Dipterocarpus tuberculatus as a promising anti-obesity treatment in Lep knockout mice.

Introduction: The therapeutic effects and mechanisms of Dipterocarpus tuberculatus (D. tuberculatus) extracts have been examined concerning inflammation, photoaging, and gastritis; however, their effect on obesity is still being investigated. Methods: We administered a methanol extract of D. tuberculatus (MED) orally to Lep knockout (KO) mice for 4 weeks to investigate the therapeutic effects on obesity, weight gain, fat accumulation, lipid metabolism, inflammatory response, and ß-oxidation. Results: In Lep KO mice, MED significantly reduced weight gains, food intake, and total cholesterol and glyceride levels. Similar reductions in fat weights and adipocyte sizes were also observed. Furthermore, MED treatment reduced liver weight, lipid droplet numbers, the expressions of adipogenesis and lipogenesis-related genes, and the expressions of lipolysis regulators in liver tissues. Moreover, the iNOS-mediated COX-2 induction pathway, the inflammasome pathway, and inflammatory cytokine levels were reduced, but ß-oxidation was increased, in the livers of MED-treated Lep KO mice. Conclusion: The results of this study suggest that MED ameliorates obesity and has considerable potential as an anti-obesity treatment.

Promoting Effects of Titanium Implants Coated with Dipterocarpus tuberculatus Extract on Osseointegration.

Titanium (Ti) is the most commonly used biomaterial for dental implants. When inserting Ti implants into jawbones, the main issue is the lack of strong bonding between the Ti implant and the host bone (osseointegration). Inspired by the outstanding adhesion performance of natural phenolic compounds on metal substrates and promoting effect for cell adhesion, we coated a natural plant extract, Dipterocarpus tuberculatus (MED), on Ti implants. We tested three groups of Ti plates and screw-shaped fixtures: nontreated Ti as commercially produced, ozone-treated Ti as commonly used surface modification for dental implants, and MED-coated Ti. Interestingly, the MED coating on the Ti plate preserved the surface wetting property for 20 days, whereas the hydrophilic wetting of ozone-treated Ti was readily transformed to hydrophobic within a day. Computerized tomography and histopathological analysis revealed that MED coating enhanced new bone tissue formation and regeneration. The gene expression level of integrin as a bone cell adhesion receptor and its downstream key regulators was significantly increased than that of ozone-treated Ti. Therefore, we suggest considering MED-mediated cell signaling pathways in screening natural products for cell adhesion and osseointegration, and MED as a suitable coating agent for improving Ti implantation.