Top

Journal of Orthopaedic Surgery and Research

Published in:

Open Access 01-12-2019 | Research article

Biomechanical analysis of a novel height-adjustable nano-hydroxyapatite/polyamide-66 vertebral body: a finite element study

Authors: Guanghui Chen, Baoquan Xin, Mengchen Yin, Tianqi Fan, Jing Wang, Ting Wang, Guangjian Bai, Jianru Xiao, Tielong Liu

Published in: Journal of Orthopaedic Surgery and Research | Issue 1/2019

Abstract

Background

To compare the biomechanical properties of a novel height-adjustable nano-hydroxyapatite/polyamide-66 vertebral body (HAVB) with the titanium mesh cage (TMC) and artificial vertebral body (AVB), and evaluate its biomechanical efficacy in spinal stability reconstruction.

Methods

A 3D nonliner FE model of the intact L1-sacrum was established and validated. Three FE models which instrumented HAVB, TMC, and AVB were constructed for surgical simulation. A pure moment of 7.5 Nm and a 400-N preload were applied to the three FE models in 3D motion. The peak von Mises stress upon each prosthesis and the interfaced endplate was recorded for analysis. In addition, the overall and intersegmental range of motion (ROM) of each model was investigated to assess the efficacy of each model in spinal stability reconstruction.

Results

AVB had the greatest stress concentration compared with TMC and HAVB in all motions (25.6–101.8 times of HAVB, 0.8–8.1 times of TMC). The peak stress on HAVB was 3.1–10.3% of TMC and 1.6–3.9% of AVB. The maximum stress values on L2 caudal and L4 cranial endplates are different between the three FE models: 0.9–1.9, 1.3–12.1, and 31.3–117.9 times of the intact model on L2 caudal endplates and 0.9–3.5, 7.2–31.5, and 10.3–56.4 times of the intact model on L4 cranial endplates in HAVB, TMC, and AVB, respectively, while the overall and segmental ROM reduction was similar between the three models, with AVB providing a relatively higher ROM reduction in all loading conditions (88.1–84.7% of intact model for overall ROM and 69.5–82.1% for L1/2, 87.0–91.7% for L2/4, and 71.1–87.2% for L4/5, respectively).

Conclusions

HAVB had similar biomechanical efficacy in spinal stability reconstruction as compared with TMC and AVB. The material used and the anatomic design of HAVB can help avoid stress concentration and the stress shielding effect, thus greatly reducing the implant-associated complications. HAVB exhibited some advantageous biomechanical properties over TMC and AVB and may prove to be a potentially viable option for spinal stability reconstruction. Further in vivo and vitro studies are still required to validate our findings and conclusions.

Available only for authorised users

Arts MP, Peul WC. Vertebral body replacement systems with expandable cages in the treatment of various spinal pathologies: a prospectively followed case series of 60 patients. Neurosurgery. 2008;63(3):537–45.CrossRef

Alleyne JC, Rodts JG, Haid RW. Corpectomy and stabilization with methylmethacrylate in patients with metastatic disease of the spine: a technical note. J Spinal Disord. 1995;8(6):439–43.CrossRef

Robinson Y, Tschoeke SK, Kayser R, Boehm H, Heyde CE. Reconstruction of large defects in vertebral osteomyelitis with expandable titanium cages. Int Orthop. 2009;33(3):745–9.CrossRef

Duan P-G, Li R-Y, Jiang Y-Q, Wang H-r, Zhou X-G, Li X-L, et al. Recurrent adamantinoma in the thoracolumbar spine successfully treated by three-level total en bloc spondylectomy by a single posterior approach. Eur Spine J. 2015;24(4):514–21.CrossRef

Thongtrangan I, Balabhadra RS, Le H, Park J, Kim DH. Vertebral body replacement with an expandable cage for reconstruction after spinal tumor resection. Neurosurg Focus. 2003;15(5):E8.CrossRef

Lau D, Song Y, Guan Z, La Marca F, Park P. Radiological outcomes of static vs expandable titanium cages after corpectomy: a retrospective cohort analysis of subsidence. Neurosurgery. 2012;72(4):529–39.CrossRef

Khandan A, Ozada N. Bredigite-magnetite (Ca7MgSi4O16-Fe3O4) nanoparticles: a study on their magnetic properties. J Alloys Compd. 2017;726:729–36.CrossRef

Khandan A, Ozada N, Saber-Samandari S, Ghadiri NM. On the mechanical and biological properties of bredigite-magnetite (Ca7MgSi4O16-Fe3O4) nanocomposite scaffolds. Ceram Int. 2018;44(3):3141–8.CrossRef

Kordjamshidi A, Saber-Samandari S, Ghadiri Nejad M, Khandan A. Preparation of novel porous calcium silicate scaffold loaded by celecoxib drug using freeze drying technique: fabrication, characterization and simulation. Ceram Int. 2019;45(11):14126–35.CrossRef

10.

Dvorak MF, Kwon BK, Fisher CG, Eiserloh HL III, Boyd M, Wing PC. Effectiveness of titanium mesh cylindrical cages in anterior column reconstruction after thoracic and lumbar vertebral body resection. Spine. 2003;28(9):902–8.PubMed

11.

Jacobs WC, Vreeling A, De Kleuver M. Fusion for low-grade adult isthmic spondylolisthesis: a systematic review of the literature. Eur Spine J. 2006;15(4):391–402.CrossRef

12.

Cardenas RJ, Javalkar V, Patil S, Gonzalez-Cruz J, Ogden A, Mukherjee D, et al. Comparison of allograft bone and titanium cages for vertebral body replacement in the thoracolumbar spine: a biomechanical study. Operative Neurosurgery. 2010;66(suppl_2):ons314–ons8.CrossRef

13.

Shen FH, Marks I, Shaffrey C, Ouellet J, Arlet V. The use of an expandable cage for corpectomy reconstruction of vertebral body tumors through a posterior extracavitary approach: a multicenter consecutive case series of prospectively followed patients. Spine J. 2008;8(2):329–39.CrossRef

14.

Wang S-J, Liu X-M, Zhao W-D, Wu D-S. Titanium mesh cage fracture after lumbar reconstruction surgery: a case report and literature review. Int J Clin Exp Med. 2015;8(4):5559.PubMedPubMedCentral

15.

Chou D, Lu DC, Weinstein P, Ames CP. Adjacent-level vertebral body fractures after expandable cage reconstruction. J Neurosurg Spine. 2008;8(6):584–8.CrossRef

16.

Pflugmacher R, Schleicher P, Schaefer J, Scholz M, Ludwig K, Khodadadyan-Klostermann C, et al. Biomechanical comparison of expandable cages for vertebral body replacement in the thoracolumbar spine. Spine. 2004;29(13):1413–9.CrossRef

17.

Rohlmann A, Zander T, Fehrmann M, Klockner C, Bergmann G. Influence of implants for vertebral body replacement on the mechanical behavior of the lumbar spine. Orthopade. 2002;31(5):503–7.CrossRef

18.

Kazemi A, Abdellahi M, Khajeh-Sharafabadi A, Khandan A, Ozada N. Study of in vitro bioactivity and mechanical properties of diopside nano-bioceramic synthesized by a facile method using eggshell as raw material. Mater Sci Eng C. 2017;71:604.CrossRef

19.

Sharafabadi AK, Abdellahi M, Kazemi A, Khandan A, Ozada N. A novel and economical route for synthesizing akermanite (Ca2MgSi2O7) nano-bioceramic. Mater Sci Eng C. 2017;71:1072–8.CrossRef

20.

Shamoradi F, Emadi R, Ghomi H. Fabrication of monticellite-akermanite nanocomposite powder for tissue engineering applications. J Alloys Compd. 2017;693:601–05.CrossRef

21.

Montazeran AH, Saber-Samandari S, Khandan A. Artificial intelligence investigation of three silicates bioceramicsmagnetite bio-nanocompositeHyperthermia and biomedical applications. Int J Nanomedicine. 2018;5(3):163–71.

22.

Du C, Cui FZ, Feng QL, Zhu XD, Groot K, De. Tissue response to nano-hydroxyapatite/collagen composite implants in marrow cavity. J Biomed Mater Res Part B Appl Biomater 1999;42(4):540–548.CrossRef

23.

Zhang R, ., Ma PX. Porous poly(L-lactic acid)/apatite composites created by biomimetic process. J Biomed Mater Res 2015;45(4):285–293.CrossRef

24.

Bonfield W, Grynpas MD, Tully AE, Bowman J, Abram J. Hydroxyapatite reinforced polyethylene — a mechanically compatible implant material for bone replacement. Biomaterials. 1981;2(3):185–6.CrossRef

25.

Du C, Meijer GJ, Valk CVD, Haan RE, Bezemer JM, Hesseling SC, et al. Bone growth in biomimetic apatite coated porous Polyactive 1000PEGT70PBT30 implants. Biomaterials. 2002;23(23):4649–56.CrossRef

26.

Wei J, Li Y. Tissue engineering scaffold material of nano-apatite crystals and polyamide composite. Eur Polym J. 2004;40(3):509–15.CrossRef

27.

Xu Q, Lu H, Zhang J, Lu G, Deng Z, Mo A. Tissue engineering scaffold material of porous nanohydroxyapatite/polyamide 66. Int J Nanomedicine. 2010;5:331–5.PubMedPubMedCentral

28.

Zhang Y, Deng X, Jiang D, Luo X, Tang K, Zhao Z, et al. Long-term results of anterior cervical corpectomy and fusion with nano-hydroxyapatite/polyamide 66 strut for cervical spondylotic myelopathy. Sci Rep. 2016;6:26751.CrossRef

29.

Xiong Y, Ren C, Zhang B, Yang H, Lang Y, Min L, et al. Analyzing the behavior of a porous nano-hydroxyapatite/polyamide 66 (n-HA/PA66) composite for healing of bone defects. Int J Nanomedicine. 2014;9:485.CrossRef

30.

Chen G, Yin M, Liu W, Xin B, Bai G, Wang J, et al. A novel height-adjustable nano-hydroxyapatite/polyamide-66 vertebral body for reconstruction of thoracolumbar structural stability after spinal tumor resection. World Neurosurgery. 2018.

31.

Goto K, Tajima N, Chosa E, Totoribe K, Kubo S, Kuroki H, et al. Effects of lumbar spinal fusion on the other lumbar intervertebral levels (three-dimensional finite element analysis). J Orthop Sci. 2003;8(4):577–84.CrossRef

32.

Shim CS, Park SW, Lee S-H, Lim TJ, Chun K, Kim DH. Biomechanical evaluation of an interspinous stabilizing device. Locker Spine. 2008;33(22):E820–E7.CrossRef

33.

Kotani Y, Abumi K, Shikinami Y, Takada T, Kadoya K, Shimamoto N, et al. Artificial intervertebral disc replacement using bioactive three-dimensional fabric: design, development, and preliminary animal study. Spine. 2002;27(9):929–35.CrossRef

34.

Cappuccino A, Cornwall GB, Turner AW, Fogel GR, Duong HT, Kim KD, et al. Biomechanical analysis and review of lateral lumbar fusion constructs. Spine. 2010;35(26S):S361–S7.CrossRef

35.

Liu X, Ma J, Park P, Huang X, Xie N, Ye X. Biomechanical comparison of multilevel lateral interbody fusion with and without supplementary instrumentation: a three-dimensional finite element study. BMC Musculoskelet Disord. 2017;18(1):63.CrossRef

36.

Knop C, Lange U, Bastian L, Blauth M. Three-dimensional motion analysis with Synex. Eur Spine J. 2000;9(6):472–85.CrossRef

37.

Ghayour H, Abdellahi M, Nejad MG, Khandan A, Saber-Samandari S. Study of the effect of the Zn-2(+) content on the anisotropy and specific absorption rate of the cobalt ferrite: the application of Co1-xZnxFe2O4 ferrite for magnetic hyperthermia. J Aust Ceram Soc. 2018;54(2):223–30.CrossRef

Title: Biomechanical analysis of a novel height-adjustable nano-hydroxyapatite/polyamide-66 vertebral body: a finite element study
Authors: Guanghui Chen
Baoquan Xin
Mengchen Yin
Tianqi Fan
Jing Wang
Ting Wang
Guangjian Bai
Jianru Xiao
Tielong Liu
Publication date: 01-12-2019
Publisher: BioMed Central
Published in: Journal of Orthopaedic Surgery and Research / Issue 1/2019
Electronic ISSN: 1749-799X
DOI: https://doi.org/10.1186/s13018-019-1432-2

At a glance: The STEP trials

Springer Medicine

Biomechanical analysis of a novel height-adjustable nano-hydroxyapatite/polyamide-66 vertebral body: a finite element study

Abstract

Background

Methods

Results

Conclusions

At a glance: The STEP trials

Springer Medicine

Abstract

Background

Methods

Results

Conclusions

Please log in to get access to this content

Other articles of this Issue 1/2019

Evaluating the bioactivity of a hydroxyapatite-incorporated polyetheretherketone biocomposite

Patients with Modic type 2 change have a severe radiographic representation in the process of lumbar degeneration: a retrospective imaging study

Comparison of D-dimer with CRP and ESR for diagnosis of periprosthetic joint infection

A comparative study of the efficacy of ultrasonics and extracorporeal shock wave in the treatment of tennis elbow: a meta-analysis of randomized controlled trials

An enhanced recovery after surgery program in orthopedic surgery: a systematic review and meta-analysis

Comparing two dry needling interventions for plantar heel pain: a protocol for a randomized controlled trial