Journal of Prevention and Treatment for Stomatological Diseases ›› 2019, Vol. 27 ›› Issue (7): 435-440.doi: 10.12016/j.issn.2096-1456.2019.07.005

• Basic Study • Previous Articles     Next Articles

Effect of laser-etched pure titanium surface on early proliferation of MG63 cells

Zehong GUO,Yingyuan NING(),Shulan XU,Peijun ZHU,Xianglong DING,Yan GAO   

  1. Center of Oral Implantology, Stomatological Hospital of Southern Medical University, Guangzhou 510280, China
  • Received:2019-02-02 Revised:2019-04-30 Online:2019-07-20 Published:2019-07-24
  • Contact: Yingyuan NING E-mail:50878976@qq.com

RichHTML

10

PDF (PC)

33

Abstract:

Objective To investigate the effect of a laser-etched pure titanium surface on proliferation of the human osteosarcoma cell line MG63 and to provide a basis for study of implant surface modification. Methods The pure titanium plate was cut into titanium pieces by a numerical control machine tool and divided into smooth surface and laser etching groups. The titanium surface of the laser etching group was etched with an Nd:YAG continuous wave laser using predetermined parameters, and the surfaces were observed by scanning electron microscopy (SEM). The surface micromorphology of each titanium sheet was evaluated. The relative element content of the titanium surface was measured by energy dispersive X-ray spectroscopy (EDS). The Ra value of each surface was determined using the Veeco roughness tester. MG63 cells were inoculated on 2 sets of titanium tablets. At 1, 3, and 6 h postinoculation, cell adhesion to the two groups of titanium sheets was observed under the microscope. At 24 h after inoculation, cellular F-actin was directly stained using immunofluorescence, and the morphology of the cytoskeleton was observed by laser confocal microscopy. Cell proliferation was examined at 1, 3, and 5 d using a MTS kit, and the data were analyzed with SAS 9.4. Results The surface of the smooth surface group was smooth and flat, the element composition was pure titanium, and the roughness Ra was 179.23 nm. The surface of the laser-etched group formed a regular and uniform pore structure. The composition was mainly Ti, O, C, etc, and the surface roughness Ra was 14.11 μm. A large number of cells were uniformly distributed on the two titanium sheets in the observations at 1, 3, and 6 h. At 24 h postinoculation, MG63 cells were completely stretched on the two sets of titanium sheets and had extended a large number of pseudopods and microfilaments to cross-link with peripheral cells; moreover, the cell division phase was observed. The cell proliferation of the two groups at 1, 3, and 5 d showed a significant increase with time, indicating that no cytotoxicity occurred on the surfaces of the two groups. However, the cell proliferation in the laser-etched group was superior to that in the mechanical smooth surface group. Conclusion The surface morphology of titanium can be controlled by laser etching, which is conductive to increase the microstructure of implants without cytotoxicity and promoting osteoblast proliferation in the early stage.

Key words: laser etching, pure titanium, surface treatment, roughness, MG63, proliferation

CLC Number: 

  • R783.1

Figure 1

Surface topography observation by SEM"

Figure 2

X-ray diffraction analysis in the two groups"

Figure 3

Adhesion of MG63 cells to the surfaces in the two groups fluorescence Microscope × 100"

Figure 4

Direct immunofluorescence staining ofF-actin in the two groups confocal laser scanning microscope × 400"

Table 1

The component of two kinds of titanium surface %"

组别 表面所含的元素
Ti O C
光滑表面组 100 0 0
激光蚀刻组 86.6 16.5 0.9

Figure 5

Comparison of OD values between the two surface types at different time points"

[1] Asri R, Harun W, Samykano M , et al. Corrosion and surface modification on biocompatible metals: a review[J]. Mater Sci Eng C Mater Biol Appl, 2017,77:1261-1274.
doi: 10.1016/j.msec.2017.04.102
[2] Ayobianmarkazi N, Karimi M, Safarhajhosseini A . Effects of Er: YAG laser irradiation on wettability, surface roughness, and biocompatibility of SLA titanium surfaces: an in vitro study[J]. Lasers Med Sci, 2015,30(2):1-6.
doi: 10.1007/s10103-013-1333-2
[3] Park KS, Al Awamleh AG, Cho SA . Comparison of removal torques between laser-etched and modified sandblasted acid-etched Ti implant surfaces in rabbit tibias[J]. J Adv Prosthodont, 2018,10(1):73-78.
doi: 10.4047/jap.2018.10.1.73
[4] Guo ZH, Zhou L, Rong MD , et al. Bone response to a pure titanium implant surface modified by laser etching and microarc oxidation[J]. Int J Oral Maxillofac Implants, 2010,25(1):130-136.
[5] Zwahr C, Guenther D, Brinkmann T , et al. Laser surface pattering of titanium for improving the biological performance of dental implants[J]. Adv Healthc Mater, 2017,6(3):1600858.
doi: 10.1002/adhm.v6.3
[6] Naganawa T, Ishihara Y, Iwata T , et al. In vitro biocompatibility of a new titanium-29niobium-13tantalum-4.6zirconium alloy with osteoblast-like MG63 cells[J]. J Periodontol, 2004,75(12):1701-1707.
doi: 10.1902/jop.2004.75.12.1701
[7] Wang M, Ning Y, Zou H , et al. Effect of Nd: YAG laser-nitriding-treated titanium nitride surface over Ti6Al4V substrate on the activity of MC3T3-E1 cells[J]. Biomed Mater Eng, 2014,24(1):643-649.
[8] Hartjen P, Nada O, Silva TG , et al. Cytocompatibility of direct laser interference-patterned titanium surfaces for implants[J]. In Vivo (Brooklyn), 2017,31(5):849-854.
[9] Tavakoli J, Khosroshahi ME . Surface morphology characterization of laser-induced titanium implants: lesson to enhance osseointegration process[J]. Biomed Eng Lett, 2018,8(3):249-257.
doi: 10.1007/s13534-018-0063-6
[10] Peng W, Xu LW, You J , et al. Selective laser melting of titanium alloy enables osseointegration of porous multi-rooted implants in a rabbit model[J]. Biomed Eng Online, 2016,15(1):85.
doi: 10.1186/s12938-016-0207-9
[11] Gotz HE, Muller M, Emmel A , et al. Effect of surface finish on the osseointegration of laser-treated titanium alloy implants[J]. Biomaterials, 2004,25(18):4057-4064.
doi: 10.1016/j.biomaterials.2003.11.002
[12] 丁祥龙, 王敬旭, 郭泽鸿 , 等. RGD肽段修饰TiO2 纳米管对MG63成骨细胞黏附增殖能力的影响[J]. 口腔疾病防治, 2018,26(11):32-37.
[13] Cei S, Karapetsa D, Aleo E , et al. Protein adsorption on a laser-modified titanium implant surface[J]. Implant Dent, 2015,24(2):134-141.
[14] Phani MK, Kumar A, Arnold W , et al. Elastic stiffness and damping measurements in titanium alloys using atomic force acoustic microscopy[J]. J Alloys Compd, 2016,676:397-406.
doi: 10.1016/j.jallcom.2016.03.155
[15] Györgyey Á, Ungvári K, Kecskeméti G , et al. Attachment and proliferation of human osteoblast-like cells(MG-63)on laser-ablated titanium implant material[J]. Mater Sci Eng C, 2013,33(7):4251-4259.
doi: 10.1016/j.msec.2013.06.020
[16] Trisi P, Berardini M, Colagiovanni M , et al. Laser-treated titanium implants: an in vivo histomorphometric and biomechanical analysis[J]. Implant Dent, 2016,25(5):575-580.
doi: 10.1097/ID.0000000000000457
[17] Shah FA, Johansson ML, Omar O , et al. Laser-modified surface enhances osseointegration and biomechanical anchorage of commercially pure titanium implants for bone-anchored hearing systems[J]. PLoS One, 2016,11(6):e0157504.
doi: 10.1371/journal.pone.0157504
[18] Arifagaoglu O, Oncul S, Ercan A , et al. HGF-1 proliferation on titanium dental implants treated with laser melting technology[J]. Niger J Clin Pract, 2019,22(2):251-257.
[19] Lepore S, Milillo L, Trotta T , et al. Adhesion and growth of osteoblast-like cells on laser-engineered porous titanium surface: expression and localization of n-cadherin and beta-catenin[J]. J Biol Regul Homeost Agents, 2013,27(2):531-541.
[20] Perez-Diaz L, Dedavid BA, Gehrke S . Evaluation of fibroblasts cells viability and adhesion on six different titanium surfaces: an in vitro experimental study[J]. Recent Pat Biotechnol, 2018,12(2):145-153.
doi: 10.2174/1872208312666180101165807
[1] WU Fayin,XU Haili. Effect and mechanism of allicin combined with 5-fluorouracil on proliferation and apoptosis of the MEC-1 cell line in mucoepidermoid carcinoma [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2020, 28(6): 355-360.
[2] ZENG Fantao,YU Dongsheng. Knockdown of circ_0001273 inhibits the proliferation, migration and invasion of oral squamous cell carcinoma cells [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2020, 28(3): 153-157.
[3] LIAN Keqian,ZHANG Xin,ZHOU Jieyu,LIAO Yanfen,SI Shanshan. Biocompatibility of bone marrow mesenchymal cells on polyetheretherketone and titanium surfaces in vitro [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2020, 28(2): 73-78.
[4] ZHOU Jiaqi,SHU Linjing,XIONG Yi,ZHANG Yixin,XIANG Lin,WU Yingying. Study on the role of FoxO1 in the regulation of osteoblastic metabolism by 1,25(OH)2D3 in a high glucose environment [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2020, 28(1): 24-29.
[5] HE Jialin, XU Yan, XIE Xianzhe, WANG Tengfei, HUO Dongmei. Effect of platelet-rich fibrin extract on the proliferation of gingival fibroblasts [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2019, 27(8): 490-495.
[6] Yanan LIU,Likai WANG,Sisi LIU,Hui HUI,Haifeng WANG. Comparison of polishing effects of three polishing systems on machinable composite resins [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2019, 27(7): 441-445.
[7] XU Shuaimei,ZENG Xiongqun,YUAN Peiyan,LIU Zhongjun,ZENG Shuguang. The role of APOD in the proliferation and migration of human dental pulp cells [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2019, 27(6): 355-359.
[8] WANG Anxun. Abnormal glucose and lipid metabolism and oral squamous cell carcinoma [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2019, 27(3): 137-142.
[9] ZENG Sujuan,PENG Bo,CHENG Weidong,WEI Dongfeng,HUANG Wenyan,LI Yunyang,ZHAO Wanghong. Experimental study on the effect of hedysarum polybotys saccharides and selenizated hedysarum polybotys saccharides on oral squamous cancer cells in vitro [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2019, 27(12): 757-762.
[10] LU Weiying,LIU Ping,CHEN Jiawei,LIU Shuying,XU Pingping. Effects of X-ray irradiation on proliferation and RANTES expression of the mouse osteogenic precursor cell line MC3T3-E1 [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2019, 27(10): 621-626.
[11] Qiaoli NIU, Yiming LI, Yanyan SONG, Chenxi LI, Jin ZHAO. Effects of different concentrations of MTA on the proliferation and differentiation of stem cells from the apical papilla [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(8): 491-495.
[12] Xiaojin WANG, Xinchao YOU, Kai CHEN, Kunsong HUANG, Xuan PAN. Influence of luteolin on the invasion and migration of an human tongue squamous carcinoma cell line [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(7): 434-439.
[13] Yan GAO, Ying LIU, Lei ZHOU, Shulan XU. Research progress in photocatalysis of titanium dioxide nanowire [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(3): 200-204.
[14] Xianglong DING,Jingxu WANG,Zehong GUO,Chunhua LAI,Yan GAO,Xi LIN,Shulan XU. Effects of RGD-grafted TiO2 nanotubes on the adhesion and proliferation of MG63 osteoblasts [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(11): 706-711.
[15] Songhao YIN, Weihong GUO. Investigation of the expression of TPX2 in tongue squamous cell carcinoma and its effect on Cal27 cell proliferation and apoptosis [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(1): 31-37.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] Hong-chang LAI,Jun-yu SHI. Maxillary sinus floor elevation[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2017, 25(1): 8 -12 .
[2] Pin ZHOU, Yang-fei LI. MRI study of temporomandibular joint disc position in asymptomatic volunteers[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2017, 25(4): 239 -244 .
[3] Xinxin XIA, Fang FANG, Lijuan CHENG. Shaping ability of Pathfile and WaveOne in simulated root canals[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2017, 25(6): 365 -368 .
[4] Yuanhong LI, Xinyi FANG, Yu QIU, Lei CHENG. Experimental study on the effects of green tea on salivary flow rate and pH value[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2017, 25(9): 560 -564 .
[5] Chengzhang LI. Masticatory muscles in occlusion[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2017, 25(12): 755 -760 .
[6] . [J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(1): 1 .
[7] Zhirong WU, Shiguang Huang. Research progress on the etiology, clinical examination and treatment of peri-implantitis[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(6): 401 -405 .
[8] Xiaowu YAO, Shisheng CHEN, Zizheng LU, Minxiao LIN. Clinical report and literature review on the amyloidosis of salivary glands[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(8): 533 -536 .
[9] Lan LIAO, Lijun ZENG. Updated research on digitalization in aesthetic restoration[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2018, 26(7): 409 -414 .
[10] Yu LU, Chengxia LIU, Zhongjun LIU. Role of TRAF6 in inflammatory responses of human osteoblast-like cells with Enterococcusfaecalis[J]. Journal of Prevention and Treatment for Stomatological Diseases, 2017, 25(7): 420 -425 .

Copyright © Editorial Board of Journal of Prevention and Treatment for Stomatological Diseases

This work is licensed under a Creative Commons Attribution 3.0 License.

Address:Guangzhou City Jiangnan Road South 366, Editorial office ofJournal of Prevention and Treatment for Stomatological Diseases, zip code: 510280 Fax:020-34304115 E-mail:kqjbfz@vip.126.com

Supported by:Beijing Magtech

This work is licensed under a Creative Commons Attribution 3.0 License.