Sage Journals: Discover world-class research

Abstract

Melt electrowriting (MEW) is an aspiring 3D printing technology with an unprecedented resolution among fiber-based printing technologies. It offers the ability to direct-write predefined designs utilizing a jet of molten polymer to fabricate constructs composed of fibers with diameters of only a few micrometers. These dimensions enable unique construct properties. Poly(ɛ-caprolactone) (PCL), a semicrystalline polymer mainly used for biomedical and life science applications, is the most prominent material for MEW and exhibits excellent printing properties. Despite the wealth of melt electrowritten constructs that have been fabricated by MEW, a detailed investigation, especially regarding fiber analysis on a macro- and microlevel is still lacking. Hence, this study systematically examines the influence of process parameters such as spinneret diameter, feeding pressure, and collector velocity on the diameter and particularly the topography of PCL fibers and sheds light on how these parameters affect the mechanical properties and crystallinity. A correlation between the mechanical properties, crystallite size, and roughness of the deposited fiber, depending on the collector velocity and applied feeding pressure, is revealed. These findings are used to print constructs composed of fibers with different microtopography without affecting the fiber diameter and thus the macroscopic assembly of the printed constructs.

Get full access to this article

View all access options for this article.

References

Hutmacher

, Woodfield

TBF

, Dalton

. Chapter 10—Scaffold design and fabrication. In: C.A.V. Blitterswijk, J. De Boer (Eds.), Tissue Engineering. Oxford: Academic Press, 2014; pp.311–346.

Hutmacher

, Dalton

. Melt electrospinning. Chem Asian J, 2011; 6:44–56.

Dalton

, Farrugia

, Dargaville

, et al. Electrospinning and additive manufacturing: Converging technologies. Biomater Sci, 2013; 1:171–185.

Muerza-Cascante

, Haylock

, Hutmacher

, et al. Melt electrospinning and its technologization in tissue engineering. Tissue Eng Part B Rev, 2015; 21:187–202.

McMaster

, Hoefner

, Hrynevich A, et al. Tailored melt electrowritten scaffolds for the generation of sheet-like tissue constructs from multicellular spheroids. Adv Healthc Mater, 2019; 8:1801326.

Hrynevich

, Elci

, Haigh JN, et al. Dimension-based design of melt electrowritten scaffolds. Small, 2018; 14:1800232.

Youssef

, Hrynevich

, Fladeland L, et al. The impact of melt electrowritten scaffold design on porosity determined by X-ray micro-tomography. Tissue Eng Part C Methods, 2019; 25:367–379.

Visser

, Melchels

, Jeon JE, et al. Reinforcement of hydrogels using three-dimensionally printed microfibres. Nat Commun, 2015; 6:6933.

Farrugia

, Brown

, Upton

, et al. Dermal fibroblast infiltration of poly(epsilon-caprolactone) scaffolds fabricated by melt electrospinning in a direct writing mode. Biofabrication, 2013; 5:025001.

10.

Petcu

, Midha

, McColl

, et al. 3D printing strategies for peripheral nerve regeneration. Biofabrication, 2018; 10:032001.

11.

Castilho

, Feyen

, Flandes-Iparraguirre M, et al. Melt electrospinning writing of poly-hydroxymethylglycolide-co-epsilon-caprolactone-based scaffolds for cardiac tissue engineering. Adv Healthc Mater, 2017; 6. DOI: 10.1002/adhm.201700311.

12.

Jungst

, Pennings

, Schmitz

, et al. Heterotypic scaffold design orchestrates primary cell organization and phenotypes in cocultured small diameter vascular grafts. Adv Funct Mater, 2019; 29:1905987.

13.

Tylek

, Blum

, Hrynevich A, et al. Precisely defined fiber scaffolds with 40μm porosity induce elongation driven M2-like polarization of human macrophages. Biofabrication, 2020; 12:025007.

14.

Kalaskar

, Alshomer

. Chapter 8—Micro- and nanotopographical cues guiding biomaterial host response. In: S.J. Lee, J.J. Yoo, A. Atala (Eds.), In Situ Tissue Regeneration. Boston: Academic Press, 2016; pp. 137–163.

15.

Robinson

, Hutmacher

, Dalton

. The next Frontier in melt electrospinning: Taming the jet. Adv Funct Mater, 2019; 29:1904664.

16.

Gunatillake

, Adhikari

. Biodegradable synthetic polymers for tissue engineering. Eur Cell Mater, 2003; 5:1–16.

17.

Hochleitner

, Jungst

, Brown TD, et al. Additive manufacturing of scaffolds with sub-micron filaments via melt electrospinning writing. Biofabrication, 2015; 7:035002.

18.

Brown

, Dalton

, Hutmacher

. Direct writing by way of melt electrospinning. Adv Mater, 2011; 23:5651–5657.

19.

Ristovski

, Bock

, Liao S, et al. Improved fabrication of melt electrospun tissue engineering scaffolds using direct writing and advanced electric field control. Biointerphases, 2015; 10:011006.

20.

Hochleitner

, Youssef

, Hrynevich A, et al. Fibre pulsing during melt electrospinning writing. Bionanomaterials, 2016; 17:159–171.

21.

Zhmayev

, Cho

, Lak Joo

. Electrohydrodynamic quenching in polymer melt electrospinning. Phys Fluids, 2011; 23:073102.

22.

Esmaeilirad

, Ko

, Rukosuyev

, et al. The effect of nozzle-exit-channel shape on resultant fiber diameter in melt-electrospinning. Mater Res Express, 2017; 4:015302.

23.

Wei

, Dong

. Direct fabrication of high-resolution three-dimensional polymeric scaffolds using electrohydrodynamic hot jet plotting. J Micromech Microeng, 2013; 23:025017.

24.

Dayan

, Afghah

, Okan BS, et al. Modeling 3D melt electrospinning writing by response surface methodology. Mater Des, 2018; 148:87–95.

25.

Hochleitner

, Chen

, Blum

, et al. Melt electrowriting below the critical translation speed to fabricate crimped elastomer scaffolds with non-linear extension behaviour mimicking that of ligaments and tendons. Acta Biomater, 2018; 72:110–120.

26.

Magill

. Review spherulites: A personal perspective. J Mater Sci, 2001; 36:3143–3164.

27.

Harada

, Bates

, Lodge

. Transverse orientation of lamellae and cylinders by solution extrusion of a pentablock copolymer. Macromolecules, 2003; 36:5440–5442.

28.

, Lodge

, Bates

. Bridge to loop transition in a shear aligned lamellae forming heptablock copolymer. Macromolecules, 2004; 37:8184–8187.

29.

Taubenberger

, Hutmacher

, Muller

. Single-cell force spectroscopy, an emerging tool to quantify cell adhesion to biomaterials. Tissue Eng Part B Rev, 2014; 20:40–55.

30.

Szewczyk

, Ura

, Metwally S, et al. Roughness and fiber fraction dominated wetting of electrospun fiber-based porous meshes. Polymers, 2018; 11:34.

31.

Kubiak

, Wilson

MCT

, Mathia

, et al. Wettability versus roughness of engineering surfaces. Wear, 2011; 271:523–528.

32.

Metwally

, Ferraris

, Spriano S, et al. Surface potential and roughness controlled cell adhesion and collagen formation in electrospun PCL fibers for bone regeneration. Mater Des, 2020; 194:108915.

33.

Zamani

, Amani-Tehran

, Latifi

, et al. The influence of surface nanoroughness of electrospun PLGA nanofibrous scaffold on nerve cell adhesion and proliferation. J Mater Sci Mater Med, 2013; 24:1551–1560.

34.

Woodruff

, Hutmacher

. The return of a forgotten polymer—Polycaprolactone in the 21st century. Progr Polym Sci, 2010; 35:1217–1256.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

1.90 MB

Controlling Topography and Crystallinity of Melt Electrowritten Poly(ɛ-Caprolactone) Fibers

Abstract

Get full access to this article

References

Supplementary Material