Electrohydrodynamic printing process monitoring by microscopic image identification

Sun, Junying; Jing, Linzhi; Fan, Xiaotian; Gao, Xueying; Liang, Yung C.

doi:10.18063/ijb.v5i1.164

Cited by 14 publications

(14 citation statements)

References 16 publications

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“…This observation is likely due to the charged amino acid residues in the peptide chains of gliadin that alter the electrical properties of the supplied composite inks. The charge could be released through parameter optimization, , making it feasible to stably print PCL/gliadin scaffolds.…”

Section: Results and Discussionmentioning

confidence: 99%

“…A high-voltage power output from the power supply was applied between the nozzle and conductive substrate to generate an electric field required by the EHDP technique. Furthermore, a digital microscope (B011, Supereyes Technology Co., Ltd., China) was installed to monitor the real-time cone jet formation and printing processes as previously described …”

Section: Experimental Sectionmentioning

confidence: 99%

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Engineered Nanotopography on the Microfibers of 3D-Printed PCL Scaffolds to Modulate Cellular Responses and Establish an In Vitro Tumor Model

Jing

Wang

Leng

et al. 2021

ACS Appl. Bio Mater.

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Scaffold-based three-dimensional (3D) cell culture systems have gained increased interest in cell biology, tissue engineering, and drug screening fields as a replacement of twodimensional (2D) monolayer cell culture and as a way to provide biomimetic extracellular matrix environments. In this study, microscale fibrous scaffolds were fabricated via electrohydrodynamic printing, and nanoscale features were created on the fiber surface by simply leaching gliadin of poly(ε-caprolactone) (PCL)/ gliadin composites in ethanol solution. The microstructure of the printed scaffolds could be precisely controlled by printing parameters, and the surface nanotopography of the printed fiber could be tuned by varying the PCL/gliadin ratios. By seeding mouse embryonic fibroblast (NIH/3T3) cells and human nonsmall cell lung cancer (A549) cells on the printed scaffolds, the cellular responses showed that the fiber nanotopography on printed scaffolds efficiently favored cell adhesion, migration, proliferation, and tissue formation. Quantitative analysis of the transcript expression levels of A549 cells seeded on nanoporous scaffolds further revealed the upregulation of integrin-β1, focal adhesion kinase, Ki-67, E-cadherin, and epithelial growth factor receptors over what was observed in the cells grown on the pure PCL scaffold. Furthermore, a significant difference was found in the relevant biomarker expression on the developed scaffolds compared with that in the monolayer culture, demonstrating the potential of cancer cell-seeded scaffolds as 3D in vitro tumor models for cancer research and drug screening.

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Section: Results and Discussionmentioning

confidence: 99%

Section: Experimental Sectionmentioning

confidence: 99%

Engineered Nanotopography on the Microfibers of 3D-Printed PCL Scaffolds to Modulate Cellular Responses and Establish an In Vitro Tumor Model

Jing

Wang

Leng

et al. 2021

ACS Appl. Bio Mater.

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“…Optimize micro-droplet generator, electrohydrodynamic, drop-ondemand, and spheroid-based bioprinters [199][200][201]205] NGC Performance SWIRL for predicting graft success Bootstrap aggregated neural networks for predicting conduit performance [206][207][208] Abbreviations…”

Section: Discussionmentioning

confidence: 99%

“…Machine sensors can analyze acoustic signals or video recordings to assess the quality of printed layers by identifying aberrant features [203,204]. Machine vision can also fine-tune the electrohydrodynamic printing (EHDP) by monitoring cone shapes for more precise scaffold biofabrication [205]. Digital microscopic imaging combined with CNN Developing automated inspection systems using machine intelligence can reduce print variation experienced during conduit production.…”

Section: E Application To Am and 3dbpmentioning

confidence: 99%

Machine intelligence for nerve conduit design and production

et al. 2020

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Nerve guidance conduits (NGCs) have emerged from recent advances within tissue engineering as a promising alternative to autografts for peripheral nerve repair. NGCs are tubular structures with engineered biomaterials, which guide axonal regeneration from the injured proximal nerve to the distal stump. NGC design can synergistically combine multiple properties to enhance proliferation of stem and neuronal cells, improve nerve migration, attenuate inflammation and reduce scar tissue formation. The aim of most laboratories fabricating NGCs is the development of an automated process that incorporates patient-specific features and complex tissue blueprints (e.g. neurovascular conduit) that serve as the basis for more complicated muscular and skin grafts. One of the major limitations for tissue engineering is lack of guidance for generating tissue blueprints and the absence of streamlined manufacturing processes. With the rapid expansion of machine intelligence, high dimensional image analysis, and computational scaffold design, optimized tissue templates for 3D bioprinting (3DBP) are feasible. In this review, we examine the translational challenges to peripheral nerve regeneration and where machine intelligence can innovate bottlenecks in neural tissue engineering.

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“…[4] A CCD camera was used to dynamically record the EHD printing process. [34] Structural Characterization: The organization of the EHD-printed microfibrous architectures was mainly characterized by a scanning electron microscope (SEM, S-3000N, Hitachi, Japan). The 3D profile of the printed scaffolds was visualized and reconstructed by using a micro-computerized topography (μCT, YXLON, German).…”

Section: Methodsmentioning

confidence: 99%

Expanding Melt‐Based Electrohydrodynamic Printing of Highly‐Ordered Microfibrous Architectures to Cm‐Height Via In Situ Charge Neutralization

Hao

Meng

et al. 2021

Adv Materials Technologies

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As EHD printing relies on the electrical force between the nozzle tip and the collecting surface to eject the polymer melts or solutions, the electrical field strength gradually decreases as the printing layer increases. [7,8] In addition, due to the inherent low conductivity nature of polymeric fibers, extensive residual charges are entrapped and accumulate inside the printed structures, which generate electrical repellent forces to the successively-printed fibers and disrupt the precision stacking process at a relatively great printing layer. [9][10][11] These factors significantly limit the height of EHD-printed scaffolds smaller than 3 mm. [12,13] It still remains a substantial challenge to fabricate microfibrous scaffolds with relatively large height and wellordered fiber organizations. [14] Currently, several pioneering explorations have been attempted to address the issues of unstable electrical field strength and the fiber repellent force for the EHD printing of 3D polymeric structures. [15][16][17] Luo et al. reported an innovative solutionbased EHD printing strategy by utilizing fibrous paper as the collector substrate, which can transfer the electrical charges from the printed fibers to the grounded conductive plate via the ions migration inside the residual solvent of the newly-deposited fibers. [18] Such charge transport mechanism dynamically changes the newly-deposited fibers into locally grounded electrical poles to attract the precision stacking of successive fibers. This phenomenon simultaneously alleviates the decrease of electrical strength and the repulsion of printed fibers, which facilitates the EHD printing of a hollow cylinder with a height of 1.3 cm. However, this strategy is not suitable for melt-based EHD printing since the polymer melts, with higher viscosity and extremely lower conductivity compared to polymer solutions, cannot freely transfer residual charges from the printed fibers to the grounded substrates. Recently, Wunner et al. reported a melt-based EHD printing strategy to fabricate large-volume scaffolds with highly-ordered architectures by dynamically changing the nozzle-to-collector distance and applied voltages to maintain constant electrical field strength during the whole printing process. [19] The maximum height of the printed structures reached 7.1 mm, which

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Electrohydrodynamic printing process monitoring by microscopic image identification

Cited by 14 publications

References 16 publications

Engineered Nanotopography on the Microfibers of 3D-Printed PCL Scaffolds to Modulate Cellular Responses and Establish an In Vitro Tumor Model

Engineered Nanotopography on the Microfibers of 3D-Printed PCL Scaffolds to Modulate Cellular Responses and Establish an In Vitro Tumor Model

Machine intelligence for nerve conduit design and production

Expanding Melt‐Based Electrohydrodynamic Printing of Highly‐Ordered Microfibrous Architectures to Cm‐Height Via In Situ Charge Neutralization

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