3D Plotting of Calcium Phosphate Cement and Melt Electrowriting of Polycaprolactone Microfibers in One Scaffold: A Hybrid Additive Manufacturing Process

Kilian, David; Witzleben, Max von; Lanaro, Matthew; Wong, Cynthia S.; Vater, Corina; Lode, Anja; Allenby, Mark C.; Woodruff, Maria A.; Gelinsky, Michael

doi:10.3390/jfb13020075

Cited by 11 publications

(11 citation statements)

References 76 publications

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“…The MEW fibers provided additional structural integrity and generally improved the infiltration of cells within the larger pores of the CP structure, providing an increased density of anchor points for cell attachment and stimulating rapid cell proliferation whilst only minimally impacting overall scaffold porosity (Figure 4A). [134] Staples et al (2022) utilized a gradient of pore sizes to mimic the periodontal ligament and bone respectively, and demonstrated precision control over cellular alignment using parallel fibers spaced 100 μm apart compared to the random orientation of cells on larger pore scaffolds (Figure 4B). [135] Ye et al (2020) vastly improved the cell seeding efficiency and structural integrity of MEW scaffolds by electrospinning a gelatin methacrylate (GelMA) hydrogel fiber membrane to create a multi-layer composite construct (Figure 4C).…”

Section: Auxetic Triangular and Multiphasic Architecturesmentioning

confidence: 99%

Materials Design Innovations in Optimizing Cellular Behavior on Melt Electrowritten (MEW) Scaffolds

Devlin,

Allenby,

Ren

et al. 2024

Adv Funct Materials

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The field of melt electrowriting (MEW) has seen significant progress, bringing innovative advancements to the fabrication of biomaterial scaffolds, and creating new possibilities for applications in tissue engineering and beyond. Multidisciplinary collaboration across materials science, computational modeling, AI, bioprinting, microfluidics, and dynamic culture systems offers promising new opportunities to gain deeper insights into complex biological systems. As the focus shifts towards personalized medicine and reduced reliance on animal models, the multidisciplinary approach becomes indispensable. This review provides a concise overview of current strategies and innovations in controlling and optimizing cellular responses to MEW scaffolds, highlighting the potential of scaffold material, MEW architecture, and computational modeling tools to accelerate the development of efficient biomimetic systems. Innovations in material science and the incorporation of biologics into MEW scaffolds have shown great potential in adding biomimetic complexity to engineered biological systems. These techniques pave the way for exciting possibilities for tissue modeling and regeneration, personalized drug screening, and cell therapies.

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Section: Auxetic Triangular and Multiphasic Architecturesmentioning

confidence: 99%

Materials Design Innovations in Optimizing Cellular Behavior on Melt Electrowritten (MEW) Scaffolds

Devlin,

Allenby,

Ren

et al. 2024

Adv Funct Materials

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“…This technique is mainly used to extrude solid or slurry materials in 2D planes according to a specific scanning path and form a planar structure with pore morphology. It is followed by superimposing multiple planar structures with a certain thickness in the Z axis sequentially to finally build pore structures of porous materials ( Cubo-Mateo and Rodriguez-Lorenzo, 2020 ; Sakthiabirami et al, 2021 ; Yang et al, 2021 ; Kilian et al, 2022 ). Considering this molding technology’s characteristics, the prepared material’s structure in the 2D plane can be controlled.…”

Section: Definition Of Pore Structure Dimensionmentioning

confidence: 99%

“…Therefore, the literature continues to use pore size as a specific parameter to define the pore structure dimension, defining it as the spacing of two parallel rods in a 2D plane ( Shanjani et al, 2017 ; Gupta et al, 2021 ). However, some literature ignores the rod diameter size and uses the scan spacing directly as the pore size ( Kilian et al, 2022 ). Nevertheless, according to the original definition of pore size and pore throat size, such parameters should be defined as the pore throat size in the 2D plane, not pore size in 3D space.…”

Section: Definition Of Pore Structure Dimensionmentioning

confidence: 99%

“…Currently, the pore structure design used for bioengineered porous bone tissue materials mainly includes two approaches: regular and irregular pore structures. In this line, there are two main technical solutions to constructing a regular pore structure: through the regular arrangement of rod structures in 2D planes and through the superposition of 2D planes in the Z axis ( Cubo-Mateo and Rodriguez-Lorenzo, 2020 ; Sakthiabirami et al, 2021 ; Kilian et al, 2022 ). On the other hand, rod structures form the unit cells in 3D spaces through angular connections, and then the whole structure is formed by stacking the unit cells in the X/Y/ Z axes ( Li et al, 2018a ; Li et al, 2018b ).…”

Section: Introductionmentioning

confidence: 99%

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Definition, measurement, and function of pore structure dimensions of bioengineered porous bone tissue materials based on additive manufacturing: A review

Wen

Liu

Wang

2023

Front. Bioeng. Biotechnol.

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Bioengineered porous bone tissue materials based on additive manufacturing technology have gradually become a research hotspot in bone tissue-related bioengineering. Research on structural design, preparation and processing processes, and performance optimization has been carried out for this material, and further industrial translation and clinical applications have been implemented. However, based on previous studies, there is controversy in the academic community about characterizing the pore structure dimensions of porous materials, with problems in the definition logic and measurement method for specific parameters. In addition, there are significant differences in the specific morphological and functional concepts for the pore structure due to differences in defining the dimensional characterization parameters of the pore structure, leading to some conflicts in perceptions and discussions among researchers. To further clarify the definitions, measurements, and dimensional parameters of porous structures in bioengineered bone materials, this literature review analyzes different dimensional characterization parameters of pore structures of porous materials to provide a theoretical basis for unified definitions and the standardized use of parameters.

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“…Recently, a multi-technological approach allowed for the simultaneous combination of calcium phosphate cement (CPC) printing with MEW of polycaprolactone (PCL) microfibers in an alternating, tuneable design in one automated fabrication process [ 15 ]. The hybrid CPC+PCL scaffolds featured a strong interface and the microfiber integration led to an improvement in integrity.…”

Section: Introductionmentioning

confidence: 99%

Generation of Controlled Micrometric Fibers inside Printed Scaffolds Using Standard FDM 3D Printers

et al. 2022

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New additive manufacturing techniques, such as melting electro-writing (MEW) or near-field electrospinning (NFES), are now used to include microfibers inside 3D printed scaffolds as FDM printers present a limited resolution in the XY axis, not making it easy to go under 100 µm without dealing with nozzle troubles. This work studies the possibility of creating reproducible microscopic internal fibers inside scaffolds printed by standard 3D printing. For this purpose, novel algorithms generating deposition routines (G-code) based on primitive geometrical figures were created by python scripts, modifying basic deposition conditions such as temperature, speed, or material flow. To evaluate the influence of these printing conditions on the creation of internal patterns at the microscopic level, an optical analysis of the printed scaffolds was carried out using a digital microscope and subsequent image analysis with ImageJ software. To conclude, the formation of heterogeneously shaped microfilaments (48 ± 12 µm, mean ± S.D.) was achieved in a standard FDM 3D Printer with the strategies developed in this work, and it was found that the optimum conditions for obtaining such microfibers were high speeds and a reduced extrusion multiplier.

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3D Plotting of Calcium Phosphate Cement and Melt Electrowriting of Polycaprolactone Microfibers in One Scaffold: A Hybrid Additive Manufacturing Process

Cited by 11 publications

References 76 publications

Materials Design Innovations in Optimizing Cellular Behavior on Melt Electrowritten (MEW) Scaffolds

Materials Design Innovations in Optimizing Cellular Behavior on Melt Electrowritten (MEW) Scaffolds

Definition, measurement, and function of pore structure dimensions of bioengineered porous bone tissue materials based on additive manufacturing: A review

Generation of Controlled Micrometric Fibers inside Printed Scaffolds Using Standard FDM 3D Printers

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