Email Alert | RSS

Journal of Peking University (Health Sciences) ›› 2025, Vol. 57 ›› Issue (2): 309-316. doi: 10.19723/j.issn.1671-167X.2025.02.014

Previous Articles     Next Articles

Biocompatibility of 3D printed biodegradable WE43 magnesium alloy scaffolds and treatment of bone defects

Shuyuan MIN, Yun TIAN*()   

  1. Department of Orthopedics, Peking University Third Hospital; Engineering Research Center of Bone and Joint Precision Medicine, Ministry of Education, Beijing 100191, China
  • Received:2022-03-02 Online:2025-04-18 Published:2025-04-12
  • Contact: Yun TIAN E-mail:tiany@bjmu.edu.cn
  • Supported by:
    the National Key Research and Development Program of China(2018YFE0104200);National Natural Science Foundation of China(82172065)

RICH HTML

   

PDF (PC)

Abstract:

Objective: To investigate the biocompatibility of porous WE43 magnesium alloy scaffolds manufactured by 3D printing technology and to observe its effect in treating femoral defects in New Zealand white rabbits. Methods: In vitro cytotoxicity test was performed using bone marrow mesenchymal stem cells from Sprague Dawley (S-D) rats. According to the different culture media, the cells were divided into 100% extract group, 50% extract group, 10% extract group and control group. After culturing for 1, 3 and 7 days, the cell activity of each group was determined by cell counting kit-8 (CCK-8). In the in vivo experiment, 3.0-3.5 kg New Zealand white rabbits were randomly divided into three groups: Experimental group, bone cement group and blank group, with 9 rabbits in each group. Each rabbit underwent surgery on the left lateral femoral condyle, and a bone defect with a diameter of 5 mm and a depth of 6 mm was created using a bone drill. The experimental group was implanted with WE43 magnesium alloy scaffolds, the bone cement group was implanted with calcium sulfate bone cement, and the blank group was not implanted. Then 4, 8 and 12 weeks after surgery, 3 rabbits in each group were euthanized by carbon dioxide anesthesia, and the femur and important internal organs were sampled. Micro-computed tomography (Micro-CT) scanning was performed on the left lateral femoral condyle. Sections of important internal organs were prepared and stained with hematoxylin-eosin (HE). Hard tissue sections were made from the left lateral femoral condyle and stained with methylene blue acid fuchsin and observed under a microscope. Results: In the cytotoxicity test, the cell survival rate in the 100% extract group was higher than that in the control group (140.56% vs. 100.00%, P < 0.05) on 1 day of culture; there was no statistically significant difference (P>0.05) in cell survival rate among the groups on 3 days of culture; the cell survival rate in the 100% extract group was lower than that in the control group (68.64% vs. 100.00%, P < 0.05) on 7 days of culture. Micro-CT scanning in the in vivo experiment found that most of the scaffolds in the experimental group had been degraded in 4 weeks, with very few high-density scaffolds remaining. In 12 weeks, there was no obvious stent outline. In 4 weeks, a certain amount of gas was generated around the WE43 magnesium alloy scaffold, and the gas was significantly reduced from 8 to 12 weeks. Hard tissue sections showed that a certain amount of extracellular matrix and osteoid were generated around the scaffolds in the experimental group in 4 weeks. In the bone cement group, most of the calcium sulfate bone cement had been degraded. In 8 weeks, the osteoid around the scaffold and its degradation products in the experimental group increased significantly. In 12 weeks, new bone was in contact with the scaffold around the scaffold in the experimental group. There was less new bone in the bone cement group and the blank group. Conclusion: The porous WE43 magnesium alloy scaffold fabricated by 3D printing process has good biocompatibility and good osteogenic properties, and has the potential to become a new material for repairing bone defects.

Key words: Biodegradable implants, Bone graft, Magnesium alloy, 3D printing, Bone defect

CLC Number: 

  • R681.8

Figure 1

3D printed WE43 magnesium alloy scaffold size and implantation A, scaffold top view; B, scaffold side view; C, implantation."

Figure 2

Cytotoxicity of extracts of different concentrations on bone marrow mesenchymal stem cell **P < 0.01, ***P < 0.001."

Figure 3

Serum biochemistry test of laboratory animal A, serum AST level; B, serum CREA level; C, serum LDH level. AST, aspartate aminotransferase; CREA, creatinine; LDH, lactate dehydrogenase."

Figure 4

Comparison of lateral femoral condyle radiographs at different time points, the yellow oval indicates gas production"

Figure 5

Radiographs of the femoral shaft and proximal femur of the experimental group at 12 weeks showed no residual gas A, femoral shaft; B, proximal femur."

Figure 6

Hard tissue sections of femoral condyle stained with methylene blue and acid fuchsin in each group at different time points ↑, scaffolds and their degradation products; , osteoid; ↑↑, newly formed bone."

Figure 7

Hematoxylin-eosin staining sections of important organs in the experimental group at 12 weeks A, liver, B, kidney; C, brain; D, heart; E, spleen; F, lung."

1 Archunan MW , Petronis S . Bone grafts in trauma and orthopaedics[J]. Cureus, 2021, 13 (9): e17705.
2 Grambart ST , Anderson DS , Anderson TD . Bone grafting options[J]. Clin Podiatr Med Surg, 2020, 37 (3): 593- 600.
doi: 10.1016/j.cpm.2020.03.012
3 Lodoso-Torrecilla I , van den Beucken J , Jansen JA . Calcium phosphate cements: Optimization toward biodegradability[J]. Acta Biomater, 2021, 119, 1- 12.
doi: 10.1016/j.actbio.2020.10.013
4 Kani KK , Porrino JA , Chew FS . External fixators: Looking beyond the hardware maze[J]. Skeletal Radiol, 2020, 49 (3): 359- 374.
doi: 10.1007/s00256-019-03306-w
5 Deng F , Liu L , Li Z , et al. 3D printed Ti6Al4V bone scaffolds with different pore structure effects on bone ingrowth[J]. J Biol Eng, 2021, 15 (1): 4.
doi: 10.1186/s13036-021-00255-8
6 Sumner DR . Long-term implant fixation and stress-shielding in total hip replacement[J]. J Biomech, 2015, 48 (5): 797- 800.
doi: 10.1016/j.jbiomech.2014.12.021
7 Karunakaran R , Ortgies S , Tamayol A , et al. Additive manufacturing of magnesium alloys[J]. Bioact Mater, 2020, 5 (1): 44- 54.
8 Zhang J , Jiang Y , Shang Z , et al. Biodegradable metals for bone defect repair: A systematic review and meta-analysis based on animal studies[J]. Bioact Mater, 2021, 6 (11): 4027- 4052.
9 Witte F , Hort N , Vogt C , et al. Degradable biomaterials based on magnesium corrosion[J]. Curr Opin Solid State Mater Sci, 2008, 12 (5/6): 63- 72.
10 Saris NE , Mervaala E , Karppanen H , et al. Magnesium. An update on physiological, clinical and analytical aspects[J]. Clin Chim Acta, 2000, 294 (1/2): 1- 26.
11 Janning C , Willbold E , Vogt C , et al. Magnesium hydroxide temporarily enhancing osteoblast activity and decreasing the osteoclast number in peri-implant bone remodelling[J]. Acta Biomater, 2010, 6 (5): 1861- 1868.
doi: 10.1016/j.actbio.2009.12.037
12 Zhang X , Chen Q , Mao X . Magnesium enhances osteogenesis of BMSCs by tuning osteoimmunomodulation[J]. Biomed Res Int, 2019, 2019, 7908205.
13 Leem YH , Lee KS , Kim JH , et al. Magnesium ions facilitate integrin alpha 2- and alpha 3-mediated proliferation and enhance alkaline phosphatase expression and activity in hBMSCs[J]. J Tissue Eng Regen Med, 2016, 10 (10): E527- E536.
doi: 10.1002/term.1861
14 Chen K , Xie X , Tang H , et al. In vitro and in vivo degradation behavior of Mg-2Sr-Ca and Mg-2Sr-Zn alloys[J]. Bioact Mater, 2020, 5 (2): 275- 285.
15 Xia D , Liu Y , Wang S , et al. In vitro and in vivo investigation on biodegradable Mg-Li-Ca alloys for bone implant application[J]. Sci China Mater, 2018, 62 (2): 256- 272.
16 Li Z , Gu X , Lou S , et al. The development of binary Mg-Ca alloys for use as biodegradable materials within bone[J]. Biomaterials, 2008, 29 (10): 1329- 1344.
17 He LY , Zhang XM , Liu B , et al. Effect of magnesium ion on human osteoblast activity[J]. Braz J Med Biol Res, 2016, 49 (7): e5257.
18 International Organization for Standardization. Biological evaluation of medical devices. Part 12: Sample preparation and reference materials: ISO 10993-12: 2021[S]. Switzerland: Vernier, 2021: 01.
19 Morgan EF , Unnikrisnan GU , Hussein AI . Bone mechanical pro-perties in healthy and diseased states[J]. Annu Rev Biomed Eng, 2018, 20, 119- 143.
20 Cuppone M , Seedhom BB , Berry E , et al. The longitudinal Young's modulus of cortical bone in the midshaft of human femur and its correlation with CT scanning data[J]. Calcif Tissue Int, 2004, 74 (3): 302- 309.
21 Lu WC , Pringa E , Chou L . Effect of magnesium on the osteogenesis of normal human osteoblasts[J]. Magnes Res, 2017, 30 (2): 42- 52.
22 Zheng YF , Gu XN , Witte F . Biodegradable metals[J]. Mater Sci Eng R Rep, 2014, 77, 1- 34.
23 Gu XN , Xie XH , Li N , et al. In vitro and in vivo studies on a Mg-Sr binary alloy system developed as a new kind of biodegradable metal[J]. Acta Biomater, 2012, 8 (6): 2360- 2374.
24 von der Höh N , von Rechenberg B , Bormann D , et al. Influence of different surface machining treatments of resorbable magnesium alloy implants on degradation-EDX-analysis and histology results[J]. Materwiss Werksttech, 2009, 40 (1/2): 88- 93.
25 Witte F , Fischer J , Nellesen J , et al. In vitro and in vivo corrosion measurements of magnesium alloys[J]. Biomaterials, 2006, 27 (7): 1013- 1018.
26 Feyerabend F , Fischer J , Holtz J , et al. Evaluation of short-term effects of rare earth and other elements used in magnesium alloys on primary cells and cell lines[J]. Acta Biomater, 2010, 6 (5): 1834- 1842.
27 Li F , Gong A , Qiu L , et al. Simultaneous determination of trace rare-earth elements in simulated water samples using ICP-OES with TODGA extraction/back-extraction[J]. PLoS One, 2017, 12 (9): e0185302.
28 Angrisani N , Reifenrath J , Zimmermann F , et al. Biocompatibility and degradation of LAE442-based magnesium alloys after implantation of up to 3.5 years in a rabbit model[J]. Acta Biomater, 2016, 44, 355- 365.
[1] Xinxin ZHAN,Lulu CAO,Dong XIANG,Hao TANG,Dandan XIA,Hong LIN. Effect of printing orientation on physical and mechanical properties of 3D printing prosthodontic base resin materials [J]. Journal of Peking University (Health Sciences), 2024, 56(2): 345-351.
[2] ABUDUREHEMAN Kaidierya,Rong-geng ZHANG,Hao-nan QIAN,Zhen-yang ZOU,YESITAO Danniya,Tian-yuan FAN. Preparation and in vitro evaluation of FDM 3D printed theophylline tablets with personalized dosage [J]. Journal of Peking University (Health Sciences), 2022, 54(6): 1202-1207.
[3] SUN Yu-chun,GUO Yu-qing,CHEN Hu,DENG Ke-hui,LI Wei-wei. Independent innovation research, development and transformation of precise bionic repair technology for oral prosthesis [J]. Journal of Peking University (Health Sciences), 2022, 54(1): 7-12.
[4] WANG Jing-qi,WANG Xiao. In vivo study of strontium-doped calcium phosphate cement for biological properties [J]. Journal of Peking University (Health Sciences), 2021, 53(2): 378-383.
[5] Fei LI,Jing QIAO,Jin-yu DUAN,Yong ZHANG,Xiu-jing WANG. Effect of concentrated growth factors combined with guided tissue regeneration in treatment of classⅡ furcation involvements of mandibular molars [J]. Journal of Peking University (Health Sciences), 2020, 52(2): 346-352.
[6] Chang CAO,Fei WANG,En-bo WANG,Yu LIU. Application of β-TCP for bone defect restore after the mandibular third molars extraction: A split-mouth clinical trial [J]. Journal of Peking University(Health Sciences), 2020, 52(1): 97-102.
[7] Wei-ting LI,Peng LI,Mu-zi PIAO,Fang ZHANG,Jie DI. Study on bone volume harvested from the implant sites with different methods [J]. Journal of Peking University(Health Sciences), 2020, 52(1): 103-106.
[8] Hao WANG,Yang LIU,Hao-chen LIU,Dong HAN,Hai-lan FENG. Detection and functional analysis of BMP2 gene mutation in patients with tooth agenesis [J]. Journal of Peking University(Health Sciences), 2019, 51(1): 9-15.
[9] ZHANG Da, WANG Lin-chuan, ZHOU Yan-heng, LIU Xiao-mo, LI Jing. Precision of three-dimensional printed brackets#br# [J]. Journal of Peking University(Health Sciences), 2017, 49(4): 704-708.
[10] QIAO Jing, DUAN Jin-yu, CHU Yi, SUN Chang-zhou. Effect of concentrated growth factors on the treatment of degree Ⅱ furcation involvements of  mandibular molars [J]. Journal of Peking University(Health Sciences), 2017, 49(1): 36-042.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Copyright © Journal of Peking University (Health Sciences), All Rights Reserved.
Powered by Beijing Magtech Co. Ltd