Effects of different implant surface properties on the biological behavior of Schwann cells

doi:10.7518/hxkq.2021.03.006

Abstract

Abstract: Objective

This study investigated the effects of different implant surface properties on the biological behavior of Schwann cells.

Methods

Schwann cells (SCs) were cultured on three types of implant surfaces including smooth polished (SMO), sand-blasted, large grit, acid-etched (SLA), and chemically-modified SLA (modSLA). At different time points, the morphology and adhesion of SCs on the implant surfaces were observed by scanning electron microscope. Cell proliferation activity was detected by MTT method. The expression levels of nerve growth factor (NGF) and brain-derived neurotrophic factor (BDNF) were detected by enzyme-linked immunosorbent assay. Changes in the mRNA levels of NGF and BDNF were detected by real-time fluorescent quantitative polymerase chain reaction (PCR).

Results

SCs adhered, stretched, and proliferated well on the three types of implant surfaces. On the 3rd, 5th, and 7th days, the OD values of the SMO group were higher than those of the SLA group and the modSLA group, and the difference was statistically significant (P<0.05). On the 3rd day, the expression and mRNA levels of NGF and BDNF in the SLA group and the modSLA group were higher than those in the SMO group (P<0.05); in particular, the levels in the modSLA group were higher than those in the SLA group (P<0.05).

Conclusion

Different implant surface properties have different effects on the biological behavior of SCs. Proliferation of SCs is significantly promoted by smooth surface, while secretion and gene expression of neurotrophic factors are significantly promoted by modSLA surface at early stage.

Key words: implant, surface treatment, Schwann cells, nerve regeneration

CLC Number:

R 783.4

Wang Yanying, Gong Ping, Zhang Jian. Effects of different implant surface properties on the biological behavior of Schwann cells[J]. West China Journal of Stomatology, 2021, 39(3): 279-285.

Figures/Tables 7

Fig 1

Fig 2

Fig 3

Fig 4

Fig 5

Fig 6

Fig 7

References 24

1	Bhatnagar VM, Karani JT, Khanna A, et al. Osseoperception: an implant mediated sensory motor control—a review[J]. J Clin Diagn Res, 2015, 9(9): ZE18-ZE20.
2	Mishra SK, Chowdhary R, Chrcanovic BR, et al. Osseoperception in dental implants: a systematic review[J]. J Prosthodont, 2016, 25(3): 185-195.
3	Kazemi M, Geramipanah F, Negahdari R, et al. Active tactile sensibility of single-tooth implants versus natural dentition: a split-mouth double-blind randomized clinical trial[J]. Clin Implant Dent Relat Res, 2014, 16(6): 947-955.
4	Reveredo AM, Shetty S, Babu CS, et al. Evaluation of active tactile perception of single tooth implant prosthesis[J]. Int J Oral Implant Clin Res, 2013, 4(1): 1-6.
5	Grieznis L, Apse P, Blumfelds L. Passive tactile sensibility of teeth and osseointegrated dental implants in the maxilla[J]. Stomatologija, 2010, 12(3): 80-86.
6	Habre-Hallage P, Abboud-Naaman NB, Reychler H, et al. Perceptual changes in the peri-implant soft tissues assessed by directional cutaneous kinaesthesia and graphaesthesia: a prospective study[J]. Clin Implant Dent Relat Res, 2011, 13(4): 296-304.
7	Corpas Ldos S, Lambrichts I, Quirynen M, et al. Peri-implant bone innervation: histological findings in humans[J]. Eur J Oral Implantol, 2014, 7(3): 283-292.
8	Wada S, Kojo T, Wang YH, et al. Effect of loading on the development of nerve fibers around oral implants in the dog mandible[J]. Clin Oral Implants Res, 2001, 12(3): 219-224.
9	Coulpier F, Decker L, Funalot B, et al. CNS/PNS boundary transgression by central Glia in the absence of Schwann cells or Krox20/Egr2 function[J]. J Neurosci, 2010, 30(17): 5958-5967.
10	Rupp F, Scheideler L, Olshanska N, et al. Enhancing surface free energy and hydrophilicity through chemical modification of microstructured titanium implant surfaces[J]. J Biomed Mater Res A, 2006, 76(2): 323-334.
11	杜娟, 姜焕焕, 莫嘉骥, 等. 钛表面形貌和亲水性表面对成骨细胞增殖、分化的影响[J]. 中国口腔颌面外科杂志, 2012, 10(3): 182-187.
	Du J, Jiang HH, Mo JJ, et al. Effect of hydrophilic titanium surface on the proliferation and differentiation of osteoblasts[J]. China J Oral Maxillofac Surg, 2012, 10(3): 182-187.
12	Terheyden H, Lang NP, Bierbaum S, et al. Osseointegration: communication of cells[J]. Clin Oral Implants Res, 2012, 23(10): 1127-1135.
13	Ganeles J, Zöllner A, Jackowski J, et al. Immediate and early loading of Straumann implants with a chemically modified surface (SLActive) in the posterior mandible and maxilla: 1-year results from a prospective multicenter study[J]. Clin Oral Implants Res, 2008, 19(11): 1119-1128.
14	Wall I, Donos N, Carlqvist K, et al. Modified titanium surfaces promote accelerated osteogenic differentiation of mesenchymal stromal cells in vitro[J]. Bone, 2009, 45(1): 17-26.
15	Miron RJ, Oates CJ, Molenberg A, et al. The effect of enamel matrix proteins on the spreading, proliferation and differentiation of osteoblasts cultured on titanium surfaces[J]. Biomaterials, 2010, 31(3): 449-460.
16	Madduri S, Gander B. Schwann cell delivery of neurotrophic factors for peripheral nerve regeneration[J]. J Peripher Nerv Syst, 2010, 15(2): 93-103.
17	Zhang JY, Luo XG, Xian CJ, et al. Endogenous BDNF is required for myelination and regeneration of injured sciatic nerve in rodents[J]. Eur J Neurosci, 2000, 12(12): 4171-4180.
18	Yuan Q, Liao DP, Yang XM, et al. Effect of implant surface microtopography on proliferation, neurotrophin secretion, and gene expression of Schwann cells[J]. J Bio-med Mater Res A, 2010, 93(1): 381-388.
19	Yin C, Li B, Wang H, et al. Biological behaviors of RSC-96 cells and dorsal root ganglion neurons on different titanium surface topographies[J]. J Biomater Tissue Eng, 2016, 6(12): 967-974.
20	Collazos-Castro JE, Cruz AM, Carballo-Vila M, et al. Neural cell growth on TiO₂ anatase nanostructured surfaces[J]. Thin Solid Films, 2009, 518(1): 160-170.
21	王艳颖, 宫苹, 张健. 血小板衍生生长因子对大鼠种植体周围神经再生影响的研究[J]. 华西口腔医学杂志, 2019, 37(4): 350-354.
	Wang YY, Gong P, Zhang J. Effects of platelet-derived growth factor on nerve regeneration around implant in rats[J]. West China J Stomatol, 2019, 37(4): 350-354.
22	Huang Y, van Dessel J, Martens W, et al. Sensory innervation around immediately vs. delayed loaded implants: a pilot study[J]. Int J Oral Sci, 2015, 7(1): 49-55.
23	李保胜. 不同种植体表面形貌对神经再生影响的初步研究[D]. 长春: 吉林大学, 2013.
	Li BS. Preliminary study on the effect of surface topo-graphy on nerve regeneration in different implant[D]. Changchun: Jilin University, 2013.
24	Enkling N, Utz KH, Bayer S, et al. Osseoperception: active tactile sensibility of osseointegrated dental implants[J]. Int J Oral Maxillofac Implants, 2010, 25(6): 1159-1167.

[1]	Wang Liangtao, Li Shan, Lu Doudou, Chen Zheng.. Structural design of gradient porous dental implant based on orthogonal test [J]. West China Journal of Stomatology, 2023, 41(6): 647-652.
[2]	Zhang Sui, Sun Yi, Huang Changbo, He Dongning. Correlation between differences in intraoperative jumping gaps and soft tissue changes around immediate implant placement and provisionalization in the maxillary anterior region [J]. West China Journal of Stomatology, 2023, 41(6): 678-685.
[3]	Wang Xudong, Wei Hongpu, Li Biao.. From “Empirical Surgery” to “Precision Surgery”: establishment and clinical application of precision orthognathic surgery system [J]. West China Journal of Stomatology, 2023, 41(5): 491-501.
[4]	Liu Yuting, Yuan Quan.. Clinical decision and related factors influencing implant direction in the esthetic area [J]. West China Journal of Stomatology, 2023, 41(5): 512-520.
[5]	Kang Fujia, Yu Lei, Zhang Qi, Li Xinpeng, Hu Zhiqiang, Zhu Xianchun.. Three-dimensional finite element study of mandibular first molar distalization with clear aligner [J]. West China Journal of Stomatology, 2023, 41(4): 405-413.
[6]	Hu Nan, Liu Chunxu, Gao Jing, Xie Chenyang, Yu Jiayi, Jia Luming, Yu Haiyang.. Simultaneous implantation and tooth preparation technology guided by 3D-printed guide [J]. West China Journal of Stomatology, 2023, 41(4): 483-490.
[7]	Ren Bihui, Guo Shuigen, Xu Yehao, Dai Jieting, Wei Hongwu.. Clinical efficacy of simple taper retentive implants in immediate posterior dental implantation for 5-7 years [J]. West China Journal of Stomatology, 2023, 41(3): 341-349.
[8]	Su Wenqi, Li Jingwen, Jiang Lishan, Cui Wenjie, Zhao Yang, Li Houxuan.. In vitro research of oral microscope-assisted implant surface decontamination [J]. West China Journal of Stomatology, 2023, 41(3): 350-355.
[9]	Shan Xiaofeng, Cai Zhigang.. Dental implant treatment in vascularized bone flaps after jaw reconstruction [J]. West China Journal of Stomatology, 2023, 41(2): 123-128.
[10]	Zhang Qihang, Gong Jiaming, Yu Jiaying, Zhao Ruimin, Gou Ping, Yu Zhanhai. Clinical efficacy of extra-short implant (4 mm) placed in posterior areas: a Meta-analysis [J]. West China Journal of Stomatology, 2023, 41(1): 80-87.
[11]	Wang Yingkai, Xie Chenyang, Zhang Yuqiang, Zhang Yameng, Fang Tinglu, Yu Haiyang.. Application of measurable surgical guides in immediate implant placement and immediate restoration [J]. West China Journal of Stomatology, 2022, 40(6): 731-739.
[12]	Yu Haiyang, Sun Manlin, Wang Zhongyi.. Clinical decision-making of anterior implant abutment [J]. West China Journal of Stomatology, 2022, 40(5): 504-512.
[13]	Gong Jiaming, Zhang Qihang, Gou Ping, Wang Hui, Yu Jiaying, Yu Zhanhai. Meta-analysis of application of autogenous dentin for alveolar ridge augmentation [J]. West China Journal of Stomatology, 2022, 40(5): 566-575.
[14]	Shi Zean, Xia Kai, Luo Liangyu, Zhao Zhihe, Liu Jun.. Three-dimensional finite element analysis of upper anterior teeth retraction and intrusion using clear aligners and mini-implants [J]. West China Journal of Stomatology, 2022, 40(5): 589-596.
[15]	Jiang Dandan, Zhou Zheng, Shen Yufeng, Tang Xiaoxue, Gou Xiaorui, Huang Meiyu, Tong Yizhou, Chen Miaomiao, Yu Chong-qing. Expression and significance of mucin-4 and matrix metalloproteinase-7 in peri-implant disease [J]. West China Journal of Stomatology, 2022, 40(1): 45-51.