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1. Fabrication of arbitrary three-dimensional suspended hollow microstructures in transparent fused silica glass

Author

Frederik Kotz, Patrick Risch, Karl Arnold, Semih Sevim, Josep Puigmartí-Luis, Alexander Quick, Michael Thiel, Andrei Hrynevich, Paul D. Dalton, Dorothea Helmer, and Bastian E. Rapp

Subjects
Science
Abstract

Fused silica glass has excellent optical properties, chemical and thermal stability and hardness, but its microstructuring for miniaturized applications has proven difficult. Here the authors demonstrate obtainment of precise arbitrary three dimensional hollow microstructures in fused silica glass by sacrificial template replication.

Published
2019
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3. List of contributors

Author

Dana Akilbekova, Michele Bertolini, Pablo Bordón, Ben Bowles, Harshavardhan Budharaju, Claudio Capelli, Miguel Castilho, Gerardo Cedillo-Servin, Wenqing Chen, Angela Daly, Carmen Salvadores Fernandez, Stephen Hilton, Shervanthi Homer-Vanniasinkam, Andrei Hrynevich, Deepak M. Kalaskar, Ruchi Pathak Kaul, Yang Li, F. Raquel Maia, Jos Malda, Mario D. Monzón, Ali Mousavi, Zaid Muwaffak, Amy Nommeots-Nomm, Joaquim M. Oliveira, Rubén Paz, Gowsihan Poologasundarampillai, Elena Provaggi, Subha N. Rath, Rui L. Reis, Uday Kiran Roopavath, Sharanya Sankar, Patricia Santos Beato, Houman Savoji, Silvia Schievano, Muthu Parkkavi Sekar, Swaminathan Sethuraman, Dhakshinamoorthy Sundaramurthi, Manish K Tiwari, Amanzhol Turlybekuly, Eirini Velliou, Lulu Xu, and Allen Zennifer

Published
2023
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5. Load-induced fluid pressurisation in hydrogel systems before and after reinforcement by melt-electrowritten fibrous meshes

Author

Eng Kuan Moo, Mohammadhossein Ebrahimi, Andrei Hrynevich, Mylène de Ruijter, Miguel Castilho, Jos Malda, Rami K. Korhonen, CS_Locomotion, and Equine Musculoskeletal Biology

Subjects
Reinforced scaffolds, Tissue Scaffolds, Fluid load support, Alginates, Sepharose, Alginate, Biomedical Engineering, Hydrogels, Viscoelasticity, Micro-indentation, Poroelasticity, Biomaterials, Unconfined compression, Mechanics of Materials, Three-Dimensional, Agarose, Tissue Engineering/methods, Gelatin, Printing, Gelatin methacryloyl
Abstract

Fluid pressure develops transiently within mechanically-loaded, cell-embedding hydrogels, but its magnitude depends on the intrinsic material properties of the hydrogel and cannot be easily altered. The recently developed melt-electrowriting (MEW) technique enables three-dimensional printing of structured fibrous mesh with small fibre diameter (20 μm). The MEW mesh with 20 μm fibre diameter can synergistically increase the instantaneous mechanical stiffness of soft hydrogels. However, the reinforcing mechanism of the MEW meshes is not well understood, and may involve load-induced fluid pressurisation. Here, we examined the reinforcing effect of MEW meshes in three hydrogels: gelatin methacryloyl (GelMA), agarose and alginate, and the role of load-induced fluid pressurisation in the MEW reinforcement. We tested the hydrogels with and without MEW mesh (i.e., hydrogel alone, and MEW-hydrogel composite) using micro-indentation and unconfined compression, and analysed the mechanical data using biphasic Hertz and mixture models. We found that the MEW mesh altered the tension-to-compression modulus ratio differently for hydrogels that are cross-linked differently, which led to a variable change to their load-induced fluid pressurisation. MEW meshes only enhanced the fluid pressurisation for GelMA, but not for agarose or alginate. We speculate that only covalently cross-linked hydrogels (GelMA) can effectively tense the MEW meshes, thereby enhancing the fluid pressure developed during compressive loading. In conclusion, load-induced fluid pressurisation in selected hydrogels was enhanced by MEW fibrous mesh, and may be controlled by MEW mesh of different designs in the future, thereby making fluid pressure a tunable cell growth stimulus for tissue engineering involving mechanical stimulation.

Published
2023
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6. The Multiweek Thermal Stability of Medical-Grade Poly(ε-caprolactone) During Melt Electrowriting

Author

Christoph Böhm, Paul D. Dalton, Jörg Teßmar, Jan Weichhold, Philipp Stahlhut, and Andrei Hrynevich

Subjects
chemistry.chemical_classification, Fusion, Jet (fluid), Materials science, Tissue Engineering, Tissue Scaffolds, Polymers, Polyesters, Modulus, General Chemistry, Polymer, Biomaterials, chemistry.chemical_compound, Crystallinity, chemistry, General Materials Science, Thermal stability, Fiber, ddc:610, Composite material, Caprolactone, Biotechnology
Abstract

Melt electrowriting (MEW) is a high-resolution additive manufacturing technology that places unique constraints on the processing of thermally degradable polymers. With a single nozzle, MEW operates at low throughput and in this study, medical-grade poly(ε-caprolactone) (PCL) is heated for 25 d at three different temperatures (75, 85, and 95 °C), collecting daily samples. There is an initial increase in the fiber diameter and decrease in the jet speed over the first 5 d, then the MEW process remains stable for the 75 and 85 °C groups. When the collector speed is fixed to a value at least 10% above the jet speed, the diameter remains constant for 25 d at 75 °C and only increases with time for 85 and 95 °C. Fiber fusion at increased layer height is observed for 85 and 95 °C, while the surface morphology of single fibers remain similar for all temperatures. The properties of the prints are assessed with no observable changes in the degree of crystallinity or the Young's modulus, while the yield strength decreases in later phases only for 95 °C. After the initial 5-d period, the MEW processing of PCL at 75 °C is extraordinarily stable with overall fiber diameters averaging 13.5 ± 1.0 µm over the entire 25-d period.

Published
2022

7. The Impact of Melt Electrowritten Scaffold Design on Porosity Determined by X-Ray Microtomography

Author

Almoatazbellah Youssef, Simon Zabler, Andreas Balles, Logan Fladeland, Jürgen Groll, Andrei Hrynevich, Paul D. Dalton, and Publica

Subjects
Scaffold, X-ray microtomography, Materials science, 0206 medical engineering, Biomedical Engineering, Medicine (miscellaneous), Bioengineering, quality assurance, 02 engineering and technology, medical devices, 03 medical and health sciences, Tissue engineering, poly(ɛ-caprolactone), Electrochemistry, Image Processing, Computer-Assisted, Composite material, Porosity, electrospinning, Microscale chemistry, 030304 developmental biology, 0303 health sciences, Tissue Scaffolds, Equipment Design, X-Ray Microtomography, 020601 biomedical engineering, Electrospinning, Methods Articles, tissue engineering, Poly ɛ caprolactone, Thermoplastic polymer, biomaterials
Abstract

Melt electrowriting (MEW) is an additive manufacturing (AM) technique using thermoplastic polymers to produce microscale structures, including scaffolds for tissue engineering. MEW scaffolds have, in general, high porosities and can be designed with different fiber diameters, spacings, and laydown patterns. The need for a reliable method for scaffold characterization is essential for quality assurance and research purposes. In this study, we describe the use of submicrometer X-ray tomography for the generation of local thickness maps of volume porosity of 16 different scaffold groups, comprising 2 diameter groups, 2 fiber spacing groups, and 4 different laydown patters (0/90°, 0/60/120°, 0/45/90/135°, and 0/30/60/90/120/150°), all made using a custom-built MEW printer with medical-grade poly(ɛ-caprolactone). The results showed a porosity range between 77.7% and 90.7% for all the scaffolds. Moreover, the influence of the scaffold regularity and flatness in the more regular pore shapes (0/90°, 0/60/120°) lead to the shift of the local thickness graph to one side, and thus the prevalence of one pore size. This nondestructive method for MEW scaffold characterization overcomes the limitations of microscopic methods of pore shape and size estimation. Impact Statement Melt electrowriting is an AM technology that bridges the gap between solution electrospinning and melt microextrusion technologies. It can be applied to biomaterials and tissue engineering by making a spectrum of scaffolds with various laydown patterns at dimensions not previously studied. Using submicrometer X-ray tomography, a “fingerprint” of porosity for such scaffolds can be obtained and used as an important measure for quality control, to ensure that the scaffold fabricated is the one designed and allows the selection of specific scaffolds based on desired porosities.

Published
2019
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8. Designing Outside the Box: Unlocking the Geometric Freedom of Melt Electrowriting using Microscale Layer Shifting

Author

Ievgenii Liashenko, Andrei Hrynevich, and Paul D. Dalton

Subjects
Manufacturing technology, Materials science, business.industry, Mechanical Engineering, Stacking, 3D printing, Mechanical engineering, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Nonlinear system, Mechanics of Materials, General Materials Science, Electrohydrodynamics, 0210 nano-technology, business, ddc:600, Microscale chemistry
Abstract

Melt electrowriting, a high-resolution additive manufacturing technology, has so far been developed with vertical stacking of fiber layers, with a printing trajectory that is constant for each layer. In this work, microscale layer shifting is introduced through deliberately offsetting the printing trajectory for each printed layer. Inaccuracies during the printing of sinusoidal walls are corrected via layer shifting, resulting in accurate control of their geometry and mechanical properties. Furthermore, more substantial layer shifting allows stacking of fiber layers in a horizontal manner, overcoming the electrostatic autofocusing effect that favors vertical layer stacking. Novel nonlinear geometries, such as overhangs, wall texturing and branching, and smooth and abrupt changes in printing trajectory are presented, demonstrating the flexibility of the layer shifting approach beyond the state-of-the-art. The practice of microscale layer shifting for melt electrowriting enables more complex geometries that promise to have a profound impact on the development of products in a broad range of applications.

Published
2020

9. Melt Electrowritten In Vitro Radial Device to Study Cell Growth and Migration

Author

Ezgi Bakirci, Andrei Hrynevich, Ouafa Dahri, Paul D. Dalton, Reiner Strick, Carmen Villmann, Pamela L. Strissel, and Natascha Schaefer

Subjects
Materials science, Depot, Biomedical Engineering, Cell Culture Techniques, General Biochemistry, Genetics and Molecular Biology, Biomaterials, 3D cell culture, Cell Movement, Cell Line, Tumor, Humans, Fiber, Cell Proliferation, Matrigel, Cell growth, Cell migration, Equipment Design, Drug Combinations, Electrowetting, Printing, Three-Dimensional, Biophysics, Seeding, Proteoglycans, Electrohydrodynamics, Collagen, Laminin, Glioblastoma
Abstract

The development of in vitro assays for 3D microenvironments is essential for understanding cell migration processes. A 3D-printed in vitro competitive radial device is developed to identify preferred Matrigel concentration for glioblastoma migration. Melt electrowriting (MEW) is used to fabricate the structural device with defined and intricate radial structures that are filled with Matrigel. Controlling the printing path is necessary to account for the distance lag in the molten jet, the applied electric field, and the continuous direct-writing nature of MEW. Circular printing below a diameter threshold results in substantial inward tilting of the MEW fiber wall. An eight-chamber radial device with a diameter of 9.4 mm is printed. Four different concentrations of Matrigel are dispensed into the radial chambers. Glioblastoma cells are seeded into the center and grow into all chambers within 8 days. The cell spreading area demonstrates that 6 and 8 mg mL-1 of Matrigel are preferred over 2 and 4 mg mL-1 . Furthermore, topographical cues via the MEW fiber wall are observed to promote migration even further away from the cell seeding depot. Previous studies implement MEW to fabricate cell invasive scaffolds whereas here it is applied to 3D-print in vitro tools to study cell migration.

Published
2020

10. Processing of Poly(lactic‐ co ‐glycolic acid) Microfibers via Melt Electrowriting

Author

Christoph Böhm, Biranche Tandon, Andrei Hrynevich, Jörg Teßmar, and Paul D. Dalton

Subjects
Polymers and Plastics, Organic Chemistry, Materials Chemistry, ddc:610, Physical and Theoretical Chemistry, Condensed Matter Physics
Abstract

Polymers sensitive to thermal degradation include poly(lactic-co-glycolic acid) (PLGA), which is not yet processed via melt electrowriting (MEW). After an initial period of instability where mean fiber diameters increase from 20.56 to 27.37 µm in 3.5 h, processing stabilizes through to 24 h. The jet speed, determined using critical translation speed measurements, also reduces slightly in this 3.5 h period from 500 to 433 mm min\(^{−1}\) but generally remains constant. Acetyl triethyl citrate (ATEC) as an additive decreases the glass transition temperature of PLGA from 49 to 4 °C, and the printed ATEC/PLGA fibers exhibits elastomeric behavior upon handling. Fiber bundles tested in cyclic mechanical testing display increased elasticity with increasing ATEC concentration. The processing temperature of PLGA also reduces from 165 to 143 °C with increase in ATEC concentration. This initial window of unstable direct writing seen with neat PLGA can also be impacted through the addition of 10-wt% ATEC, producing fiber diameters of 14.13 ± 1.69 µm for the first 3.5 h of heating. The investigation shows that the initial changes to the PLGA direct-writing outcomes seen in the first 3.5 h are temporary and that longer times result in a more stable MEW process.

Published
2022
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11. Precisely defined fiber scaffolds with 40 μm porosity induce elongation driven M2-like polarization of human macrophages

Author

Andrei Hrynevich, Tatjana Schilling, Katrin Schlegelmilch, Jürgen Groll, Tina Tylek, Paul D. Dalton, and Carina Blum

Subjects
Materials science, Cellular differentiation, 0206 medical engineering, Biomedical Engineering, Macrophage polarization, Bioengineering, Biocompatible Materials, 02 engineering and technology, Biochemistry, Biomaterials, Cell polarity, Macrophage, Humans, ddc:610, Polarization (electrochemistry), Tissue Engineering, Tissue Scaffolds, Regeneration (biology), Macrophages, Biomaterial, Cell Polarity, Cell Differentiation, General Medicine, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Biophysics, Elongation, 0210 nano-technology, Porosity, Biotechnology
Abstract

Macrophages are key players of the innate immune system that can roughly be divided into the pro-inflammatory M1 type and the anti-inflammatory, pro-healing M2 type. While a transient initial pro-inflammatory state is helpful, a prolonged inflammation deteriorates a proper healing and subsequent regeneration. One promising strategy to drive macrophage polarization by biomaterials is precise control over biomaterial geometry. For regenerative approaches, it is of particular interest to identify geometrical parameters that direct human macrophage polarization. For this purpose, we advanced melt electrowriting (MEW) towards the fabrication of fibrous scaffolds with box-shaped pores and precise inter-fiber spacing from 100 μm down to only 40 μm. These scaffolds facilitate primary human macrophage elongation accompanied by differentiation towards the M2 type, which was most pronounced for the smallest pore size of 40 μm. These new findings can be important in helping to design new biomaterials with an enhanced positive impact on tissue regeneration.

Published
2019

14. Melt Electrospinning of Nanofibers from Medical‐Grade Poly(ε‐Caprolactone) with a Modified Nozzle

Author

Paul D. Dalton, Marius Berthel, Andrei Hrynevich, Chiara Großhaus, Ezgi Bakirci, Juliane C Kade, Jürgen Groll, and Gernot Hochleitner

Subjects
chemistry.chemical_classification, Jet (fluid), Materials science, Nozzle, 02 engineering and technology, General Chemistry, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Electrospinning, 0104 chemical sciences, Taylor cone, Volumetric flow rate, Biomaterials, chemistry, Nanofiber, General Materials Science, Composite material, 0210 nano-technology, Melt electrospinning, Biotechnology
Abstract

Melt electrospun fibers, in general, have larger diameters than normally achieved with solution electrospinning. This study uses a modified nozzle to direct-write melt electrospun medical-grade poly(e-caprolactone) onto a collector resulting in fibers with the smallest average diameter being 275 ± 86 nm under certain processing conditions. Within a flat-tipped nozzle is a small acupuncture needle positioned so that reduces the flow rate to ≈0.1 µL h-1 and has the sharp tip protruding beyond the nozzle, into the Taylor cone. The investigations indicate that 1-mm needle protrusion coupled with a heating temperature of 120 °C produce the most consistent, small diameter nanofibers. Using different protrusion distances for the acupuncture needle results in an unstable jet that deposited poor quality fibers that, in turn, affects the next adjacent path. The material quality is notably affected by the direct-writing speed, which became unstable above 10 mm min-1 . Coupled with a dual head printer, first melt electrospinning, then melt electrowriting could be performed in a single, automated process for the first time. Overall, the approach used here resulted in some of the smallest melt electrospun fibers reported to date and the smallest diameter fibers from a medical-grade degradable polymer using a melt processing technology.

Published
2020
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15. 3D Electrophysiological Measurements on Cells Embedded within Fiber-Reinforced Matrigel

Author

Dieter Janzen, Natascha Schaefer, Paul D. Dalton, Carmen Villmann, Ezgi Bakirci, and Andrei Hrynevich

Subjects
Agonist, Scaffold, medicine.drug_class, Biomedical Engineering, Pharmaceutical Science, 02 engineering and technology, Matrix (biology), 010402 general chemistry, Inhibitory postsynaptic potential, 01 natural sciences, Cell Line, Biomaterials, Mice, Receptors, Glycine, medicine, Animals, ddc:610, Glycine receptor, Ion channel, Neurons, Matrigel, Tissue Engineering, Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Electrophysiology, Drug Combinations, Biophysics, Proteoglycans, Collagen, Laminin, 0210 nano-technology
Abstract

2D electrophysiology is often used to determine the electrical properties of neurons, while in the brain, neurons form extensive 3D networks. Thus, performing electrophysiology in a 3D environment provides a closer situation to the physiological condition and serves as a useful tool for various applications in the field of neuroscience. In this study, we established 3D electrophysiology within a fiber-reinforced matrix to enable fast readouts from transfected cells, which are often used as model systems for 2D electrophysiology. Using melt electrowriting (MEW) of scaffolds to reinforce Matrigel, we performed 3D electrophysiology on a glycine receptor-transfected Ltk-11 mouse fibroblast cell line. The glycine receptor is an inhibitory ion channel associated when mutated with impaired neuromotor behaviour. The average thickness of the MEW scaffold was 141.4 ± 5.7µm, using 9.7 ± 0.2µm diameter fibers, and square pore spacings of 100 µm, 200 µm and 400 µm. We demonstrate, for the first time, the electrophysiological characterization of glycine receptor-transfected cells with respect to agonist efficacy and potency in a 3D matrix. With the MEW scaffold reinforcement not interfering with the electrophysiology measurement, this approach can now be further adapted and developed for different kinds of neuronal cultures to study and understand pathological mechanisms under disease conditions.

Published
2019

16. Tailored Melt Electrowritten Scaffolds for the Generation of Sheet-Like Tissue Constructs from Multicellular Spheroids

Author

Katharina Wittmann, Torsten Blunk, Tim R. Dargaville, Paul D. Dalton, Christiane Hoefner, Jürgen Groll, Rebecca McMaster, Carina Blum, Petra Bauer-Kreisel, Andrei Hrynevich, and Miriam Wiesner

Subjects
Scaffold, Materials science, Stromal cell, Cell Survival, Polyesters, Biomedical Engineering, Pharmaceutical Science, Biocompatible Materials, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biomaterials, Spheroids, Cellular, Humans, Adipose tissue engineering, Manufacturing technology, Adipogenesis, Tissue Engineering, Tissue Scaffolds, Sepharose, Spheroid, Cell Differentiation, Lipid Droplets, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Adipose Tissue, embryonic structures, Printing, Three-Dimensional, Multicellular spheroid, Seeding, Stromal Cells, 0210 nano-technology, Porosity, Biomedical engineering
Abstract

Melt electrowriting (MEW) is an additive manufacturing technology that is recently used to fabricate voluminous scaffolds for biomedical applications. In this study, MEW is adapted for the seeding of multicellular spheroids, which permits the easy handling as a single sheet-like tissue-scaffold construct. Spheroids are made from adipose-derived stromal cells (ASCs). Poly(e-caprolactone) is processed via MEW into scaffolds with box-structured pores, readily tailorable to spheroid size, using 13-15 µm diameter fibers. Two 7-8 µm diameter "catching fibers" near the bottom of the scaffold are threaded through each pore (360 and 380 µm) to prevent loss of spheroids during seeding. Cell viability remains high during the two week culture period, while the differentiation of ASCs into the adipogenic lineage is induced. Subsequent sectioning and staining of the spheroid-scaffold construct can be readily performed and accumulated lipid droplets are observed, while up regulation of molecular markers associated with successful differentiation is demonstrated. Tailoring MEW scaffolds with pores allows the simultaneous seeding of high numbers of spheroids at a time into a construct that can be handled in culture and may be readily transferred to other sites for use as implants or tissue models.

Published
2018

17. Dimension-Based Design of Melt Electrowritten Scaffolds

Author

Jürgen Groll, Jodie N. Haigh, Andrei Hrynevich, Almoatazbellah Youssef, Gernot Hochleitner, Carina Blum, Bilge Ş. Elçi, Torsten Blunk, Rebecca McMaster, and Paul D. Dalton

Subjects
Fabrication, Materials science, Nozzle, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biomaterials, Dimension (vector space), Mass flow rate, Electrochemistry, Pressure, Humans, General Materials Science, Fiber, Tissue Engineering, Tissue Scaffolds, business.industry, Stem Cells, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Adipose Tissue, Optoelectronics, Electrohydrodynamics, 0210 nano-technology, business, Biotechnology, Biofabrication, Voltage
Abstract

The electrohydrodynamic stabilization of direct-written fluid jets is explored to design and manufacture tissue engineering scaffolds based on their desired fiber dimensions. It is demonstrated that melt electrowriting can fabricate a full spectrum of various fibers with discrete diameters (2-50 µm) using a single nozzle. This change in fiber diameter is digitally controlled by combining the mass flow rate to the nozzle with collector speed variations without changing the applied voltage. The greatest spectrum of fiber diameters was achieved by the simultaneous alteration of those parameters during printing. The highest placement accuracy could be achieved when maintaining the collector speed slightly above the critical translation speed. This permits the fabrication of medical-grade poly(e-caprolactone) into complex multimodal and multiphasic scaffolds, using a single nozzle in a single print. This ability to control fiber diameter during printing opens new design opportunities for accurate scaffold fabrication for biomedical applications.

Published
2018

18. Fibre pulsing during melt electrospinning writing

Author

Jürgen Groll, Gernot Hochleitner, Almoatazbellah Youssef, Andrei Hrynevich, Paul D. Dalton, Jodie N. Haigh, and Tomasz Jungst

Subjects
Scaffold, Materials science, Tissue engineering, Biomedical Engineering, Bioengineering, Composite material, Melt electrospinning, Electrospinning, Nanomaterials
Abstract

Additive manufacturing with electrohydrodynamic direct writing is a promising approach for the production of polymeric microscale objects. In this study we investigate the stability of one such process, melt electrospinning writing, to maintain accurate placement of the deposited fibre throughout the entire print. The influence of acceleration voltage and feeding pressure on the deposited poly(ε-caprolactone) fibre homogeneity is described, and how this affects the variable lag of the jet drawn by the collector movement. Three classes of diameter instabilities were observed that led to poor printing quality: (1) temporary pulsing, (2) continuous pulsing, and (3) regular long bead defects. No breakup of the electrified jet was observed for any of the experiments. A simple approach is presented for the melt electrospinning user to evaluate fibre writing integrity, and adjust the processing parameters accordingly to achieve reproducible and constant diameter fibres.

Published
2016
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