds in conjunction with different surgical techniques. Bone replacement grafts use osteoinductive and osteoconductive bone graft materials to fill the bone defect areas, with the aim of regenerating the most important component of supportive tissue, the alveolar bone [103]. Common graft materials are autologous bone, bovine xenograft, and demineralized freeze-dried bone allograft (DFDBA) [104‐106]. Several efforts have been dedicated to exploring novel biomaterials in recent decades [107]. Biomaterials are normally used as scaffolds in tissue engineering to facilitate cell attachment, tissue formation, and mechanical support. Given the complexity of the periodontium, materials such as hydroxyapatite (HA), biphasic calcium phosphate, and tricalcium phosphate (TCP) have been used to reconstruct bone tissue [108]. Some innovative biomaterials that mimic the structure and characteristics of the cementum, periodontal ligament, and alveolar bone have also been used to restore naturally structured periodontal tissues [109].

Although several studies have investigated the effects of NSAIDs on the treatment of periodontitis, either alone or as adjuncts to non-surgical or surgical periodontal treatments, it remains challenging to draw a definitive conclusion on their efficacy. This is exacerbated by the fact that conventional periodontal therapies have proven safe and efficacious in resolving inflammation and halting tissue destruction [140, 141], making it unnecessary to use NSAIDs as adjunctive therapy for most conditions [7]. Furthermore, NSAIDs have long-term adverse effects that cannot be ignored; non-selective NSAIDs can cause gastrointestinal bleeding, renal effects, hypertension, hepatic injury, and headache, and COX-2 inhibitors have similar adverse cardiovascular and renal effects [142, 143]. Moreover, aspirin exerts anti-platelet effects even at low doses, as it inhibits thromboxane synthesis, which increases the risk of bleeding [144]. This may increase periodontal bleeding in patients with or without periodontal diseases [89, 145, 146]. Therefore, considering the costs and benefits, systemic or local use of NSAIDs as an adjunct to conventional periodontal treatment is not recommended by the EFP [7].

Notwithstanding the limitations, recent preclinical and clinical research on host modulation utilizing NSAIDs, especially aspirin, in combination with omega-3 PUFA for NSPT and alone in periodontal regeneration has yielded promising outcomes. These promising preliminary results signal their potential use as adjunctive treatment in selective patient groups with high susceptibility risk profile or poor response. Studies on the mechanism of action of aspirin have shown that, in addition to inhibiting PG synthesis, it activates various signaling pathways [147‐149]. They have also documented its role in promoting osteogenesis, inhibiting adipogenesis, attenuating osteoclastogenesis, modulating macrophage polarization, and inducing cell migration and stem cell homing, all of which support periodontal regeneration. However, some of the results must be interpreted with caution as many of these preclinical studies have used critical-size defect models of the tibia and cranium in animals. Given the position of defects, local infection, and inflammation level, it remains to be determined whether the results from these models can precisely reflect the chronic inflammation condition in the periodontium. Well-designed, high quality randomized controlled trials investigating the adjunctive use of NSAIDs in periodontal therapy alone or in combination are also needed to further substantiate their additional benefits, determine dosing regimen, and establish safety.

The timing of administering NSAIDs also warrants consideration. Tissue healing comprises two inflammatory phases, the initiation and resolution of acute inflammation, characterized by immune cell infiltration, cellular debris clearance, and the production of cytokines and growth factors that facilitate tissue healing [122]. Disturbing either of these phases may delay healing [150]. Moreover, it has been shown that pro-inflammatory signals, when delivered at the early inflammatory stage, can aid tissue repair [151]. Therefore, the controlled release of anti-inflammatory drugs in the resolution phase, rather than the initiation phase, may boost tissue regeneration [115]. Smart biomaterials that can sense, respond, and adapt to stimuli have attracted increasing attention [152]. It is thus possible that a combination of anti-inflammatory agents and smart biomaterials will generate a precisely controlled microenvironment that can maximize the benefits and potential for periodontal regeneration in the future.