Sage Journals: Discover world-class research

Abstract

Mandible reconstruction stands as a significant area with an advancement technology associated with computer-aided manufacturing (CAM) techniques. These technologies have potential to overcome of lattice structures and enhance scaffold quality. Recently, Osteosynthesis methods have evolved, and influenced for biomaterial selection and manufacturing methodologies for light weight implants. This study investigates the mechanical strength of lattice structures namely diamond, kelvin, and gyroid fabricated using multi-material 3D-printing. The mechanical performance of 3D- printed lightweight lattice structures for mandibular defects were evaluated by experimental method. The design of experiments was developed by varying thickness of lattices and its types. These experimental design results on variation of porosity of lattice structures from 15 % to 70% and surface area to volume ratio from 1 to 17. The experimental study of multi-material lattices structures results high flexural strength compared with compressive and tensile. However, the adhesion breakage of lattices structures was observed in compression and tensile tests. The gyroid lattices structures with least thickness of 1.5 mm, porosity of higher porosity and surface area to volume ratio results optimum mechanical strength for scaffold applications. Tensile, compression, and flexural strengths of 15 MPa, 21 MPa, and 45 MPa were attained by the gyroid 1.5 mm lattice thickness specimen with porosities of 20%, 67%, and 50%, respectively. Finite element analysis using tensile, compression, and flexural modulus values revealed a 32% variation when compared with experimental results.

Keywords

Mandible lattice structures compression testing scaffolds porosity

Get full access to this article

View all access options for this article.

References

Tang

, et al. Current global research on mandibular defect: a bibliometric analysis from 2001 to 2021. Front Bioeng Biotechnol 2023; 11: 1061567.

Winarso

Ismail

Anggoro

, et al. A scoping review of the additive manufacturing of mandibular implants. Front Mech Eng 2023; 9: 1079887.

Mattavelli

Verzeletti

Deganello

, et al. Computer-aided designed 3D-printed polymeric scaffolds for personalized reconstruction of maxillary and mandibular defects: a proof-of-concept study. Eur Arch Otorhinolaryngol 2024; 281(3): 1493–1503.

Zhang

, et al. Mechanical properties and oral restoration applications of 3D printed aliphatic polyester-calcium composite materials. Alex Eng J 2024; 88: 245–252.

Hassan

Omar

Daskalakis

, et al. The potential of polyethylene terephthalate glycol as biomaterial for bone tissue engineering. Polymers 2020; 12: 3045.

Katschnig

Wallner

Janics

, et al. Biofunctional glycol-modified polyethylene terephthalate and thermoplastic polyurethane implants by extrusion-based additive manufacturing for medical 3D maxillofacial defect reconstruction. Polymers 2020; 12: 1751.

Kalaithendral

Karuppudaiyan

Roy

. Design and analysis of multi-material structures of 3D printed implants of mandible. Biomed Phys Eng Express 2023; 9: 065020.

Nazir

Gokcekaya

Md Masum Billah

, et al. Multi-material additive manufacturing: a systematic review of design, properties, applications, challenges, and 3D printing of materials and cellular metamaterials. Mater Des 2023; 226: 111661.

Hasanov

Alkunte

Rajeshirke

, et al. Review on additive manufacturing of multi-material parts: Progress and challenges. J Manuf Mater Process 2021; 6: 4.

10.

Wang

Huang

Zhou

, et al. 3D printing of bone tissue engineering scaffolds. Bioact Mater 2020; 5: 82–91.

11.

Hulme

Sakhaei

Shafiee

. Mechanical analysis and additive manufacturing of 3D-printed lattice materials for bone scaffolds. Mater Today Proc 2023; 101: 30–37.

12.

Abueidda

Elhebeary

Shiang

, et al. Mechanical properties of 3D printed polymeric gyroid cellular structures: experimental and finite element study. Mater Des 2019; 165: 107597.

13.

Saleh

Anwar

Al-Ahmari

, et al. Compression performance and failure analysis of 3D-printed carbon fiber/PLA composite TPMS lattice structures. Polymers 2022; 14: 4595.

14.

Ahmad

Belluomo

Bici

, et al. Bird’s eye view on lattice structures: design issues and applications for best practices in mechanical design. Metals 2023; 13: 1666.

15.

Guo

Takezawa

Honda

, et al. Finite element simulation of the compressive response of additively manufactured lattice structures with large diameters. Comput Mater Sci 2020; 175: 109610.

16.

Güzelce

. Biomechanical comparison of different framework materials in mandibular overdenture prosthesis supported with implants of different sizes: a finite element analysis. BMC Oral Health 2023; 23: 450.

17.

Anitua

Larrazabal Saez de Ibarra

Saracho Rotaeche

. Implant-supported prostheses in the edentulous mandible: biomechanical analysis of different implant configurations via finite element analysis. Dent J 2022; 11: 4.

18.

Cojocaru

Frunzaverde

Miclosina

, et al. The influence of the process parameters on the mechanical properties of PLA specimens produced by fused filament fabrication—A review. Polymers 2022; 14: 886.

19.

Hsueh

Lai

Wang

, et al. Effect of printing parameters on the thermal and mechanical properties of 3D-printed PLA and PETG, using fused deposition modeling. Polymers 2021; 13: 1758.

20.

Cui

Cheng

, et al. Quantifying the discrepancies in the geometric and mechanical properties of the theoretically designed and additively manufactured scaffolds. J Mech Behav Biomed Mater 2020; 112: 104080.

21.

Sokollu

Gulcan

Konukseven

. Mechanical properties comparison of strut-based and triply periodic minimal surface lattice structures produced by electron beam melting. Addit Manuf 2022; 60: 103199.

22.

Kalaithendral

Karuppudaiyan

Roy

. Design and evaluation of mechanical strength of multi-material polymeric implants for mandibular reconstruction. Int J Artif Organs 2024; 47: 698–706.

23.

Hernandez

Woodrow

. Medical applications of porous biomaterials: features of porosity and tissue-specific implications for biocompatibility. Adv Healthc Mater 2022; 11: 2102087.

24.

Algarni

Ghazali

. Comparative study of the sensitivity of PLA, ABS, PEEK, and PETG’s mechanical properties to FDM printing process parameters. Crystals 2021; 11: 995.

25.

Bouguermouh

Habibi

Laperrière

, et al. 4D-printed PLA-PETG polymer blends: comprehensive analysis of thermal, mechanical, and shape memory performances. J Mater Sci 2024; 59: 11596–11618.

26.

Kumaresan

Samykano

Kadirgama

, et al. Effects of printing parameters on the mechanical characteristics and mathematical modeling of FDM-printed PETG. Int J Adv Manuf Technol 2023; 128: 3471–3489.

27.

Gao

, et al. Study of material color influences on mechanical characteristics of fused deposition modeling parts. Materials 2022; 15: 7039.

28.

Sa'ude

Nabilah

. A study on the mechanical properties of PLA, ABS and PETG filament printed by various types of infill design using 3D printing machine. Res Prog Mech Manuf Eng 2023; 4: 162–167.

29.

Lyu

Gong

, et al. Study on the energy absorption performance of triply periodic minimal surface (TPMS) structures at different load-bearing angles. Biomimetics 2024; 9(7): 392.

Evaluating the lattice structures performance under mechanical loading for the application of mandible scaffolds: An experimental study

Abstract

Keywords

Get full access to this article

References