Sage Journals: Discover world-class research

Abstract

In recent years, tissue engineering (TE) has received more and more attention from scientific and research communities. One of the main requirements of this new approach is the fabrication of biocompatible and biodegradable scaffolds with required geometrical and mechanical properties. In TE, highly porous scaffold structures are required to provide a temporary mechanical support, to accommodate and guide the proliferation, regeneration, and growth of cells in three dimensions. This article presents an investigation on designing and fabricating possible scaffolds of a different internal structure with desired porosity and surface-area-to-volume ratio for TE applications by using the Creo Parametric computer-aided design system and the fused deposition modeling (FDM) three-dimensional printing technique. Scaffolds of various cell geometry structures are designed, and a simple FDM-type 3D printer is used to fabricate such scaffolds in biodegradable and biocompatible polylactic acid thermoplastics to verify the proposed approach. Finite element analysis and compression testing have been carried out to evaluate and analyze the mechanical strength of the proposed scaffolds.

Get full access to this article

View all access options for this article.

References

Murugan

, Ramakrishna

. Design strategies of tissue engineering scaffolds with controlled fiber orientation. Tissue Eng, 2007; 13:1845–1866.

Rezwan

, Chen

, Blaker

, et al. Biodegradable and bioactive porous polymer/inorganic composite scaffolds for bone tissue engineering. Biomaterials, 2006; 27:3413–3431.

Vacanti

. Tissue engineering and regenerative medicine: from first principles to state of the art. J Pediatr Surg, 2010; 45:291–294.

Podshivalov

, Gomes

, Zocca

, et al. Design, analysis and additive manufacturing of porous structures for biocompatible micro-scale scaffolds. Procedia CIRP, 2013; 5:247–252.

Almeida

, Bártolo

, Ferreira

. Mechanical behaviour and vascularisation analysis of tissue engineering scaffolds. In: Proceedings of the 3rd International Conference on Advanced Research in Virtual and Rapid Prototyping: Virtual and Rapid Manufacturing. Leiria, Portugal: Advanced Research Virtual and Rapid Prototyping. 2007.

Pooyan

, Tannenbaum

, Garmestani

. Mechanical behavior of a cellulose-reinforced scaffold in vascular tissue engineering. J Mech Behav Biomed Mater, 2012; 7:50–59.

Chua

, Leong

, Cheah

, et al. Development of a tissue engineering scaffold structure library for rapid prototyping. Part 1: Investigation and Classification. Int J Adv Manuf Technol, 2003; 21:291–301.

Zein

, Dietmar

, Kim

, et al. Fused deposition modelling of novel scaffold architectures for tissue engineering applications. Biomaterials, 2002; 23:1169–1185.

Hoque

, Meng

TTH

, Chuan

, et al. Fabrication and characterization of hybrid PCL/PEG 3D scaffolds for potential tissue engineering applications. Mater Lett, 2014; 131:255–258.

10.

Chen

, Lee

, Shyu

VBH

, et al. Surface modification of polycaprolactone scaffolds fabricated via selective laser sintering for cartilage tissue engineering. Mater Sci Eng C, 2014; 40:389–397.

11.

Serra

, Ortiz-Hernandez

, Engel

, et al. Relevance of PEG in PLA-based blends for tissue engineering 3D-printed scaffolds. Mater Sci Eng C, 2014; 38:55–62.

12.

Masood

, Alamara

. Development of scaffold building units and assembly for tissue engineering using fused deposition modelling. In International Conference on Advances in Materials and Processing Technologies, AMPT 2008. Manama, 2010; 269–274.

13.

Masood

, Singh

, Morsi

. The design and manufacturing of porous scaffolds for tissue engineering using rapid prototyping. Int J Adv Manuf Technol, 2005; 27:415–420.

14.

Leong

, Cheah

, Chua

. Solid freeform fabrication of three-dimensional scaffolds for engineering replacement tissues and organs. Biomaterials, 2003; 24:2363–2378.

15.

Hutmacher

. Scaffold design and fabrication technologies for engineering tissues—State of the art and future perspectives. J Biomater Sci Polym Ed, 2001; 12:107–124.

16.

Chantarapanich

, Puttawibul

, Sucharitpwatskul

, et al. Scaffold library for tissue engineering: A geometric evaluation. Comput Math Methods Med, 2012; 2012:407805.

17.

Naing

, Chua

, Leong

, et al. Fabrication of customised scaffolds using computer-aided design and rapid prototyping techniques. Rapid Prototyp J, 2005; 11:249–259.

18.

Armillotta

, Pelzer

. Modeling of porous structures for rapid prototyping of tissue engineering scaffolds. Int J Adv Manuf Technol, 2008; 39:501–511.

19.

Liulan

, Qingxi

, Xianxu

, et al. Design and fabrication of bone tissue engineering scaffolds via rapid prototyping and CAD. J Rare Earths, 2007; 25(Suppl. 2):379–383.

20.

Lipowiecki

, Brabazon

. Design of bone scaffolds structures for rapid prototyping with increased strength and osteoconductivity. In International Conference on Advances in Materials and Processing Technologies, AMPT 2008. Manama, 2010; 914–922.

21.

Craddock

, Brackett

, Wildman

, et al. The design of impact absorbing structures for additive manufacture. J Phys Confer Ser, 2012; 382:12042–12049.

22.

O'Brien

. Biomaterials & scaffolds for tissue engineering. Mater Today, 2011; 14:88–95.

23.

Dhandayuthapani

, Yoshida

, Maekawa

, Kumar

. Polymeric scaffolds in tissue engineering application: A review. Int J Polym Sci, 2011; 2011:Article ID 290602, 19 pages.

24.

Vasita

, Katti

. Nanofibers and their applications in tissue engineering. Int J Nanomed, 2006; 1:15–30.

25.

Peter

, Choi

. Biodegradable polymer scaffolds with well-defined interconnected spherical pore network. Tissue Eng, 2001; 7:23–33.

26.

Brahatheeswaran

, Yasuhiko

, Toru

, et al. Polymeric scaffolds in tissue engineering application: A review. Int J Polym Sci, 2011; 2011:19.

27.

Ashby

. The properties of foams and lattices. Philos Trans R Soc A, 2006; 364:15–30.

Design and Development of Scaffolds for Tissue Engineering Using Three-Dimensional Printing for Bio-Based Applications

Abstract

Abstract

Get full access to this article

References