Background
Chronic periodontitis (CP) is characterized as a complex progressive chronic inflammatory process, which leads to the destruction of periodontal supportive tissue and a further loss of teeth. CP occurs when the magnitude effects of the pathogenic microbial load in the periodontal pocket are larger than that of the hosts immune response [
1,
2]. The basis of periodontal treatment is elimination or suppression of periodontal pathogens. The golden standard of which is mechanical debridement by scaling and root planing (SRP). However, large limitations of physical treatment have been observed due to the difficulty of accessing deep periodontal defects, which compromises the effectiveness of biofilm removal. The persistence of periodontal pathogens, such as
Aggregatibacteractinomycetemcomitans and
Porphyromonas gingivalis (P.g), were often found following SRP and can result in microbial re-colonization and the consequent destruction of periodontal tissue [
3‐
6]. In regards to this issue, adjunctive systemic and localized antibiotics have been applied to compensate for the limitation of mechanical therapy. Despite the rapid development of a variety of adjunctive local periodontal treatments in recent years, such as metformin, antioxidants, photodynamic treatment and so on [
7‐
9], chlorhexidine (CHX) remains one of the most effective local antimicrobial agents, and is widely used for the local treatment of periodontitis [
10‐
13]. Through the rapid attraction of the negatively charged bacterial cell surface to the cationic CHX molecule, CHX shows strong antibacterial activity in the periodontal pocket, along with a lack of toxicity, incompliance from patients and an emergence of resistance microorganisms. However, the high clearance of CHX from the periodontal pocket leads to subtherapeutic CHX concentrations in the local environment after only a short time of subgingival CHX application [
14], which results in an insufficient treatment effectiveness [
1,
15]. Given this limitation, CHX Gel with CHX concentration up to 15 times than liquid carriers was developed for periodontal treatment. In recent years, numerous of studies have reported the effectiveness of adjunctive CHX to nonsurgical periodontal treatment (NSPT). However, contrary results were presented [
10‐
13], there is still no consensus on this issue. So far, only one systematic review without quantitative analysis indicated that the positive effect of local subgingival application of CHX Gel adjunctive to NSPT could be not justified as compared to NSPT alone [
16]. Therefore, there is lack of strong evidence for support the beneficial effect of subgingival use CHX as adjunct to NSPT.
Full-mouth disinfection (FMD) was proposed by Quirynen in 1995, with the aim of eradicating periodontal pathogens in a short time from all the oropharyngeal habitats (mucous membranes, tongue, tonsils and saliva) [
17]. CHX gel as an adjunct was used in the FMD protocol, which was described as full-mouth scaling and root planing (FMSRP) in 1–2 sessions within 24 h combined with full-mouth subgingival irrigation with CHX gel, as well as a tongue brush and mouthwash by means of CHX [
2,
17‐
20]. However, whether the use of antiseptics played a role in FMD is still unclear.
The aim of this systematic review and meta-analysis was to evaluate the benefits of a subgingival administration of CHX gel as an adjunct to NSPT for the treatment of CP.
Method
Focus questions
Whether subgingival chlorhexidine gel application as an adjunct to nonsurgical periodontal treatment provides additional benefit to clinical outcomes in chronic periodontitis?
Search strategy
The review and meta-analysis were based on the Preferred Reporting Items for Meta-Analysis (PRISMA) statement [
21]. Three reviewers (HZ, JCH and LZ) conducted an independent search of three databases, including PubMed, EMBASE and the Cochrane Collaboration Library on the 20 August 2019 for articles addressing the focused question. Furthermore, a search of the Open Grey database was performed, and a hand search was conducted of following journals: Journal of Dental Research, Journal of Periodontology, Journal of Clinical Periodontology and Journal of Periodontal Research from 2000 until 2019.
Study selection
Titles and abstracts were reviewed for eligibility by two independent reviewers (HZ, JCH) according to the inclusion criteria. Studies that met all inclusion criteria or met some of inclusion criteria but did not meet any of the exclusion criteria were admitted for full-text review. In this phase, full-text papers were assessed in line with the exclusion criteria. And the reasons for exclusion were recorded (Additional file
1: Table S1). Any disagreements were resolved on discussion between the three reviewers and a consensus was reached through voting. The agreement value between the reviewers was calculated using Kappa statistics, which is used to measure inter-rater reliability. The classification of Kappa Value was suggested: ≤ 0 as indicating no agreement, 0.01–0.20 as none to slight, 0.21–0.40 as fair, 0.41–0.60 as moderate, 0.61–0.80 as substantial, and 0.81–1.00 as perfect agreement [
22].
The search strategy for PubMed (adapted to the other databases) is listed below:
(periodontitis OR periodontal disease) AND ((((chlorhexidine, OR chlorhexidine gluconate, OR xanthan OR xanthan chlorhexidine) AND gel) AND (subgingival, OR subgingival curettage, OR dental scaling, OR root planing OR dental prophylaxis)) OR full mouth disinfection)
Primary and secondary outcomes
The primary outcomes were probing pocket depth (PPD) reduction and the clinical attachment level (CAL) gain at 3 and 6 months post-therapy. The secondary outcome was adverse events.
Eligibility criteria
The inclusion criteria for the studies were: 1) randomized controlled trials (RCTs); 2) comparison of SRP alone/placebo and CHX gel adjunct to SRP; or comparison of FMSRP alone/placebo and FMD, including subgingival use of CHX gel; 3) follow-up of at least 3 months; 4) reported data on clinical parameters (CAL and PPD) and 5) publication in English only.
The exclusion criteria were: 1) not RCTs; 2) duplicate publications; 3) Inadequate treatment strategy: CHX was used as mono-therapy or CHX was used as adjunct to surgery or other treatment; 4) follow-up less than 3 months; 5) reported only microbiological findings with no reference to clinical result; 6) not in English.
Quality assessment
The methodology quality of the included articles was evaluated independently by two reviewers (HZ and JCH) based on recommendations from the CONSORT statement [
23]. Quality assessments of the included studies were conducted using the revised risk of bias assessment tool from the Cochrane Collaboration’s handbook version 5.2.0 [
24], which includes seven criteria: random sequence generation; allocation concealment; blinding of participants and personnel; blinding of outcome assessment; incomplete outcome data; selective reporting and other sources of bias. Each category was estimated on whether it could impact the overall results and was further qualified as either low, high or unclear. Overall, each article was judged as (i) low risk of bias, (ii) unclear risk of bias or (iii) high risk of bias. When a trial did not meet all four criteria for randomization and blinding methods, it was excluded from quantitative analysis, as its low quality and high bias may have subverted the validity of the results and conclusions.
Data collection process/data items
Data of each included study were recorded using a standardized data extraction form, including study design, number of patients, demographics, inclusion criteria, types of CHX gel, timing and frequency of CHX gel application, number of adverse events and length of follow-up.
Data synthesis
The meta-analysis was performed using RevMan version 5.3 (2014). Mean differences (MD) with 95% confidence intervals (95% CI) were used for continuous data. The I2 value was used to access the statistical heterogeneity of the studies. If the heterogeneity was evaluated as I2 ≤ 50%, a fixed effects model was applied. When the heterogeneity was assessed as I2 > 50%, a random effects model was used. The inverse-variance method performed, and the overall effect was defined as statistically significant if the
p value < 0.05.The I2 value was classified into four levels: i) no heterogeneity, between 0 and 25%; ii) low heterogeneity, 25–50%; iii) moderate heterogeneity, 50–75% and iiii) high heterogeneity, 75–100% [
25].
Discussion
Four trials comparing adjunctive CHX gel and SRP with SRP alone at selected sites were included for quantitative analysis. The results showed that adjunctive administration of CHX gel provided a significant improvement in PPD reduction with a small overall effect size of 0.15 mm and no benefit to CAL. For subgroup analysis, adjunctive subgingival administration of XAN-CHX gel containing 1.5% CHX provided also a slightly greater improvement of PPD reduction of MD 0.15 mm.
In qualitative analysis, CHX gel without Xanthan gum was applied as adjunct to SRP at selected sites in three studies, and showed no beneficial clinical outcomes [
10‐
12]. The results were consistent with various studies reporting minimal benefits in the local use of traditional CHX gel as a monotherapy [
36,
37] or as an adjunct to SRP [
10‐
13]. The effect of locally delivered antimicrobial drugs depends on its concentration and contact time in the local environment [
12]. For subgingival administration of drugs, the outflow of crevicular fluid may play an important role. Evidence indicated that the outflow of crevicular fluid is about 20 ml/hour, which might be the main cause of the short-term half-life of the gel within the periodontal pocket [
14,
38]. Oosterwaal et al. applied fluorescein gel in four pockets of 10 patients, samples were taken from 1 of the 4 pockets at 5, 10, 20 and 40 min. The results showed that the most locally delivered gels in the pocket disappeared within 5 min after application, which might be due to the elasticity of pocket soft tissue, bleeding after drug administration and spreading of the gel. And then the gel was washed out linearly and gradually by crevicular fluid flow and released from the adherent surface of the periodontal pocket [
14]. Given the high clearance of CHX within the pockets, CHX gel seemed to not be an effective adjuvant to SRP. XAN-CHX gel has been applied for local periodontal treatment within the recent 10 years, which contains a mixture of CHX digluconate and CHX dihydrochloride, incorporated in a Xanthan gum. XAN-CHX gel demonstrated a greater capacity to increase viscosity of the carrier (CHX) and maintained the bacteriostatic and bactericidal concentrations for at least 2 weeks inside the periodontal pocket [
35], which could further promote its pharmacotherapeutic effects. Based on this evidence, XAN-CHX gel may overcome the limitations of the previously used CHX gel. Considering the results of this meta-analysis for subgroups, XAN-CHX gel provided only a minor additional improvement with mean MD of 0.15 mm of PPD reduction, and no benefit of CAL gain. So far, no sufficient data have supported the clinical efficacy of adjunctive subgingival applications of XAN-CHX gel according to existing research. Evidence has reported that CHX has a high affinity for salivary or serum proteins and blood, which might lead to its rapid concentration decrease in the subgingival environment [
39‐
41]. Furthermore, the behaviour of pathogenic bacteria in periodontal pocket may also resist the effectiveness of local CHX gel. Evidence supported that P.g releases vesicles capable of inactivating the CHX molecule, thereby protecting themselves and other bacteria from the bactericidal activity [
15]. These features may markedly negatively regulate the effects of subgingival administrations of a XAN-CHX gel. Microbiological outcomes of various studies have confirmed the minimal efficacy of locally delivered XAN-CHX gel as an adjunct to SRP, which showed minor bacterial count reductions in an adjunctive XAN-CHX gel group as compared to control [
29,
31,
34,
42]. Due to a lack of microbiological data from consistent testing methods and standards, microbiological outcomes were not analysed in the review.
In recent years, CHX gel has been commonly used for FMD protocol in the treatment of periodontal disease. Considering the clinical benefit of FMD in varying degrees, FMD protocol has been conducted in a large number of studies [
43‐
46]. In addition to full-mouth subgingival applications of CHX gel, tongue brush with CHX gel and mouthwash with CHX solution were also performed with the aim of maximum elimination of periodontal pathogens in the mouth. Despite these, no additional benefits for the adjunctive use of CHX in FMSRP were shown in this meta-analysis. This result is consistent with other studies and reviews, which indicated that the benefits of FMD probably resulted from the short-term full-mouth mechanical debridement, rather than the beneficial effects of CHX [
15,
47]. A high heterogeneity was detected for analysis of the mean PPD between the FMD and FMSRP groups at 3 months (I2 = 76%) and 6 months (I2 = 78%). Regarding the small number of included studies and limited data available, there were variable factors impacting on the results, such as the general health of the included patients, the initial disease severity of the chronic periodontitis, the frequency of CHX gel application and the influence of other adjunctive means of CHX included in FMD and its period and frequency.
Noticeably, side effects and adverse events related to the use of the local administration of CHX in the treatment of periodontitis should be taken into account and be weighed against the potential benefits. Although the local application of antiseptics or antibiotics overcomes uncertainties in the systemic use of antibiotics, adverse events, such as changes in taste perception, dry mouth, erythema, oral ulceration, gingival tingling, periodontal abscesses, root sensitivity and staining of tongue or teeth, were reported [
48]. For FMD, due to long-term mouthwash using CHX solution, staining could occur in most patients [
18]. This fact should remind clinicians that the balance between the small effect size of clinical benefit and high possibility of tooth staining should be taken in consideration when developing a treatment plan for periodontal patients.
Limitations
To the best of our knowledge, this is the first systematic review focusing on the effects of adjunctive subgingival application of CHX gel to SRP. Therefore, we cannot compare our results with previous publications. In addition, because of the lack of RCTs with high quality, only seven studies with a small number of participants were included for quantitative meta-analysis, and long-term clinical results comparing the test and control groups were not calculated. More RCTs with more participants and long-term follow-up are needed in the future.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.