• Journal of Dental Anesthesia and Pain Medicine
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• 제16권4호
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• pp.263-271
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• 2016

Background: Bone injury is common in many clinical situations, such as surgery or trauma. During surgery, excessive reactive oxygen species (ROS) production decreases the quality and quantity of osteoblasts. Remifentanil decreases ROS production, reducing oxidative stress and the inflammatory response. We investigated remifentanil's protective effects against $H_2O_2$-induced oxidative stress in osteoblasts. Methods: To investigate the effect of remifentanil on human fetal osteoblast (hFOB) cells, the cells were incubated with 1 ng/ml of remifentanil for 2 h before exposure to $H_2O_2$. For induction of oxidative stress, hFOB cells were then treated with $200{\mu}M$ $H_2O_2$ for 2 h. To evaluate the effect on autophagy, a separate group of cells were incubated with 1 mM 3-methyladenine (3-MA) before treatment with remifentanil and $H_2O_2$. Cell viability and apoptotic cell death were determined via MTT assay and Hoechst staining, respectively. Mineralized matrix formation was visualized using alizarin red S staining. Western blot analysis was used to determine the expression levels of bone-related genes. Results: Cell viability and mineralized matrix formation increased on remifentanil pretreatment before exposure to $H_2O_2$-induced oxidative stress. As determined via western blot analysis, remifentanil pretreatment increased the expression of bone-related genes (Col I, BMP-2, osterix, and $TGF-{\beta}$). However, pretreatment with 3-MA before exposure to remifentanil and $H_2O_2$ inhibited remifentanil's protective effects on hFOB cells during oxidative stress. Conclusions: We showed that remifentanil prevents oxidative damage in hFOB cells via a mechanism that may be highly related to autophagy. Further clinical studies are required to investigate its potential as a therapeutic agent.

• Journal of Periodontal and Implant Science
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• 제46권4호
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• pp.220-233
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• 2016

Purpose: The aim of this study was to present new a model that allows the study of the bone healing process, with an emphasis on the biological behavior of different graft-to-host interfaces. A standardized "over-inlay" surgical technique combined with a differential histomorphometric analysis is presented in order to optimize the use of critical-size calvarial defects in pre-clinical testing. Methods: Critical-size defects were created into the parietal bone of 8 male Wistar rats. Deproteinized bovine bone (DBBM) blocks were inserted into the defects, so that part of the block was included within the calvarial thickness and part exceeded the calvarial height (an "over-inlay" graft). All animals were sacrificed at 1 or 3 months. Histomorphometric and immunohistochemical evaluation was carried out within distinct regions of interest (ROIs): the areas adjacent to the native bone (BA), the periosteal area (PA) and the central area (CA). Results: The animals healed without complications. Differential morphometry allowed the examination of the tissue composition within distinct regions: the BA presented consistent amounts of new bone formation (NB), which increased over time ($24.53%{\pm}1.26%$ at 1 month; $37.73%{\pm}0.39%$ at 3 months), thus suggesting that this area makes a substantial contribution toward NB. The PA was mainly composed of fibrous tissue ($71.16%{\pm}8.06%$ and $78.30%{\pm}2.67%$, respectively), while the CA showed high amounts of DBBM at both time points ($78.30%{\pm}2.67%$ and $74.68%{\pm}1.07%$, respectively), demonstrating a slow remodeling process. Blood vessels revealed a progressive migration from the interface with native bone toward the central area of the graft. Osterix-positive cells observed at 1 month within the PA suggested that the periosteum was a source of osteoprogenitor elements. Alkaline phosphatase data on matrix deposition confirmed this observation. Conclusions: The present model allowed for a standardized investigation of distinct graft-to-host interfaces both at vertically augmented and inlay-augmented sites, thus possibly limiting the number of animals required for pre-clinical investigations.

• Journal of Dental Anesthesia and Pain Medicine
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• 제16권1호
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• pp.39-47
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• 2016

Background: Oxidative stress occurs during the aging process and other conditions such as bone fracture, bone diseases, and osteoporosis, but the role of oxidative stress in bone remodeling is unknown. Propofol exerts antioxidant effects, but the mechanisms of propofol preconditioning on oxidative stress have not been fully explained. Therefore, the aim of this study was to evaluate the protective effects of propofol against $H_2O_2$-induced oxidative stress on a human fetal osteoblast (hFOB) cell line via activation of autophagy. Methods: Cells were randomly divided into the following groups: control cells were incubated in normoxia (5% $CO_2$, 21% $O_2$, and 74% $N_2$) without propofol. Hydrogen peroxide ($H_2O_2$) group cells were exposed to $H_2O_2\;(200{\mu}M)$ for 2 h, propofol preconditioning (PPC)/$H_2O_2$ group cells were pretreated with propofol then exposed to $H_2O_2$, 3-methyladenine (3-MA)/PPC/$H_2O_2$ cells were pretreated with 3-MA (1 mM) and propofol, then were exposed to $H_2O_2$. Cell viability and apoptosis were evaluated. Osteoblast maturation was determined by assaying bone nodular mineralization. Expression levels of bone related proteins were determined by western blot. Results: Cell viability and bone nodular mineralization were decreased significantly by $H_2O_2$, and this effect was rescued by propofol preconditioning. Propofol preconditioning effectively decreased $H_2O_2$-induced hFOB cell apoptosis. However, pretreatment with 3-MA inhibited the protective effect of propofol. In western blot analysis, propofol preconditioning increased protein levels of collagen type I, BMP-2, osterix, and TGF-${\beta}1$. Conclusions: This study suggests that propofol preconditioning has a protective effect on $H_2O_2$-induced hFOB cell death, which is mediated by autophagy activation.

• 한국식품영양과학회지
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• 제42권7호
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• pp.1015-1021
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• 2013

창과감초(Glycyrrhiza inflata Batal)는 한약재의 조화를 돕고 해독, 항염증, 항궤양 등의 약리작용으로 한방에서 널리 이용되는 약용식물이다. 본 연구에서는 지방세포와 조골세포에서 감초의 생리활성을 확인하고자 감초에탄올추출물(GBE)을 이용하여 세포분화 촉진여부를 조사하였다. GBE의 세포독성여부를 통해 안전하다고 확인된 $1{\sim}30{\mu}g/mL$의 농도 내에서 실험이 진행되었고 지방세포 분화조건에서 다분화능 세포 C3H10T1/2과 지방전구세포 3T3-L1의 Oil Red O 염색을 통해 GBE의 지방세포분화 촉진효과를 확인할 수 있었다. 또한 지방세포의 핵심전사조절인자인 $PPAR{\gamma}$와 그의 표지유전자 aP2, AdipoQ, $C/EBP{\alpha}$의 발현량 증가를 통해 GBE의 지방세포분화 촉진효과를 재확인하였다. 이와 일관된 결과로서 조골세포 분화조건에서 다분화능 세포 C3H10T1/2과 조골전구세포 MC3T3-E1의 ALP 염색을 통해 GBE의 조골세포분화 촉진효과를 확인하였고 조골세포 표지유전자인 ALP, RUNX2, osterix, collagen의 발현량 증가를 통해 GBE의 조골세포분화 촉진효과를 재확인하였다. 이에 따라 본 연구에서는 GBE의 지방세포와 조골세포 분화효과를 매개하는 감초의 구성성분을 조사하기 위해 GA(glycyrrhizic acid)와 LA(licochalcone A)의 분화촉진 여부를 확인한 결과, GA는 영향을 주지 않으나 LA가 GBE의 세포분화효과를 매개한다고 사료된다. 따라서 본 연구에서는 제2형 당뇨와 그에 수반되는 골질환과 골다공증에 대한 치료 소재로서 GBE와 그의 생리활성을 매개할 수 있는 LA의 가능성을 보았으며 GBE에서 분리되는 다양한 화합물의 동정 및 생리활성 효과, LA와의 상승효과 등의 추후 연구가 기대된다.