Gingival tissue plays a critical role in maintaining oral health as a fundamental component of periodontal tissues. Recent evidence suggests that circadian rhythm mechanisms, beyond microbial factors, may significantly influence periodontal disease pathogenesis through modulation of host immune responses.
The circadian rhythm is an endogenous mechanism regulating biological processes in approximately 24-hour physiological and behavioral cycles, controlled centrally by the suprachiasmatic nucleus in the hypothalamus. At the molecular level, core clock genes (CLOCK, BMAL1, PER1-3, CRY1-2) operate through the Transcription-Translation Feedback Loop (TTFL). CLOCK and BMAL1 proteins form heterodimers in the cell nucleus, bind to E-box regions on DNA, and initiate transcription of PER and CRY genes. Subsequently, PER and CRY proteins synthesized in the cytoplasm return to the nucleus and inhibit the CLOCK-BMAL1 complex, creating approximately 24-hour rhythmic gene expression cycles. Regulatory nuclear receptors such as REV-ERBa and ROR also contribute to the fine-tuning of this mechanism.
Recent studies have demonstrated the presence of functional peripheral clock mechanisms in periodontal tissues. CLOCK, BMAL1, PER1-3, and CRY1-2 gene expression has been identified in gingival fibroblasts and periodontal ligament fibroblasts. Experimental studies have shown that circadian rhythm disruption can increase inflammatory processes, enhance macrophage activation, elevate inflammatory cytokine production, and accelerate alveolar bone loss in periodontitis models.
Despite these findings, human studies evaluating the relationship between inflammatory cytokines and circadian rhythm proteins in gingival crevicular fluid (GCF) remain limited. This study addresses this gap by evaluating gingival health status using clinical periodontal parameters in individuals with and without circadian rhythm disruption.
Study Design:
Participants will be classified into four groups based on circadian rhythm status and periodontal health:
* Group 1: Normal circadian rhythm / Periodontally healthy (control)
* Group 2: Normal circadian rhythm / Gingivitis
* Group 3: Circadian rhythm disruption / Periodontally healthy
* Group 4: Circadian rhythm disruption / Gingivitis
* Group 5: Group 2 at 2 weeks post-periodontal treatment
* Group 6: Group 4 at 2 weeks post-periodontal treatment
Time Points:
T0 (Baseline): Clinical periodontal examination, GCF, saliva, and serum sampling in all groups.
T1 (Day 14): Re-evaluation of clinical parameters and biological sampling in gingivitis groups after standard periodontal treatment.
Clinical Periodontal Assessment:
All periodontal measurements will be performed by a single examiner using a standard periodontal probe at six sites per tooth (mesiobuccal, buccal, distobuccal, mesiolingual, lingual, distolingual). Parameters include plaque index (PI), gingival index (GI), bleeding on probing (BOP), probing depth (PD), and clinical attachment level (CAL).
GCF Sampling:
GCF samples will be collected using sterile Periopaper strips placed in the gingival sulcus for 30 seconds after supragingival plaque removal and isolation. GCF volumes will be quantified using a Periotron device. Samples contaminated with blood will be excluded.
Saliva Sampling:
Unstimulated saliva samples will be collected as an alternative biological material if circadian rhythm proteins cannot be detected at sufficient levels in GCF.
Serum Sampling:
Venous blood samples will be collected from the antecubital vein for biochemical evaluation of circadian rhythm status through cortisol and melatonin level analysis.
All biological samples will be collected during standardized morning hours (09:00-11:00) to minimize diurnal variation in biomarker levels.
Laboratory Analysis:
GCF samples will be analyzed using ELISA for circadian rhythm-related proteins (MTNR1B, BMAL-1, CLOCK, PER-1, PER-2, PER-3, CRY-1, CRY-2, REV-ERB-beta) and inflammatory biomarkers (IL-1beta and IL-10).
Statistical Analysis:
Data will be analyzed using SPSS. Normality will be assessed by Shapiro-Wilk test. Comparisons among independent groups will use one-way ANOVA or Kruskal-Wallis test, with Tukey or Dunn post-hoc tests. Pre- and post-treatment comparisons will use paired t-test or Wilcoxon signed-rank test. Correlations will be assessed by Pearson or Spearman analysis. Multivariate regression models will control for age, sex, BMI, and waist circumference as covariates. Significance level: p \< 0.05.
This study was approved by the Inonu University Health Sciences Scientific Research Ethics Committee and will be conducted in accordance with the Declaration of Helsinki. Written informed consent will be obtained from all participants.
