Objective and design: To determine whether an inhibitor of matrix metalloproteinases (MMPs), administered to human subjects in a dental school research clinic, can reduce bone-type collagen degradation fragments in oral inflammatory exudates containing excessive levels of collagenase.
Materials and subjects: Gingival crevicular fluid (GCF) was collected from 18 subjects with adult periodontitis whose clinical findings (gingival inflammation, pocket depth, and bone loss on radiographs) predicted excessive MMP activity in their periodontal pockets.
Treatment: One month before the baseline appointment, plaque and calculus were removed from the teeth by supra- and subgingival scaling. After collection of GCF from 8-12 pocket sites per subject and recording of clinical indices, 12 of the 18 subjects were treated with doxycycline at a low dosage (20 mg b.i.d.) known via an extensive literature to suppress mammalian MMP activity by a non-antimicrobial mechanism. The remaining 6 subjects were followed without drug treatment.
Methods: At the baseline, 1 and 2-month appointments, GCF samples were analyzed for ICTP. (carboxyterminal peptide, a pyridinoline-containing fragment of Type I collagen) and osteocalcin by radioimmunoassay, as well as collagenolytic enzyme activity and MMP species (Western blot). Statistical analyses were determined by ANOVA.
Results: GCF ICTP and functional collagenase activity (but not osteocalcin levels) were significantly reduced (p < 0.05) in the doxycycline-treated subjects at both 1 and 2 month evaluations: there was no such change in the non-treated subjects. Western blots revealed that neutrophil-type collagenase (MMP-8) was the predominant MMP; MMP-13, which has been associated with pathologic collagenolysis including bone resorption, was detected in human GCF for the first time and was more substantially reduced than MMP-8.
Conclusion: This is the first demonstration in human subjects of the simultaneous reduction of excessive MMP activity with concomitant reduction in levels of collagen degradation fragments. The findings are potentially applicable to a wide variety of human diseases characterized by excessive collagenase activity.