This study was performed to evaluate the antibacterial activity of water-soluble mangostin derivatives (WsMD) of the ethanol extract of the peel of Garcinia mangostana L. (mangosteen) and the ethanol extracts of the fruit of Psoralea corylifolia L. and the root of Glycyrrhiza uralensis (licorice) against oral bacteria associated with endodontic infections. Cytotoxicity of the three natural products was tested on human embryonic kidney 293 cells (HEK 293) using the methylthiazolyldiphenyl-tetrazolium bromide (MTT) assay or the cell counting method. Antimicrobial activity was evaluated based on the minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC). The highest concentrations of the WsMD of the ethanol extract of the peel of mangosteen and ethanol extracts of P. corylifolia L. fruit and licorice root without cytotoxic effects on HEK 293 cells were 20, 400, and 320 µg/ml, respectively. The MIC and MBC values of the WsMD of the ethanol extract of the peel of mangosteen and ethanol extracts of P. corylifolia L. fruit against 35 isolates (23 species) of pulpitis- and periapical disease-causative bacteria were 1.25–20 µg/ml and 25–200 µg/ml, respectively, except for Dialister invisus KCOM 1973. The ethanol extract of licorice root had MBC values of 40–320 µg/ml against 27 of 35 bacterial strains. These results showed that the WsMD of the ethanol extract of mangosteen peel had the highest antibacterial activity among the three natural extracts and suggested it as a potential root canal irrigation agent.

Background: The risk of device thrombosis and device-oriented clinical outcomes with bioresorbable vascular scaffold (BVS) was reported to be significantly higher than with contemporary drug-eluting stents (DESs). However, optimal device implantation may improve clinical outcomes in patients receiving BVS. The current study evaluated mid-term safety and efficacy of Absorb BVS with meticulous device optimization under intravascular imaging guidance. Methods: The SMART-REWARD and PERSPECTIVE-PCI registries in Korea prospectively enrolled 390 patients with BVS and 675 patients with DES, respectively. The primary endpoint was target vessel failure (TVF) at 2 years and the secondary major endpoint was patientoriented composite outcome (POCO) at 2 years. Results: Patient-level pooled analysis evaluated 1,003 patients (377 patients with BVS and 626 patients with DES). Mean scaffold diameter per lesion was 3.24 ± 0.30 mm in BVS group.Most BVSs were implanted with pre-dilatation (90.9%), intravascular imaging guidance (74.9%), and post-dilatation (73.1%) at proximal to mid segment (81.9%) in target vessel.Patients treated with BVS showed comparable risks of 2-year TVF (2.9% vs. 3.7%, adjusted hazard ratio [HR], 1.283, 95% confidence interval [CI], 0.487–3.378, P = 0.615) and 2-year POCO (4.5% vs. 5.9%, adjusted HR, 1.413, 95% CI, 0.663–3.012,P = 0.370) than those with DES. The rate of 2-year definite or probable device thrombosis (0.3% vs. 0.5%, P = 0.424) was also similar. The sensitivity analyses consistently showed comparable risk of TVF and POCO between the 2 groups. Conclusion With meticulous device optimization under imaging guidance and avoidance of implantation in small vessels, BVS showed comparable risks of 2-year TVF and device thrombosis with DES.

This study was conducted to evaluate the cytotoxic and anti-inflammatory effects of the ethanol extract of Syzygium aromaticum L. (clove) buds. The cytotoxicity test was performed by cell counting method using hTERT-hNOF cells, a human immortalized gingival fibroblast cell line. To test the anti-inflammatory effects, the hTERT-hNOF cells were treated with lipopolysaccharide (LPS) extracted from Porphyromonas gingivalis KCOM 2804 (PgLPS) and ethanol extract of clove buds. The expression levels of PGE2, IL-6, and IL-8 were measured by enzyme-linked immunosorbent assay. The cytotoxicity test data showed a cell viability of ≧ 82% in hTERT-hNOF cells treated with 10 to 80 µg/mL of the ethanol extract of clove buds. The anti-inflammatory test data showed that the expression of PGE2 by PgLPS treatment was reduced to the level of the negative control group by treatment with 10 µg/mL or more of the ethanol extract of clove buds. In group treated with PgLPS and 40 µg/mL of clove bud ethanol extract, the expression levels of IL-6 and IL-8 in were inhibited by 75% and 77%, respectively (p<0.05), compared to the positive control (PgLPS treatment) group. These results suggest that the ethanol extract of clove buds can be used in developing oral hygine products for preventing periodontal disease.

Purpose: Fusobacterium species can cause infections, and associations with cancer are being increasingly reported. As their clinical significance differs, accurate identification of individual species is important. However, matrix-assisted laser desorption/ionization-time of flight mass spectrometry has not been found to be effective in identifying Fusobacterium species in previous studies. In this study, we aimed to improve the accuracy and efficacy of identifying Fusobacterium species in clinical laboratories. Materials and Methods: In total, 229 Fusobacterium isolates were included in this study. All isolates were identified at the species level based on nucleotide sequences of the 16S ribosomal RNA gene and/or DNA-dependent RNA polymerase β-subunit gene (rpoB). Where necessary, isolates were identified based on whole genome sequences. Among them, 47 isolates were used for updating the ASTA database, and 182 isolates were used for the validation of Fusobacterium spp. identification. Results: Fusobacterium isolates used for validation (182/182) were correctly identified at the genus level, and most (180/182) were correctly identified at the species level using the ASTA MicroIDSys system. Most of the F. nucleatum isolates (74/75) were correctly identified at the subspecies level. Conclusion The updated ASTA MicroIDSys system can identify nine species of Fusobacterium and four subspecies of F. nucleatum in good agreement. This tool can be routinely used in clinical microbiology laboratories to identify Fusobacterium species and serve as a springboard for future research.

This study aimed to develop strain-specific polymerase chain reaction (PCR) primers to detect Fusobacterium hwasookii KCOM 1249T , F. hwasookii KCOM 1253, F. hwasookii KCOM 1256, F. hwasookii KCOM 1258, and F. hwasookii KCOM 1268 on the basis of nucleotide sequences of a gene specific to each strain. The unique genes for each F. hwasookii strain were determined on the basis of their genome sequences using Roary. The strain-specific PCR primers based on each strain-specific gene were designed using PrimerSelect. The specificity of each PCR primer was determined using the genomic DNA of the 5 F. hwasookii strains and 25 strains of oral bacterial species.The detection limit and sensitivity of each strain-specific PCR primer pair were determined using the genomic DNA of each target strain. The results showed that the strain-specific PCR primers correspond to F. hwasookii KCOM 1249T , F. hwasookii KCOM 1253, F. hwasookii KCOM 1258, F. hwasookii KCOM 1256/F. nucleatum subsp. polymorphum KCOM 1260, or F. hwasookii KCOM 1268/Fusobacterium sp. oral taxon 203 were developed. The detection limits of these strain-specific PCR primers ranged from 0.2 to 2 ng of genomic DNA for each target strain. The results suggest that these strain-specific PCR primers are valuable in quality control for detecting specific F. hwasookii strains.

In previous studies, we introduced that mangosteen extract complex (MEC; ethanol extracts of Garcinia mangostana L. peel and propolis) had inhibitory effects on inflammation and alveolar bone loss in silk-ligature applied and Porphyromonas gingivalis lipopolysaccharide (LPS) induced periodontitis model in rats. This study was conducted to evaluate whether MEC had inhibitory effect of alveolar bone loss when a higher inflammatory state was induced by increasing the injection amount of P. gingivalis LPS by 20 times and increasing the treatment dose of MEC by twice the amount or maintaining MEC dose that used in the previous study. The data showed that alveolar bone loss was significantly reduced in the Lig+L+MEC 1:34 group (treated with mixture of 16 µg mangosteen peel extract powder and 544 µg propolis extract powder) and in the Lig+L+MEC 2:68 group (treated with mixture of 32 µg mangosteen peel extract powder and 1,088 µg propolis extract powder) by 24.3% and 28.9%, respectively. This result reveals that the mixture of MEC 1:34 could be useful in improving periodontal tissue health and may be able to be used as a therapeutic adjuvant for periodontitis.

Increases of neutrophils and osteoclasts are pathological changes of periodontitis. RANKL is an osteoclast differentiation factor. The effect of periodontopathogen LPS on RANKL-expressing neutrophils has not been clarified yet. We evaluated numerical changes of RANKL-expressing neutrophils in air pouches of mice injected with LPSs of Fusobacterium nucleatum and Porphyromonas gingivalis. Mice with air pouches were assigned into saline (C)-, E. coli LPS- (Ec LPS)-, F. nucleatum LPS (Fn LPS)-, P. gingivalis LPS (Pg LPS)-, and Fn LPS and Pg LPS (Fn + Pg LPS)-injected groups. CD11b +Ly6G + neutrophils and CD11b +Ly6G+RANKL + neutrophils in blood and air pouch exudates were determined by flow cytometry. In blood, compared to the C group, the Fn LPS group showed increases of CD11b +Ly6G + neutrophils and CD11b +Ly6G +RANKL + neutrophils whereas the Pg LPS group showed no significant differences. These increases in the Fn LPS group were not different to those in the Ec LPS group. In exudates, Fn LPS and Pg LPS groups showed increases of CD11b +Ly6G + neutrophils and CD11b +Ly6G +RANKL + neutrophils compared to the C group. Increased levels in the Fn LPS group were not different to those in the Ec LPS group, but Pg LPS group was lower than those in the Ec LPS group. In blood and exudates, the Fn+ Pg LPS group showed no difference in levels of these neutrophils compared to the Ec LPS group. LPSs of F. nucleatum and P. gingivalis increased RANKL-expressing neutrophils although the degrees of increases were different. These suggest that periodontopathogen LPS can act as a stimulant to increase RANKL-expressing neutrophils.

PURPOSE: The purpose of this study is to compare the antibacterial activity of currently purchasable denture cleansers against Candida albicans. Materials and methods: This study used tablet-type denture cleansers, PolidentⓇ , CoolingdentⓇ and FittydentⓇ , along with liquid denture cleansers, HexamedineⓇ , ListerineⓇ and Apple vinegarⓇ . The antibacterial activities of denture cleansers were evaluated based on the number of C. albicans and concentrations of the denture cleansers. Results: In the 0.5 × 106 cfu/㎖ culture medium, the C. albicans’ death rate of PolidentⓇ was significantly lower than those of FittydentⓇ , HexamedineⓇ , ListerineⓇ , and Apple vinegarⓇ (P <.05). In the 0.5 × 107 cfu/, the C. albicans’ death rates of PolidentⓇ and CoolingdentⓇ were significantly lower than those of FittydentⓇ , HexamedineⓇ , ListerineⓇ and Apple vinegarⓇ (P <.05). The C. albicans’ death rates of PolidentⓇ and CoolingdentⓇ were significantly decreased at 0.02 g and 0.01 g. The C. albicans’ death rate of FittydentⓇ was significantly decreased at 0.005 g (P <.05). The C. albicans’ death rate of HexamedineⓇ was significantly decreased at 1/16 dilution. The C. albicans’ death rate of ListerineⓇ was decreased at 1/8 dilution, and the antibacterial activity of Apple vinegarⓇ was decreased at 1/4 dilution (P<.05). Conclusion As the number of C. albicans increased, the antibacterial activities of the denture cleansers decrease. In the tablet-type denture cleanser, all denture cleansers showed 100% C. albicans’ death rate when used at a dose of 1 tablet. One denture cleanser showed the same antibacterial effect with only 1/3 of a tablet. In the liquid type denture cleanser, the level of dilution required was different for each denture cleanser.

In previous studies, we introduced that mangosteen extract complex (MEC; ethanol extracts of Garcinia mangostana L. peel and propolis) had inhibitory effects on inflammation and alveolar bone loss in silk-ligature applied and Porphyromonas gingivalis lipopolysaccharide (LPS) induced periodontitis model in rats. This study was conducted to evaluate whether MEC had inhibitory effect of alveolar bone loss when a higher inflammatory state was induced by increasing the injection amount of P. gingivalis LPS by 20 times and increasing the treatment dose of MEC by twice the amount or maintaining MEC dose that used in the previous study. The data showed that alveolar bone loss was significantly reduced in the Lig+L+MEC 1:34 group (treated with mixture of 16 µg mangosteen peel extract powder and 544 µg propolis extract powder) and in the Lig+L+MEC 2:68 group (treated with mixture of 32 µg mangosteen peel extract powder and 1,088 µg propolis extract powder) by 24.3% and 28.9%, respectively. This result reveals that the mixture of MEC 1:34 could be useful in improving periodontal tissue health and may be able to be used as a therapeutic adjuvant for periodontitis.