Protective effects of (6R)-5,6,7,8-tetrahydro-l-biopterin on local ischemia/reperfusion-induced suppression of reactive hyperemia in rat gingiva.

We herein investigated the regulatory mechanism in the circulation responsible for rat gingival reactive hyperemia (RH) associated with ischemia/reperfusion (I/R). RH was analyzed using a laser Doppler flowmeter. RH and I/R were elicited by gingival compression and release with a laser Doppler probe. RH increased in a time-dependent manner when the duration of compression was between 30 s and 20 min. This increase was significantly suppressed by N (ω)-nitro-l-arginine-methyl-ester (l-NAME), 7-nitroindazole (7-NI), and 2,4-diamino-6-hydroxypyrimidine (DAHP). However, RH was markedly inhibited following 60 min of compression. This inhibition was significantly decreased by treatments with superoxide dismutase (SOD), (6R)-5,6,7,8-tetrahydro-l-biopterin (BH4), and sepiapterin. The luminescent intensity of superoxide anion (O2 (•-))-induced 2-methyl-6-(4-methoxyphenyl)-3,7-dihydroimidazo-[1,2-a] pyrazine-3-one (MCLA) was markedly decreased by SOD and BH4, but only slightly by sepiapterin. BH4 significantly decreased O2 (•-) scavenging activity in a time-dependent manner. These results suggested that nitric oxide (NO) secreted by the nitrergic nerve played a role in regulating local circulation in rat gingiva. This NO-related regulation of local circulation was temporarily inhibited in the gingiva by the I/R treatment. The decrease observed in the production of NO, which was caused by suppression of NO synthase (NOS) activity subsequent to depletion of the NOS co-factor BH4 by O2 (•-), played a partial role in this inhibition.

Contribution of nitrergic nerve in canine gingival reactive hyperemia.

Reactive hyperemia reflects a compensatory vasodilation response of the local vasculature in ischemic tissue. The purpose of this study is to clarify the mechanism of regulation of this response in gingival circulation by using pharmacological analysis of reactive hyperemia and histochemical analysis of gingival tissue. Application of pressure to the gingiva was used to create temporary ischemia, and gingival blood flow was measured after pressure release. Reactive hyperemia increased in proportion to the duration of pressure. Systemic hemodynamics remained unaffected by the stimulus; therefore, the gingival reactive hyperemia reflected a local adjustment in circulation. Gingival reactive hyperemia was significantly suppressed by nitric oxide (NO) synthase inhibitors, especially the neural NO synthase-selective antagonist 7-nitroindazole, but not by anticholinergic drugs, ß-blockers, or antihistaminergic drugs. Moreover, immunohistochemical staining for neural NO synthase and histochemical staining for NADPH diaphorase activity were both positive in the gingival perivascular region. These histochemical and pharmacological analyses show that reactive hyperemia following pressure release is mediated by NO-induced vasodilation. Furthermore, histochemical analysis strongly suggests that NO originates from nitrergic nerves. Therefore, NO may play an important role in the neural regulation of local circulation in gingival tissue ischemia.

A biological study establishing the endotoxin limit of biomaterials for bone regeneration in cranial and femoral implantation of rats.

The purpose of this study was to accurately quantify the risk of endotoxin contamination in biomaterials for bone regeneration in order to establish the acceptable endotoxin limit. Collagen sheets containing varying amounts of purified endotoxin from Escherichia coli and dried, heat-killed E. coli or Staphylococcus aureus cells were implanted into cranial or femoral defects in rats. These defects were artificially prepared to a size of 5 × 5 mm or a diameter of 1 mm, respectively. The degree of osteoanagenesis was assessed by soft X-ray radiography and histopathology at 1 and 4 weeks after implantation. The collagen sheet containing the dried E. coli cells showed a dose-dependent delay in cranial and/or femoral osteoanagenesis at endotoxin activities of more than 33.6 EU/mg, at which no inflammatory response was observed. In contrast, no such observation occurred with the collagen sheet containing S. aureus cells. These results suggest that endotoxins may affect the process of osteoanagenesis. Additionally, the no-observed-adverse-effect level was 9.6 EU/mg, corresponding to 255 EU/kg body weight in rats. Interestingly, no delay in osteoanagenesis was induced by the implantation of collagen sheets containing purified endotoxin at any dose tested. This suggested that pure endotoxin implanted into tissues having poor circulation of bodily fluids without bleeding may not be recognized as a foreign substance and may not induce a significant biological response. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 1514-1524, 2017.

Role of nitric oxide in post-ischemic gingival hyperemia in anesthetized dogs.

The possible involvement of nitric oxide (*NO) in the preservation of blood flow to the canine gingiva after compression of gingival tissue was studied. Gingival blood flow, gingival tissue oxygen partial pressure (PO2), external carotid arterial blood pressure and external carotid arterial blood flow were monitored before, during, and after compression of gingival tissue in the presence and absence of the nitric oxide synthase inhibitor, Nomega-nitro-L-arginine-methyl-ester (L-NAME). Compression of gingival tissue resulted in an immediate decrease in gingival blood flow and tissue PO2. After the compression of gingival tissue, hyperemia was observed in the gingiva, which depended on the duration of ischemia. Gingival tissue PO2 slowly recovered during hyperemia. Pretreatment with L-NAME (60 mg/kg, i.a.) significantly suppressed reactive hyperemia in gingival tissue. The L-NAME-suppressed reactive hyperemia was partially reversed by treatment with L-arginine (60 mg/kg, i.a.). In addition, *NO was detected using an *NO selective electrode during interruption of blood flow and during reactive hyperemia in the gingiva. These results suggest that *NO contributes to the vasodilation during reactive hyperemia in gingival tissue, and aids in the maintenance of homeostasis in gingival circulation.

Inhibitory effects of Jixueteng on P. gingivalis-induced bone loss and osteoclast differentiation.

OBJECTIVE: The aim of this study was to investigate the possibility of Jixueteng as a preventive and therapeutic drug for the periodontitis. We investigated the inhibitory effects of Jixueteng on Porphyromonas gingivalis-induced bone loss in mice, antibacterial activity against P. gingivalis and differentiation of osteoclast and viability of cells. MATERIALS AND METHODS: Fifty-four male, 4-week-old C57BL/6N mice, were randomly divided into the following three groups of 18 mice each; group A served as the P. gingivalis non-infected control (sham group), group B was infected orally with P. gingivalis and group C was administered Jixueteng extract in drinking water and was then infected with P. gingivalis. In order to evaluate the effect of Jixueteng, the distance from the alveolar bone crest to the cemento-enamel junction was determined. P. gingivalis suspension was exposed for 1, 15 and 60 min to 5 ml of the Jixueteng extract. Furthermore, to clarify the mechanism of the inhibitory effects of Jixueteng on osteoclast formation, Jixueteng extract was added to the culture of mouse bone marrow cells, osteoclast precursor. RESULTS: Administration of Jixueteng along with P. gingivalis infection significantly reduced alveolar bone loss compared to P. gingivalis infection. Jixueteng treatment at the concentration of 0.01% significantly inhibited osteoclast formation. The addition of Jixueteng extract (0.1%, 0.01%, and 0.001%) to the culture showed a significant inhibition of the number of surviving osteoclasts in a dose-dependent manner. CONCLUSION: Jixueteng has an antibacterial activity against P. gingivalis and inhibitory effects on osteoclastogenesis, it may be useful as a therapeutic drug in the treatment of P. gingivalis-induced periodontitis.

Gingival vascular functions are altered in type 2 diabetes mellitus model and/or periodontitis model.

The association of vascular reactivity between diabetes and periodontal disease has not been clarified. Gingival blood flow was measured by laser Doppler flowmetry for 31 weeks in Wistar rats, Wistar rats orally challenged with Porphyromonas gingivalis (Wistar rats + Porphyromonas gingivalis), Goto-Kakizaki rats, and Goto-Kakizaki rats orally challenged with Porphyromonas gingivalis (Goto-Kakizaki rats + Porphyromonas gingivalis). Effects of alveolar bone resorption on periodontal tissue was enhanced in Wistar rats + Porphyromonas gingivalis, and Goto-Kakizaki rats, with this effect being significantly enhanced by Goto-Kakizaki rats + Porphyromonas gingivalis. Using the L-band electron spin resonance technique, we succeeded in measuring oxidative stress as decay rate constant (K(1) and K(2)) of 3-carbamoyl-2,2,5,5-tetramethylpyrrolidin-1-yloxy in the oral and maxillofacial region of the animal models. The decay rate constant (K(1)) of 3-carbamoyl-2,2,5,5-tetramethylpyrrolidin-1-yloxy was significantly greater in the oral and maxillofacial region of Goto-Kakizaki rats + Porphyromonas gingivalis compared to Wistar rats, Wistar rats + Porphyromonas gingivalis and Goto-Kakizaki rats groups. Gingival reactive hyperemia was attenuated by periodontal disease, and this effect was also remarkable in the diabetes mellitus model. Taken together, we found that vascular endothelial function was decreased in diabetes mellitus and/or periodontal disease animal models due to increasing oxidative stress in the gingival circulation.