Duarte Poliana Mendes, Reis André Figueiredo, de Freitas Patrícia Moreira, Ota-Tsuzuki Claudia
Department of Periodontics, Dental Research Division, Guarulhos University, Guarulhos, SP, Brazil.
J Periodontol. 2009 Nov;80(11):1824-32. doi: 10.1902/jop.2009.090273.
Newly formed biofilm after implant debridement may challenge the long-term stability of peri-implant therapy. This in vitro study aimed to assess the roughness and adherence of Streptococcus sanguinis after treatment of smooth and rough titanium surfaces with an erbium-doped:yttrium, aluminum, and garnet (Er:YAG) laser, metal and plastic curets, and an air-powder abrasive system.
Forty titanium disks with smooth-machined surfaces and 40 with sand-blasted and acid-etched surfaces were divided into the following treatment groups: Er:YAG laser; plastic curet; metal curet, and air-powder abrasive system. The surface roughness (roughness average [Ra]) before and after treatments was determined using a profilometer. S. sanguinis (American Type Culture Collection 10556) was grown on treated and untreated specimens, and the amounts of retained bacteria on the surfaces were measured by the culture method. Rough and smooth surfaces with and without a suspension of S. sanguinis were also analyzed using scanning electron microscopy (SEM).
For smooth surfaces, the roughest surfaces were produced by metal curets (repeated-measures analysis of variance [ANOVA] and Tukey test; P <0.05). The rough-surface profile was not altered by any of the treatments (repeated-measures ANOVA; P >0.05). Rough surfaces treated with metal curets and air-powder abrasion showed the lowest level of bacterial adhesion (two-way ANOVA and Tukey test; P <0.05). SEM analysis revealed distinct surface profiles produced by all devices.
Metal curets are not recommended for smooth titanium surface debridement due to severe texture alteration. Rough surfaces treated with a metal curet and the air-powder abrasive system were less susceptible to bacterial adhesion, probably due to texture modification and the presence of abrasive deposits.
种植体清创后新形成的生物膜可能会对种植体周围治疗的长期稳定性构成挑战。本体外研究旨在评估用掺铒钇铝石榴石(Er:YAG)激光、金属和塑料刮治器以及气粉研磨系统处理光滑和粗糙钛表面后血链球菌的粗糙度和黏附情况。
将40个表面经过机械加工光滑的钛盘和40个经过喷砂和酸蚀处理的表面粗糙的钛盘分为以下治疗组:Er:YAG激光组;塑料刮治器组;金属刮治器组和气粉研磨系统组。使用轮廓仪测定处理前后的表面粗糙度(平均粗糙度[Ra])。血链球菌(美国典型培养物保藏中心10556)在处理过和未处理的样本上生长,通过培养法测量表面留存的细菌数量。还使用扫描电子显微镜(SEM)对有和没有血链球菌悬液的粗糙和光滑表面进行了分析。
对于光滑表面,金属刮治器产生的表面最粗糙(重复测量方差分析[ANOVA]和Tukey检验;P<0.05)。粗糙表面的轮廓未因任何处理而改变(重复测量ANOVA;P>0.05)。用金属刮治器和气粉研磨处理的粗糙表面显示出最低水平的细菌黏附(双向ANOVA和Tukey检验;P<0.05)。SEM分析揭示了所有器械产生的不同表面轮廓。
由于严重的质地改变,不建议使用金属刮治器对光滑钛表面进行清创。用金属刮治器和气粉研磨系统处理的粗糙表面对细菌黏附的敏感性较低,可能是由于质地改变和磨料沉积物的存在。
