Stübinger Stefan, Waser Jasmin, Hefti Thomas, Drechsler Anika, Sidler Michéle, Klein Karina, von Rechenberg Brigitte, Schlottig Falko
Musculoskeletal Research Unit, Equine Hospital, Vetsuisse Faculty ZH, University of Zurich, Zurich, Switzerland; Center of Applied Biotechnology and Molecular Medicine (CABMM), Vetsuisse Faculty, University of Zurich, Zurich, Switzerland.
Clin Oral Implants Res. 2015 May;26(5):572-80. doi: 10.1111/clr.12445. Epub 2014 Jul 2.
The aim of this study was to evaluate the clinical performance of local cancellous bone amelioration by a 70:30 poly-(L-lactide-co-D,L-Lacide) copolymer with two different implant designs on primary stability and after 4 and 12 weeks of healing time.
In six sheep, n = 36 implants (TH) with a conditioned, sandblasted, thermal acid-etched micro-rough surface and n = 36 implants (NB) with a highly crystalline and phosphate-enriched anodized titanium oxide surface were placed in the pelvic bone. Using an ultrasound-based process named Constant Amelioration Process (CAP), half of peri-implant trabecular bone structures were locally tested with 70:30 poly-(L-lactide-co-D,L-Lacide) copolymer in both implant groups, TH and NB. The CAP technology employs ultrasonic energy to liquefy 70:30 poly-(L-lactide-co-D,L-Lacide) which enters the inter-trabecular space, leading to local reinforcement of the cancellous bone structure after solidification of the copolymer. The CAP test group was compared with reference implants placed with the conventional site preparation according to the manufacturers' description. Primary stability was assessed by the measurement of torque-in values and implant stability quotient (ISQ; n = 18 per group). Secondary stability was analyzed by biomechanical removal torque testing after 4 and 12 weeks (n = 9 per group).
Insertion torque value (23.3 N cm ± 13.6) of reference TH implants demonstrated a statistically significant (P = 0.00) difference in comparison with test TH implants (41.9 N cm ± 19.5). Reference NB implants revealed a statistically significant (P = 0.03) lower insertion torque value (23.7 N cm ± 13.5) than test NB implants (39.7 N cm ± 18.6). ISQ values increased for all implants from initial implant placement until sacrifice at 12 weeks. Reference TH implants tended to result in an increase in torque values from 4 weeks (181.9 N cm ± 22.8) to 12 weeks (225.7 N cm ± 47.4). This trend could be also proven for implants of test sites (4 week: 176.8 N cm ± 24.1; 12 week: 201.5 N cm ± 53.4). For reference, NB implants a non-significant increase in removal torque values from 4 weeks (146. 7 N cm ± 18.0) to 12 weeks (170.2 N cm ± 40.4) was observed. Removal torque values of test NB implants did not increase from 4 weeks (153.3 N cm ± 21.5) to 12 weeks (146.1 N cm ± 37.5).
Biomechanical data proved significantly enhanced primary stability of dental implants after local amelioration without long-term sequelae and irrespective of implant design. After 4- and 12-week healing time, removal torque of locally test implants was as high as for control implants, and osseointegration was therefore not influenced by the CAP process. No correlation between ISQ values and torque values was found.
本研究旨在评估采用70:30聚(L-丙交酯-co-D,L-丙交酯)共聚物对局部松质骨进行改良,并结合两种不同种植体设计,在种植后即刻稳定性以及愈合4周和12周后的临床性能。
在6只绵羊的骨盆骨中植入36枚具有经过处理、喷砂、热酸蚀微粗糙表面的种植体(TH组)和36枚具有高度结晶且富含磷酸盐的阳极氧化钛表面的种植体(NB组)。采用一种名为持续改良工艺(CAP)的基于超声的方法,在TH组和NB组这两个种植体组中,对一半种植体周围的小梁骨结构局部应用70:30聚(L-丙交酯-co-D,L-丙交酯)共聚物进行测试。CAP技术利用超声能量使70:30聚(L-丙交酯-co-D,L-丙交酯)液化,该共聚物进入小梁间隙,在共聚物固化后导致松质骨结构的局部强化。将CAP测试组与根据制造商说明采用传统位点制备方法植入的对照种植体进行比较。通过测量植入扭矩值和种植体稳定性商数(ISQ;每组n = 18)评估即刻稳定性。在4周和12周后通过生物力学去除扭矩测试分析二期稳定性(每组n = 9)。
对照TH种植体的植入扭矩值(23.3 N·cm ± 13.6)与测试TH种植体(41.9 N·cm ± 19.5)相比,差异具有统计学意义(P = 0.00)。对照NB种植体的植入扭矩值(23.7 N·cm ± 13.5)显著低于测试NB种植体(39.7 N·cm ± 18.6)(P = 0.03)。从种植即刻到12周处死时,所有种植体的ISQ值均增加。对照TH种植体的扭矩值从4周时的(181.9 N·cm ± 22.8)增加到12周时的(225.7 N·cm ± 47.4)。测试位点的种植体也呈现出这种趋势(4周:176.8 N·cm ± 24.1;12周:201.5 N·cm ± 53.4)。对于对照NB种植体,观察到去除扭矩值从4周时的(146.7 N·cm ± 18.0)到12周时的(170.2 N·cm ± 40.4)无显著增加。测试NB种植体的去除扭矩值从4周时的(153.3 N·cm ± 21.5)到12周时的(146.1 N·cm ± 37.5)没有增加。
生物力学数据证明,局部改良后牙种植体的即刻稳定性显著增强,且无长期后遗症,与种植体设计无关。在愈合4周和12周后,局部测试种植体的去除扭矩与对照种植体一样高,因此骨结合未受CAP工艺影响。未发现ISQ值与扭矩值之间存在相关性。
