中国组织工程研究与临床康复
中國組織工程研究與臨床康複
중국조직공정연구여림상강복
JOURNAL OF CLINICAL REHABILITATIVE TISSUE ENGINEERING RESEARCH
2010年
8期
1504-1507
,共4页
金属加强丝%义齿修理%弯曲强度%聚甲基丙烯酸甲酯%口腔生物材料
金屬加彊絲%義齒脩理%彎麯彊度%聚甲基丙烯痠甲酯%口腔生物材料
금속가강사%의치수리%만곡강도%취갑기병희산갑지%구강생물재료
背景:聚甲基丙烯酸甲酯长期以来作为义齿基托材料在牙科领域得到了广泛应用,然而义齿折裂是修复学至今尚未解决的难题.因此,如何增强义齿修理后的弯曲强度显得尤为重要.目的:研究加入不同数目的金属加强丝对义齿基托修理后弯曲强度的影响.方法:用聚甲基丙烯酸甲酯热凝树脂制作25个50 mm×30 mm×2.5 mm 的长方体试件,将试件在万能试验机上压断,测得其弯曲强度.各组试件断面经预备后分别加入1~4根不锈钢丝,未加入钢丝组为对照组,并用自凝树脂修理裂缝,测定修理后试件的弯曲强度,计算强度恢复率.结果与结论:各组试件修理后的弯曲强度均明显低于修理前(P<0.01).除加入1根钢丝组外,其余各组强度恢复率均高于对照组(P<0.05).加入2,3,4根钢丝各组间强度恢复率比较,差异无显著性意义(P>0.05).结果证实加入2~4叫根金属加强丝可增强义齿基托修理后的弯曲强度.
揹景:聚甲基丙烯痠甲酯長期以來作為義齒基託材料在牙科領域得到瞭廣汎應用,然而義齒摺裂是脩複學至今尚未解決的難題.因此,如何增彊義齒脩理後的彎麯彊度顯得尤為重要.目的:研究加入不同數目的金屬加彊絲對義齒基託脩理後彎麯彊度的影響.方法:用聚甲基丙烯痠甲酯熱凝樹脂製作25箇50 mm×30 mm×2.5 mm 的長方體試件,將試件在萬能試驗機上壓斷,測得其彎麯彊度.各組試件斷麵經預備後分彆加入1~4根不鏽鋼絲,未加入鋼絲組為對照組,併用自凝樹脂脩理裂縫,測定脩理後試件的彎麯彊度,計算彊度恢複率.結果與結論:各組試件脩理後的彎麯彊度均明顯低于脩理前(P<0.01).除加入1根鋼絲組外,其餘各組彊度恢複率均高于對照組(P<0.05).加入2,3,4根鋼絲各組間彊度恢複率比較,差異無顯著性意義(P>0.05).結果證實加入2~4叫根金屬加彊絲可增彊義齒基託脩理後的彎麯彊度.
배경:취갑기병희산갑지장기이래작위의치기탁재료재아과영역득도료엄범응용,연이의치절렬시수복학지금상미해결적난제.인차,여하증강의치수리후적만곡강도현득우위중요.목적:연구가입불동수목적금속가강사대의치기탁수리후만곡강도적영향.방법:용취갑기병희산갑지열응수지제작25개50 mm×30 mm×2.5 mm 적장방체시건,장시건재만능시험궤상압단,측득기만곡강도.각조시건단면경예비후분별가입1~4근불수강사,미가입강사조위대조조,병용자응수지수리렬봉,측정수리후시건적만곡강도,계산강도회복솔.결과여결론:각조시건수리후적만곡강도균명현저우수리전(P<0.01).제가입1근강사조외,기여각조강도회복솔균고우대조조(P<0.05).가입2,3,4근강사각조간강도회복솔비교,차이무현저성의의(P>0.05).결과증실가입2~4규근금속가강사가증강의치기탁수리후적만곡강도.
BACKGROUND: Poly methyl methyacrylate (PMMA) has been widely used as a denture base material in dental field for a long time. However, the fracture of acrylic resin dentures is an unresolved problem in prosthodontics. Therefore, how to improve the flexural strength of repaired denture seems to be extremely important. OBJECTIVE: To study the effect of embedding different amounts of metal wires on the flexural strength of repaired denture bases. METHODS: Twenty-five rectangular specimens (50 mm× 30 mm × 2.5 mm) were fabricated using heat-cured acrylic resins and randomly and evenly divided into five groups: A, B, C, D, and E. All specimens were fractured through the use of universal testing machine, and the flexural strengths were tested. Following preparation of fracture surfaces, one to four metal wires were separately embedded in the groups B, C, D, and E. No metal wires were embedded in the group A. All fractured specimens were repaired using self-curing resins. The flexural strengths were measured again using the same testing machine, and the percentages of strength recovery were calculated. RESULTS AND CONCLUSION: After repair, the flexural strengths were obviously reduced (P < 0.01). Compared to group A, the percentages of strength recovery were significantly increased in groups C, D, and E (P < 0.05). There was no significant difference in the percentage of strength recovery among groups C, D, and E (P > 0.05). These results indicate that embedding two to four metal wires can improve the flexural strength of denture bases.