Melt electrowriting of PLA, PCL, and composite PLA/PCL scaffolds for tissue engineering application

Melt electrowriting of PLA, PCL, and composite PLA/PCL scaffolds for tissue engineering application

Fabrication of well-ordered and bio-mimetic scaffolds is one of the most important research lines in tissue engineering. Different techniques have been utilized to achieve this goal, however, each method has its own disadvantages. Recently, melt electrowriting (MEW) as a technique for fabrication of...

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Veröffentlicht in:Scientific reports 2022-11, Vol.12 (1), p.19935-16, Article 19935
Hauptverfasser: Shahverdi, Mohammad, Seifi, Saeed, Akbari, Ali, Mohammadi, Kaivan, Shamloo, Amir, Movahhedy, Mohammad Reza
Format: Artikel
Sprache:eng
Schlagworte:
631/1647
639/166
Animals
Anisotropy
Bone and Bones
Cell viability
Elastic Modulus
Fabrication
Fibers
Humanities and Social Sciences
Humans
Hydrophobicity
Mechanical properties
Mice
multidisciplinary
Polycaprolactone
Polyesters - chemistry
Polymers
Science
Science (multidisciplinary)
Tensile stress
Tissue engineering
Tissue Engineering - methods
Tissue Scaffolds - chemistry
Umbilical vein
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Zusammenfassung:Fabrication of well-ordered and bio-mimetic scaffolds is one of the most important research lines in tissue engineering. Different techniques have been utilized to achieve this goal, however, each method has its own disadvantages. Recently, melt electrowriting (MEW) as a technique for fabrication of well-organized scaffolds has attracted the researchers’ attention due to simultaneous use of principles of additive manufacturing and electrohydrodynamic phenomena. In previous research studies, polycaprolactone (PCL) has been mostly used in MEW process. PCL is a biocompatible polymer with characteristics that make it easy to fabricate well-arranged structures using MEW device. However, the mechanical properties of PCL are not favorable for applications like bone tissue engineering. Furthermore, it is of vital importance to demonstrate the capability of MEW technique for processing a broad range of polymers. To address aforementioned problems, in this study, three ten-layered box-structured well-ordered scaffolds, including neat PLA, neat PCL, and PLA/PCL composite are fabricated using an MEW device. Printing of the composite PLA/PCL scaffold using the MEW device is conducted in this study for the first time. The MEW device used in this study is a commercial fused deposition modeling (FDM) 3D printer which with some changes in its setup and configuration becomes prepared for being used as an MEW device. Since in most of previous studies, a setup has been designed and built for MEW process, the use of the FDM device can be considered as one of the novelties of this research. The printing parameters are adjusted in a way that scaffolds with nearly equal pore sizes in the range of 140 µm to 150 µm are fabricated. However, PCL fibers are mostly narrower (diameters in the range of 5 µm to 15 µm) than PLA fibers with diameters between 15 and 25 µm. Unlike the MEW process of PCL, accurate positioning of PLA fibers is difficult which can be due to higher viscosity of PLA melt compared to PCL melt. The printed composite PLA/PCL scaffold possesses a well-ordered box structure with improved mechanical properties and cell-scaffold interactions compared to both neat PLA and PCL scaffolds. Besides, the composite scaffold exhibits a higher swelling ratio than the neat PCL scaffold which can be related to the presence of less hydrophobic PLA fibers. This scaffold demonstrates an anisotropic behavior during uniaxial tensile test in which its Young’s modulus, ultimate tensile st
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-022-24275-6