수산화인회석은 생체적합성이 뛰어나기 때문에 생체재료로 사용되고 있다. 본 연구에서는 온도, 농도, pH를 조절하여 인산수소칼슘 중간체의 가수분해반응을 통해 c면이 배향된 수산화인회석을 합성하였다. 염기조건에서 전구체의 농도가 낮을 경우 막대 형태의 수산화인회석 결정이 모여 불규칙한 형태의 입자를 만들었고 농도가 높을 경우 수산화인회석결정의 c면이 노출된 판 형태의 입자를 만들었으며 이에 따라 입자의 제타전위 차가 3 mV가 되었다. 생성물의 물리화학적 특성은 XRD, SEM, FT-IR, 제타전위측정기를 통해 평가하였다.
It is necessary to improve the esthetic and function in the patient with oral and maxillofacial bone defects. Synthetic bone substitute materials and anorganic bovine bone mineral(ABBM) have been used for clinical restoration. The purpose of this study was to observe the biocompatibility and bone formation of synthetic hydroxyapatite(SHA) and ABBM in hole of rabbit's tibia. After specimens with SHA and ABBM at 8 weeks were fixed in 10% neutral formalin solution, dehydrated, and embedded with spurr low viscosity, they were cut by 500um with slow diamond wheel saw and grinded up to 200um in thickness. These specimens were coated with carbon and examined with r efraction microscope for bone density. Refraction microscopic features of 8 weeks in synthetic HA showed network-like new bone forming trabecular pattern attached to resorbed HA. Less well calcified trabecular bone surrounding conglomerated HAs showed irregular arrangement of numerous osteocytes. There was not completely filled in defected area by new bone trabecular. New trabecular bone formation by ABBM was more prominent and completely compacted in defect hole at 8 weeks. It suggested that although bone formation activity of AMMB might be superior to that on synthetic HA, both group would be the good biocompatibility in this experiment.
This experiment was performed to study the biocompatibility of xenograft materials (ABBM. coralline HA). Both autogenous bone grafts and allogenic banked bone were frequently and successfully used to promote regeneration of parts of skeleton. The use of these types of grafts were limited by the cost of donor site operation for autogenous boneor by fear of the risk of infection of allogenic materials. Another type of graft is xenograft which include ABBM and coralline HA. For investigating the biocompatibility, generally many investigators used cancer cell lines or animal cell lines. But cancer cell lines and animal cell lines had functioned different metabolism from normal human cell. So the experiment used normal human osteoblast for compare the biocompatibility of ABBM with coralline HA which were fixed in 24 well base contained culture medium. After 1st, 3rd, 7th, 14th, 28th days, the culture medium were taken out and checked the concentrations ofcalcium( Ca), inorganic phosphate(IP) and alkaline phosphatase(ALP). In another method, histologic samples were investigated after 8weeks of xenograft materials implantated on rabbit's tibia, the bone was cut and made undecalcified ground samples and checked with fluorecent microscope, polarizing microscope, reflection electron microscope and electron probe microanalysis. The statistical results of concentrations (Ca, IP, ALP) of materials in the culture medium have decreasedby day's, which meant that xenograft materials were effective for bone remodelling. The concentrations in the culture medium of ABBM were lower than that of coralline HA, that meant that biocompatibility of ABBM were superior than that of coralline HA. Histologic samples showed that ABBM had better bone remodelling effect than coralline HA. ABBM showed good alizarin red marking lines, more deposition of Ca, IP, and dense color of bone around newly formed osteon and bone trabeculae. it was concluded that ABBM was more biocompatible than corallineHA in vivo and in vitro test