• 대한치과보철학회지
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• 제48권3호
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• pp.202-208
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• 2010

연구 목적: 이 연구의 목적은 골형성단백질 (recombinant human Bone Morphogenetic Protein-2; rhBMP-2)이 코팅된 임플란트가 치조골 증대에 미치는 영향을 알아보는 것이다. 연구 재료 및 방법: 6마리의 비글견이 실험에 사용되었다. 6개의 8 mm 길이의 임플란트가 발치 후 6개월 이상의 충분한 치유기간이 경과한 비글견의 치조골에 5 mm 깊이로 식립되었다. 각각의 동물에 좌측과 우측의 악궁-분할형으로 임의추출하여 한쪽에는 1.5 ml/mg 농도의 rhBMP-2가 코팅된 임플란트를, 반대편에는 코팅되지 않은 대조군 임플란트를 식립하고 임플란트 주변 골에 round bur를 이용하여 피질골 천공을 시행하였다. 점막골막판막에 이완절개를 시행하여 판막을 접합시키고 봉합하여 임플란트가 피개되도록 하였다. 방사선 사진 촬영은 수술 직후 (기준치), 수술 4주후, 수술 8주 후에 시행하였다. 측정은 각 방사선 사진의 임플란트 덮개나사 최상방에서 변연골까지의 거리를 측정하여 골 형성량을 계산하였다. 수술 직후와 수술 8주 후에 임플란트 안정도 (Implant Stability Quotient value; ISQ value)를 측정하였다. 통계분석을 위해 SPSS software를 사용하여 Man-Whitney ranksum test와 Wilcoxon signed ranksum test를 시행하였다. 통계적 유의수준은P=.05를 기준으로 하였다. 결과: 골형성단백질이 코팅된 임플란트에서 수직 결손부 상방으로 약 0.6 mm의 골 형성이 관찰되었다. 대조군에서는 제한된 양의 골 형성 혹은 골 소실이 일어났다. 각 시기에 따른 실험군과 대조군간의 골 형성량에 유의한 차이가 있었다 (P<.05). ISQ value는 수술 직후에는 실험군과 대조군의 유의한 차이가 없었지만 수술 8주 후에는 실험군에서 대조군 보다 유의하게 높게 증가되었다 (P<.05). 결론: 골형성단백질이 코팅된 임플란트는 완전히 치유된 치조골에서 임상적으로 유의한 골 증대 효과가 있는 것으로 보인다.

• 한국산림과학회지
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• 제104권3호
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• pp.337-351
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• 2015

한국임학회지(1962년의 1권부터 2013년 102권 4호)에 게재된 산림특용자원식물 논문에서 대상식물을 식 음용식물, 약용식물, 사료식물, 조경식물, 섬유식물, 산업용 식물, 밀원식물, 바이오에너지/환경정화 식물, 염료/도료 및 희귀 멸종위기 특산식물로 분류하고, 그 연구내용에 따라 입지환경, 생태, 생리, 번식, 조림(무육과 재배 포함), 유전 육종, 분류(또는 식별), 병 충해와 방제, 동물피해와 방제, 성분분석과 추출물, 식생 또는 자생지 정보, 생물공학, 경영과 경제, 휴양 및 산림치유 및 총설로 구분하였다. 총 2,433편의 논문 중에서 특용자원식물 관련 논문은 611편으로 25.1%를 나타내었다. 연구내용에서 보면, 조림분야의 논문이 14.9%로 가장 높은 비율을 나타냈으며, 다음으로는 생리, 번식, 분류 및 유전 육종 등의 순으로 나타났다. 식물의 이용 목적에 따라서는 식 음용으로 이용된 식물이 26.5%로 가장 높게 나타났으며, 다음으로는 산업용, 바이오에너지/환경정화, 조경, 약용과 희귀 멸종위기 특산식물 등의 순으로 나타났다. 게재된 식물 중 연구빈도가 가장 높은 식물은 포플러류(62편)였으며, 밤나무, 잣나무, 아까시나무, 은행나무 등의 순으로 나타났다. 연구의 분야, 내용 및 대상식물 결과 등을 종합하여 보면, 1) 산림 내 생물자원에 대한 자원적 가치 인식 제고, 2) 산림과학분야 다양한 영역에서의 생산, 경영 및 이용에 관한 연구, 3) 식물정보의 데이터베이스 구축 및 타 과학 및 산업 분야의 흐름에 부응 및 4) 전통 식물 발굴 등이 산림특용자원식물 분야의 연구에서 깊이 고려되어야 할 것이다.

• Journal of the Korean Association of Oral and Maxillofacial Surgeons
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• 제26권1호
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• pp.59-72
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• 2000

In this study, the rate of bone formation and the pattern of bone to implant contact surface around HA coated implant and pure Ti implant inserted into the irradiated tibia of rabbit were compared. Sixteen mongrel mature male rabbits were used as experimental animal. Each rabbit received 15 Gy of irradiation. Four weeks after irradiation, two holes were prepared on the tibia of each rabbit for placement of HA coated type and pure Ti type implants. Prior to implant placement, one group received steroid irrigation and the control group was similarly irrigated with normal saline. This was immediately followed by placement of the two different types of implants. Postoperatively, tetracycline was injected intramuscularly for 3 days. For fluorescent labelling, 3 days of intramuscular alizarine red injection was given. 2 weeks before sacrifice, followed by intramuscular calcein green on the last 3 days before specimen collection. Each rabbit was sacrificed on the second, fourth, sixth and eighth week after the implantation. The specimens were observed by the light microscope and the fluorescent microscope. The results were as follows; 1. All implants inserted into the irradiated tibia of rabbit were free from clinical mobility and no signs of bony resorption were noted around the site of implant placement. 2. Under the light microscope, new bone formation proceeded faster around implants that received steroid irrigation compared to the control group irrigated with saline. Bone to implant contact surface was greater in the steroid irrigated group than the saline irrigated group. Therefore, better initial stabilization was observed in the group pretreated with steroid irrigation. 3. Under the light microscope. HA coated implants showed broader bone to implant contact surface than pure Ti implants, and HA coated implants had better bone healing pattern than pure Ti implants. 4. In the steroid pretreated group, acceleration of bone formation was demonstrated by fluorescent microscopy around the 2, 4 weeks group and the 6 weeks HA coated implant group. The difference in the rate of bone formation proved to be statistically significant(P<0.05). Faster bone formation was noted in the saline irrigated group in the 6 weeks pure Ti implants and 8 weeks group. The difference was not statistically significant(P<0.05). 5. For the rabbits that were sacrificed on the second and fourth week after the implant placements, the rates of bone formation around HA coated implants proceeded faster than those around pure Ti implants under the fluorescent microscopy. For the rabbits that were sacrificed on the sixth week after the implant placements, the rates of bone formation around pure Ti implants proceeded faster than those around HA coated implants under the fluorescent microscopy. But this result did not show statistical significance (P<0.05) For the rabbits that were sacrificed on the eighth week after the implant placements, the rates of bone formation around HA coated implants proceeded faster than those around pure Ti implants under the fluorescent microscopy. This result was statistically significant (P<0.05).

• Journal of Periodontal and Implant Science
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• 제30권4호
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• pp.851-870
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• 2000

The major goals of periodontal therapy is the functional regeneration of periodontal supporting structures already destructed by periodontal disease as well as the reduction of signs and symptoms of progressive periodontal disease. There have been many efforts to develop materials and therapeutic methods to promote periodontal wound healing. There have been increasing interest on the chitosan made by chitin. Chitin is second only to cellulose as the most abundant natural biopolymer. It is a structural component of the exoskeleton of invertebrates(e.g., shrimp, crabs, lobsters), of the cell wall of fungi, and of the cuticle of insects. Chitosan is a derivative of chitin made by deacetylation of side chains. Many experiments using chitosan in various animal models have proven its beneficial effects. The aim of this study is to evaluate the osteogenesis of chitosan on the calvarial critical size defect in Sprague Dawley rats. An 8 mm surgical defect was produced with a trephine bur in the area of the midsagittal suture. The rats were divided into two groups: Untreated control group versus experimental group with 50mg of soluble chitosan gel. The animals were sacrificed at 2, 4 and 8 weeks after surgical procedure. The specimens were examined by histologic, histomorphometric and radiodensitometric analyses. The results are as follows: 1. The length of newly formed bone in the defects was $102.91{\pm}25.46{\mu}m$, $219.46{\pm}97.81{\mu}m$ at the 2 weeks, $130.95{\pm}39.24{\mu}m$, $212.39{\pm}89.22{\mu}m$ at the 4 weeks, $181.53{\pm}76.35{\mu}m$ and $257.12{\pm}51.22{\mu}m$ at the 8 weeks in the control group and experimental group respectively. At all periods, the means of experimental group was greater than those of control group. But, there was no statistically significant difference between the two groups. 2. The area of newly formed bone in the defects was $2962.06{\pm}1284.48{\mu}m^2$, $5194.88{\pm}1247.88{\mu}m^2$ at the 2 weeks, $5103.25{\pm}1375.88{\mu}m^2$, $7751.43{\pm}2228.20{\mu}m^2$ at the 4 weeks and $8046.20{\pm}818.99{\mu}m^2$, $15578.57{\pm}5606.55{\mu}m^2$ at the 8 weeks in the control group and experimental group respectively. At all periods, the means of experimental group was greater than those of control group. The experimental group showed statistically significant difference to the control group at the 2 and 8 weeks. 3. The density of newly formed bone in the defects was $14.26{\pm}6.33%$, $27.91{\pm}6.65%$ at the 2 weeks, $20.06{\pm}9.07%$, $27.86{\pm}8.20%$ at the 4 weeks and $22.99{\pm}3.76%$, $32.17{\pm}6.38%$ at the 8 weeks in the control group and experimental group respectively. At all periods, the means of experimental group was greater than those of control group. The experimental group showed statistically significant difference to the control group at the 2 and 8 weeks. These results suggest that the use of chitosan on the calvarial defects in rats has significant effect on the regeneration of bone tissue in itself