Your search keyword '"PRINTING ink"' showing total 4,135 results

51. Formulation of Nickel Oxide–Graphene Composite Ink and the Fabrication of Thin-Film Electrodes Using Direct Ink Writing.

Author

Thakur, Neha, Thomas, Neethu, Koshy, Aarju Mathew, Swaminathan, Parasuraman, and Murthy, Hari

Subjects

INK, NICKEL oxide, ETHYLENE glycol, PRINTING ink, NICKEL

Abstract

Nickel oxide (NiO) is a p-type material with a wide bandgap of 3.6 to 4 eV, and graphene is a zero-bandgap material. When the two materials are combined to form a composite, their structural, optical, and electrical properties are enhanced. This work presents the formulation of nickel oxide (NiO)–graphene composite ink (with ethylene glycol as a solvent) for the fabrication of thin-film electrodes using a direct ink writing technique. NiO is used in nanopowder form, which is prepared via a wet-chemical approach. NiO ink is prepared in three different concentrations of 40 mg/ml (N1), 60 mg/ml (N2), and 70 mg/ml (N3). Graphene ink (G) is also prepared in concentrations of 0.5 mg/ml (G1), 1 mg/ml (G2), and 2 mg/ml (G3). Among the pure NiO inks, it was observed that low resistance and uniform printing were obtained for N2. Therefore, N2 is mixed with different concentrations of graphene to form the composite ink, which is further printed on the substrates. The rheological properties of all the formulated inks are measured. An extrusion-based direct-write system is employed for printing the inks on a glass substrate. The printed samples are characterized before and after annealing at 250°C for 2 h. The resistance of the composite ink (N2G1) is decreased by 53% in comparison with the pure NiO ink (N2). As the conductivity of the composite ink thin film is in the range of MΩ, they could find application in the field of gas sensing and thermistors. [ABSTRACT FROM AUTHOR]

Published

2024

52. Synthesis of photoresponsive phenanthroimidazole-based S,S-dioxide dithienylethene for information storage and encryption.

Author

Lu, Jiaxian, Yan, Qing, Luo, Miao, Ren, Jun, and Wang, Sheng

Subjects

*INFORMATION technology security, *THIN films, *PRINTING ink, *DIARYLETHENE, *FLUORESCENCE, *SULFONES, *INTRAMOLECULAR proton transfer reactions

Abstract

Photoresponsive fluorescent compounds have been widely used to prepare the encryption inks for modern information security. In this study, a photoresponsive fluorescent material based on dithienylethene DTE-PIO4 was synthesized by oxidizing the two sulfur atoms to sulfones. Its solution presented a distinctive fluorescence switching performance when compared with the traditional "turn-off" mode fluorescent dithienylethene, while irreversible "turn-off" fluorescence switching was observed in PMMA films and solid state upon exposure to 254 nm UV light. Remarkably, the PMMA ink was successfully prepared by incorporation with DTE-PIO4, which indicated the great potential in the fields of optical information storage and ink printing. Further research on information encryption has also been demonstrated through the blending of DTE-PIO4 with DTE-PI in PMMA medium. [ABSTRACT FROM AUTHOR]

Published

2024

53. Design of printing ink spectral collection system and research on ink proportion prediction method.

Author

Zhang, Wenhao, Liu, Xinru, Zhang, Rui, Jiang, Fei, He, Junjia, and Fang, Shuyang

Subjects

*PRINTING ink, *STANDARD deviations, *INK, *ROOT-mean-squares

Abstract

In spectral-based ink content measurement, improving the accuracy of the spectral collection system and reducing the algorithm complexity of the ink content measurement model are important aspects of research. This study designs a spectral collection system with an M-type Czerny–Turner optical path structure, uses a third-order polynomial fitting method for calibration analysis, collects the spectral of the standard color card and denoises it through Savitzky–Golay convolution smoothing, and establishes a functional relationship between the spectral and the logarithm of ink content. Uninformative Variable Elimination (UVE) and Competitive Adaptive Reweighting Sampling are used to perform comparative analysis on feature wavelength extraction, and a prediction model for printing ink content is established. Experimental results show that the R2 of ink C, ink M, and ink Y are 0.9981, 0.9975, and 0.9892, respectively, and the root mean square error is 0.0134, 0.0153, and 0.0317, respectively, showing good performance in ink prediction accuracy. [ABSTRACT FROM AUTHOR]

Published

2024

54. Multi-material 3D printed eutectogel microneedle patches integrated with fast customization and tunable drug delivery.

Author

Liu, Huan, Zhou, Xinmeng, Nail, Aminov, Yu, Hao, Yu, Zilian, Sun, Yue, Wang, Kun, Bao, Nanbin, Meng, Decheng, Zhu, Liran, and Li, Huanjun

Subjects

*TRANSDERMAL medication, *THREE-dimensional printing, *CUSTOMIZATION, *DRUG solubility, *PRINTING ink, *CANAGLIFLOZIN

Abstract

Microneedle patches are emerging multifunctional platforms for transdermal diagnostics and drug delivery. However, it still remains challenging to develop smart microneedles integrated with customization, sensing, detection and drug delivery by 3D printing strategy. Here, we present an innovative but facile strategy to rationally design and fabricate multifunctional eutectogel microneedle (EMN) patches via multi-material 3D printing. Polymerizable deep eutectic solvents (PDES) were selected as printing inks for rapid one-step fabrication of 3D printing functional EMN patches due to fast photopolymerization rate and ultrahigh drug solubility. Moreover, stretchable EMN patches incorporating rigid needles and flexible backing layers were easily realized by changing PDES compositions of multi-material 3D printing. Meanwhile, we developed multifunctional smart multi-material EMN patches capable of performing wireless monitoring of body movements, painless colorimetric glucose detection, and controlled transdermal drug delivery. Thus, such multi-material EMN system could provide an effective platform for the painless diagnosis, detection, and therapy of a variety of diseases. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

55. Gradient matters via filament diameter-adjustable 3D printing.

Author

Qu, Huawei, Gao, Chongjian, Liu, Kaizheng, Fu, Hongya, Liu, Zhiyuan, Kouwer, Paul H. J., Han, Zhenyu, and Ruan, Changshun

Subjects

THREE-dimensional printing, 3-D printers, FIBERS, FLEXIBLE electronics, DIAMETER, PRINTING ink

Abstract

Gradient matters with hierarchical structures endow the natural world with excellent integrity and diversity. Currently, direct ink writing 3D printing is attracting tremendous interest, and has been used to explore the fabrication of 1D and 2D hierarchical structures by adjusting the diameter, spacing, and angle between filaments. However, it is difficult to generate complex 3D gradient matters owing to the inherent limitations of existing methods in terms of available gradient dimension, gradient resolution, and shape fidelity. Here, we report a filament diameter-adjustable 3D printing strategy that enables conventional extrusion 3D printers to produce 1D, 2D, and 3D gradient matters with tunable heterogeneous structures by continuously varying the volume of deposited ink on the printing trajectory. In detail, we develop diameter-programmable filaments by customizing the printing velocity and height. To achieve high shape fidelity, we specially add supporting layers at needed locations. Finally, we showcase multi-disciplinary applications of our strategy in creating horizontal, radial, and axial gradient structures, letter-embedded structures, metastructures, tissue-mimicking scaffolds, flexible electronics, and time-driven devices. By showing the potential of this strategy, we anticipate that it could be easily extended to a variety of filament-based additive manufacturing technologies and facilitate the development of functionally graded structures. Direct ink writing of complex 3D gradient structures can be challenging due to inherent method limitations. Here, the authors report continuous diameter-adjustable filament by varying printing speed and height and enable extrusion 3D printers to produce complex gradient porous matters. [ABSTRACT FROM AUTHOR]

Published

2024

56. 47‐1: Invited Paper: Electrohydrodynamic Inkjet Specialized Perovskite non‐polar Ink for Printing Color Conversion Layer of Micro‐LED Display.

Author

Lin, Yue, Yang, Xiao, Wang, Shuli, and Chen, Zhong

Subjects

INK, COLOR printing, PRINTING ink, LED displays, PEROVSKITE, ELECTRIC properties, QUANTUM dots

Abstract

In micro‐LED display, electrohydrodynamic (EHD) inkjet printing has been proven competent in patterning the fluorescent quantum dots in to color conversion arrays with the highest spatial resolution, compared with other inkjet printing technologies. In this article, we introduce basic thoughts of designing the EHD specialized inks, aiming to optimized the properties of ink for commercially readily products. First, from the view point of electrodynamics, the basic mechanism of electrical driving is introduced, in which the difference between two type of ink, the ionic polar ink and the colloidal nonpolar ink are compared. Secondly, the interconnections and the physical problem between ink engineering and the optimization targets: ejection control, pixel homogeneity, stability and efficiency are revealed. The correlation between dielectric constant and viscosity are described in theory. It is pointed out that this coupling between electric and rheologic properties need to be taken into consideration when designing the EHD specialized ink. [ABSTRACT FROM AUTHOR]

Published

2024

57. Investigation of Liquid Collagen Ink for Three-Dimensional Printing.

Author

Snider, Colten L., Glover, Chris J., Grant, David A., and Grant, Sheila A.

Subjects

THREE-dimensional printing, PRINTING ink, COLLAGEN, CELL culture, TISSUE scaffolds, GOLD nanoparticles, ETHYLENEDIAMINETETRAACETIC acid, POLYCAPROLACTONE

Abstract

Three-dimensional printing provides more versatility in the fabrication of scaffold materials for hard and soft tissue replacement, but a critical component is the ink. The ink solution should be biocompatible, stable, and able to maintain scaffold shape, size, and function once printed. This paper describes the development of a collagen ink that remains in a liquid pre-fibrillized state prior to printing. The liquid stability occurs due to the incorporation of ethylenediaminetetraacetic acid (EDTA) during dialysis of the collagen. Collagen inks were 3D-printed using two different printers. The resulting scaffolds were further processed using two different chemical crosslinkers, 1-Ethyl-3-[3-dimethylaminopropyl]carbodiimide hydrochloride)/N-hydroxysuccinimide (EDC/NHS) and genipin; gold nanoparticles were conjugated to the scaffolds. The 3D-printed scaffolds were characterized to determine their extrudability, stability, amount of AuNP conjugated, and overall biocompatibility via cell culture studies using fibroblast cells and stroma cells. The results demonstrated that the liquid collagen ink was amendable to 3D printing and was able to maintain its 3D shape. The scaffolds could be conjugated with gold nanoparticles and demonstrated enhanced biocompatibility. It was concluded that the liquid collagen ink is a good candidate material for the 3D printing of tissue scaffolds. [ABSTRACT FROM AUTHOR]

Published

2024

58. 3D printed polyvinylpyrrolidone–honey-gel with adhesive and degradable ability applied as bio-tape.

Author

Hu, Shilong, Liu, Yan, Yin, Zhengzhou, Chen, Husheng, Jin, Yuan, Zhang, Aibing, Zhang, Minghua, Hua, Licheng, Du, Jianke, and Li, Guangyong

Subjects

ADHESIVE tape, HONEY, THREE-dimensional printing, ADHESIVES, ANIMAL experimentation, MATERIALS testing, PRINTING ink

Abstract

This study explored the development of polyvinylpyrrolidone (PVP)–honey-gel (PHG) through 3D printing, aiming to develop a multifunctional bio-tape with adhesive and degradable properties. Based on the potential of honey to promote wound healing due to its antibacterial and anti-inflammatory properties, a PVP–honey-based 3D printing ink was developed by combining honey and PVP to create PHG through 3D printing technology that can form a film with strong adhesion and flexibility. First, the chemical–physical properties of PHG and its 3D printing performance were characterized. The line width achievable in 3D printing for the PHG line can extend to ∼100 µm. In addition, the adhesive properties of the PHG film were evaluated by using a 180° peeling test on various materials (glass, copper, wood, and pig skin), highlighting its potential for diverse applications. Finally, the application of the PHG film as a bio-tape was demonstrated through a successful animal experiment on a rabbit's skin wound. Due to its adhesive and degradable properties, the bio-tape exhibited 3D conformability and ease of removal without residue. [ABSTRACT FROM AUTHOR]

Published

2024

59. Integrated Ink Printing Paper Based Self‐Powered Electrochemical Multimodal Biosensing (IFP−Multi) with ChatGPT–Bioelectronic Interface for Personalized Healthcare Management.

Author

Xiong, Chuanyin, Dang, Weihua, Yang, Qi, Zhou, Qiusheng, Shen, Mengxia, Xiong, Qiancheng, An, Meng, Jiang, Xue, Ni, Yonghao, and Ji, Xianglin

Subjects

*PRINTING ink, *ELECTROCHEMICAL apparatus, *WRIST, *MUSCLE contraction, *PATIENT monitoring, *WEARABLE technology

Abstract

Personalized healthcare management is an emerging field that requires the development of environment‐friendly, integrated, and electrochemical multimodal devices. In this study, the concept of integrated paper‐based biosensors (IFP−Multi) for personalized healthcare management is introduced. By leveraging ink printing technology and a ChatGPT–bioelectronic interface, these biosensors offer ultrahigh areal‐specific capacitance (74633 mF cm−2), excellent mechanical properties, and multifunctional sensing and humidity power generation capabilities. More importantly, the IFP−Multi devices have the potential to simulate deaf‐mute vocalization and can be integrated into wearable sensors to detect muscle contractions and bending motions. Moreover, they also enable monitoring of physiological signals from various body parts, such as the throat, nape, elbow, wrist, and knee, and successfully record sharp and repeatable signals generated by muscle contractions. In addition, the IFP−Multi devices demonstrate self‐powered handwriting sensing and moisture power generation for sweat‐sensing applications. As a proof‐of‐concept, a GPT 3.5 model‐based fine‐tuning and prediction pipeline that utilizes recorded physiological signals through IFP−Multi is showcased, enabling artificial intelligence with multimodal sensing capabilities for personalized healthcare management. This work presents a promising and ecofriendly approach to developing paper‐based electrochemical multimodal devices, paving the way for a new era of healthcare advancements. [ABSTRACT FROM AUTHOR]

Published

2024

60. Toughening 3D printed biomimetic hydroxyapatite scaffolds: Polycaprolactone-based self-hardening inks.

Author

del-Mazo-Barbara, Laura, Johansson, Linh, Tampieri, Francesco, and Ginebra, Maria-Pau

Subjects

POLYCAPROLACTONE, BIOMIMETIC materials, HYDROXYAPATITE, FUSED deposition modeling, CALCIUM phosphate, PRINTING ink, THREE-dimensional printing

Abstract

The application of 3D printing to calcium phosphates has opened unprecedented possibilities for the fabrication of personalized bone grafts. However, their biocompatibility and bioactivity are counterbalanced by their high brittleness. In this work we aim at overcoming this problem by developing a self-hardening ink containing reactive ceramic particles in a polycaprolactone solution instead of the traditional approach that use hydrogels as binders. The presence of polycaprolactone preserved the printability of the ink and was compatible with the hydrolysis-based hardening process, despite the absence of water in the ink and its hydrophobicity. The microstructure evolved from a continuous polymeric phase with loose ceramic particles to a continuous network of hydroxyapatite nanocrystals intertwined with the polymer, in a configuration radically different from the polymer/ceramic composites obtained by fused deposition modelling. This resulted in the evolution from a ductile behavior, dominated by the polymer, to a stiffer behavior as the ceramic phase reacted. The polycaprolactone binder provides two highly relevant benefits compared to hydrogel-based inks. First, the handleability and elasticity of the as-printed scaffolds, together with the proven possibility of eliminating the solvent, opens the door to implanting the scaffolds freshly printed once lyophilized, while in a ductile state, and the hardening process to take place inside the body, as in the case of calcium phosphate cements. Second, even with a hydroxyapatite content of more than 92 wt.%, the flexural strength and toughness of the scaffolds after hardening are twice and five times those of the all-ceramic scaffolds obtained with the hydrogel-based inks, respectively. Overcoming the brittleness of ceramic scaffolds would extend the applicability of synthetic bone grafts to high load-bearing situations. In this work we developed a 3D printing ink by replacing the conventional hydrogel binder with a water-free polycaprolactone solution. The presence of polycaprolactone not only enhanced significantly the strength and toughness of the scaffolds while keeping the proportion of bioactive ceramic phase larger than 90 wt.%, but it also conferred flexibility and manipulability to the as-printed scaffolds. Since they are able to harden upon contact with water under physiological conditions, this opens up the possibility of implanting them immediately after printing, while they are still in a ductile state, with clear advantages for fixation and press-fit in the bone defect. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

61. Naturally Crosslinked Biocompatible Carbonaceous Liquid Metal Aqueous Ink Printing Wearable Electronics for Multi-Sensing and Energy Harvesting.

Author

Chung, King Yan, Xu, Bingang, Tan, Di, Yang, Qingjun, Li, Zihua, and Fu, Hong

Subjects

*LIQUID metals, *ENERGY harvesting, *WEARABLE technology, *PRINTING ink, *MULTIWALLED carbon nanotubes, *SMART materials

Abstract

Highlights: Naturally crosslinked carbonaceous liquid metal aqueous printable ink mediated by biopolymers. E-textile with conductivity, stability, wearability, and aesthetic characteristics. Multi-applications in health monitoring, pressure sensing, and energy harvesting. Achieving flexible electronics with comfort and durability comparable to traditional textiles is one of the ultimate pursuits of smart wearables. Ink printing is desirable for e-textile development using a simple and inexpensive process. However, fabricating high-performance atop textiles with good dispersity, stability, biocompatibility, and wearability for high-resolution, large-scale manufacturing, and practical applications has remained challenging. Here, water-based multi-walled carbon nanotubes (MWCNTs)-decorated liquid metal (LM) inks are proposed with carbonaceous gallium–indium micro-nanostructure. With the assistance of biopolymers, the sodium alginate-encapsulated LM droplets contain high carboxyl groups which non-covalently crosslink with silk sericin-mediated MWCNTs. E-textile can be prepared subsequently via printing technique and natural waterproof triboelectric coating, enabling good flexibility, hydrophilicity, breathability, wearability, biocompatibility, conductivity, stability, and excellent versatility, without any artificial chemicals. The obtained e-textile can be used in various applications with designable patterns and circuits. Multi-sensing applications of recognizing complex human motions, breathing, phonation, and pressure distribution are demonstrated with repeatable and reliable signals. Self-powered and energy-harvesting capabilities are also presented by driving electronic devices and lighting LEDs. As proof of concept, this work provides new opportunities in a scalable and sustainable way to develop novel wearable electronics and smart clothing for future commercial applications. [ABSTRACT FROM AUTHOR]

Published

2024

62. Coaxial 4D Printing of Vein‐Inspired Thermoresponsive Channel Hydrogel Actuators.

Author

Podstawczyk, Daria, Nizioł, Martyna, Śledzik, Piotr, Simińska‐Stanny, Julia, Dawiec‐Liśniewska, Anna, and Shavandi, Amin

Subjects

*HYDROGELS, *MICROFIBERS, *ACTUATORS, *CHLAMYDOMONAS reinhardtii, *TEMPERATURE control, *PRINTING ink, *THREE-dimensional printing, *TISSUE scaffolds

Abstract

Although significant progress has been made in coaxial printing of vascularized tissue models, this technique has not yet been used to fabricate stimulus‐responsive scaffolds capable of shape change over time. Here, a new method of direct ink printing (DIP) is proposed with a coaxial nozzle, coaxial 4D printing, enabling the manufacturing of thermoresponsive constructs embedded with a network of interconnected channels. In this approach, a poly(N‐isopropylacrylamide) (PNIPAAm)‐based thermoink is coaxially extruded into either core/sheath microfibers or microtubes. PNIPAAm renders a hydrogel temperature‐sensitive and endows it with a shape‐morphing property both at the micro‐ and macroscale. Specifically, the lumen diameter of the microtubes can be controlled by temperature by 30%. The macrostructural soft actuators can undergo programmed and reversible temperature‐dependent shape changes due to the structural anisotropy of the hydrogel. The permeability tests demonstrate that the hydrogel can possess enough strength to maintain the hollow channels without breaking. In vitro tests confirm the biocompatibility of the material with EA.hy926 cells, paving the avenue for new perfusable soft robots, or active implants. Finally, microalgae Chlamydomonas reinhardtii is combined with the hydrogels to fabricate materials having functions of both living microorganisms and stimuli‐responsive polymers toward creating engineered living materials (ELMs) with a vein‐like geometry. [ABSTRACT FROM AUTHOR]

Published

2024

63. Properties and interaction of layers in board-biodegradable primer-printing ink screen-printed system.

Author

Tomašegović, Tamara, Poljaček, Sanja Mahović, Hudika, Tomislav, and Marče, Andrea

Subjects

*PRINTING ink, *LACTIC acid, *INK, *PROTECTIVE coatings, *SCREEN process printing, *SURFACE interactions, *DNA primers, *SURFACE roughness

Abstract

Surface interactions of the materials during and after the printing process are extremely important for understanding and optimizing the process of graphic reproduction. In screen printing on porous and absorbent substrates, mesh type and ink composition significantly influence the properties of the printed product. To protect the absorbent printing substrates such as board from moisture penetration and to ensure the optimal interaction of the printed ink layer and the substrate, board substrates can be coated with protective primers before printing. In this research, biodegradable primers made of poly(ɛ-caprolactone) and poly(lactic acid) were applied on the board substrate which was then screen-printed using two screen rulings of the mesh and two different types of water-based printing inks on unprimed and primed board substrates. Printed ink layer thickness, surface roughness, water vapor transmission rate, surface free energy and adhesion parameters were measured/calculated on all produced samples. Microscopy of the printed elements was performed to visualize the influence of the primers on the printed line edge. Results of the research have shown that the primers influence the roughness reduction of the printed ink layer. Furthermore, thickness of the printed ink layers increased when the primers were applied on the substrate, pointing to the decreased permeability of the board, which was confirmed by the reduced water vapor transmission rate of the primed and printed substrates. The surface free energies of the tested surfaces and the adhesion parameters between biodegradable primers and prepared printing inks differed depending on the type of the ink and primer, pointing to the optimal combination of the primer and ink for the favorable acceptance of printing ink on the substrate. Results of this research have enabled the optimization of the quality of screen-printed board product. [ABSTRACT FROM AUTHOR]

Published

2024

64. Study on Preparation and Ink Performance of Flexible Electro-luminescent Devices.

Author

Ting Wang, Yibin Liu, Chenyang Liu, Gongming Li, Zhenzhen Li, Zhitong Yang, and Zhicheng Sun

Subjects

ELECTROLUMINESCENT devices, INK, ALTERNATING currents, PRINTING ink, ELECTROLUMINESCENCE

Abstract

Alternating current electroluminescence (ACEL) is a rapidly evolving technology with wide usage in intelligent and wearable display field owing to its high luminous efficiency and excellent flexibility. The purpose of this research is to develop and optimize the ink formula, create an inorganic ACEL device with dual-emission structure and superior performance, and investigate the effect of pigment concentration on the performance of luminescent ink. Through examination of ink and device performance, the study showed that a pigment concentration of 1:1 provided the best printing adaptability for the luminescent ink. Meanwhile, the device demonstrated the highest luminous efficiency of 77.73% and the maximum luminance of 189.56 cd/m2 at a voltage of 140 V and a frequency of 3000 Hz. This design scheme offers valuable insights for the production of electroluminescent inks with superior printing and luminescent properties, as well as contributing to the advancement of electroluminescent devices. [ABSTRACT FROM AUTHOR]

Published

2024

65. The assessment of average cell number inside in-flight 3D printed droplets in microvalve-based bioprinting.

Author

Chen, Xinxing, O'Mahony, Aidan P., and Barber, Tracie

Subjects

*BIOPRINTING, *TISSUE engineering, *TISSUE scaffolds, *IMAGING systems, *PRINTING ink

Abstract

3D cell bioprinting is an innovative and time-saving additive manufacturing technology; it precisely generates complex cell-laden constructs to overcome the limitations of 2D cell culture and conventional tissue engineering scaffold technology. Many efforts have been made to evaluate the bioprinter performance by considering printed cell number and the consistency of printed cell number. In this paper, a modified droplet imaging system is used to study the printing performance for a micro-valve-based 3D bioprinter using fluorescence MCF-7 cells. The effects of droplet dispensing physics (dosing energy E d), ink properties (Z number—the inverse of the Ohnesorge number and particle sedimentation velocity), and input cell concentration are considered. The droplet imaging system demonstrates a strong capability and accuracy in analyzing bioprinting performance for printed cell density less than 300 cells/droplet. The average printed cell number is positively correlated with the increasing input cell concentration, dosing energy, and printing time. Printing ink, with Z number ranging from 4 to 7.41 and cell sedimentation velocity at 9.45 × 10 − 8 m/s, can provide the estimated printed cell number and consistent cell printing results within 2 min printing time. Printing inks with higher Z number or cell sedimentation velocity should be ejected under dosing energy below 2.1 La and printed right after filling the reservoir to achieve reliable and stable printing results. [ABSTRACT FROM AUTHOR]

Published

2022

66. 20‐2: High‐resolution Pixelated Quantum Dot Light Emitting Diodes via Electrohydrodynamic Printing Technology.

Author

Yuan, Xu, Wang, Haowei, Liu, Yang, Chen, Zhuo, Li, Dong, Li, Yanzhao, Li, Xinguo, and Xu, Xiaoguang

Subjects

LIGHT emitting diodes, PIXEL density measurement, PHOTONS, QUANTUM dots, PRINTING ink, DIODES

Abstract

In this study, we achieved high‐resolution pixelated QLED device with 500 pixels per inch (ppi) through electrohydrodynamic printing (EHD) technology. We optimize the EHD printing process by controlling ink viscosity and printing speed to obtain a uniform and flat emission layer film. Then, we prepared high‐resolution pixelated bottom‐emission and top‐emission PMQLED with maximum current efficiencies of 13.6 cd/A and 16.4 cd/A, respectively. Finally, we fabricated a 500 ppi red and green (R/G) dual‐color bottom‐emission QLED device using the EHD printing method. The successful preparation of these 500 ppi QLED devices with high efficiency indicated that the EHD printing method can provides a technical basis for developing the high‐resolution QLED display technology in the future. [ABSTRACT FROM AUTHOR]

Published

2024

67. Direct-ink-write cross-linkable bottlebrush block copolymers for on-the-fly control of structural color.

Author

Sanghyun Jeon, Kamble, Yash Laxman, Haisu Kang, Jiachun Shi, Wade, Matthew A., Patel, Bijal B., Tianyuan Pan, Rogers, Simon A., Sing, Charles E., Guironnet, Damien, and Ying Diao

Subjects

*STRUCTURAL colors, *PRINTING ink, *VISIBLE spectra, *BLOCK copolymers, *PHOTOCROSSLINKING

Abstract

Additive manufacturing capable of controlling and dynamically modulating structures down to the nanoscopic scale remains challenging. By marrying additive manufacturing with self-assembly, we develop a UV (ultra-violet)-assisted direct ink write approach for on-the-fly modulation of structural color by programming the assembly kinetics through photo-cross-linking. We design a photo-cross-linkable bottlebrush block copolymer solution as a printing ink that exhibits vibrant structural color (i.e., photonic properties) due to the nanoscopic lamellar structures formed post extrusion. By dynamically modulating UV-light irradiance during printing, we can program the color of the printed material to access a broad spectrum of visible light with a single ink while also creating color gradients not previously possible. We unveil the mechanism of this approach using a combination of coarse-grained simulations, rheological measurements, and structural characterizations. Central to the assembly mechanism is the matching of the cross-linking timescale with the assembly timescale, which leads to kinetic trapping of the assembly process that evolves structural color from blue to red driven by solvent evaporation. This strategy of integrating cross-linking chemistry and out-of-equilibrium processing opens an avenue for spatiotemporal control of self-assembled nanostructures during additive manufacturing. [ABSTRACT FROM AUTHOR]

Published

2024

68. Photopolymerization Inks for 3D Printing of Elastic, Strong, and Biodegradable Oral Delivery Devices.

Author

Yuts, Yulia, Bohley, Marilena, Krivitsky, Adva, Bao, Yinyin, Luo, Zhi, and Leroux, Jean‐Christophe

Subjects

*THREE-dimensional printing, *DRUG delivery devices, *PHOTOPOLYMERIZATION, *DRUG delivery systems, *PRINTING ink

Abstract

Three‐dimensional (3D) printing via vat photopolymerization is transforming the manufacturing paradigms of biomedical devices, offering tremendous advantages for the production of customized advanced drug delivery systems. However, the existing commercial inks often lack the ability to simultaneously provide elasticity, strength, and biodegradability. Herein, photopolymerizable inks based on poly(β‐aminoester) diacrylates and N‐vinyl pyrrolidone are used to address these limitations. These biodegradable polymers enable the digital light processing 3D printing of elastomers with adjustable elongation at break (103–762%), stress at failure (0.2–8.3 MPa), and hydrolysis rates ranging from 25 min to 80 days. The authors are able to synthesize a soft polymer that possess properties akin to natural latex, which can enhance its elastic modulus when subjected to high strains. It can withstand 762% stretch with a maximum strength of 8.3 MPa. In addition, this polymer demonstrates cytocompatibility and unique biodegradation properties under simulated gastrointestinal conditions (within hours at pH 6.8). By utilizing this elastomer, a prototype of an expandable oral drug delivery device that has the ability to degrade within the average transit time in the jejunum is manufactured. This study paves the way to leverage vat photopolymerization 3D printing in the creation of complex prototypes of biomedical devices where strength, elasticity and biodegradability are essential. [ABSTRACT FROM AUTHOR]

Published

2024

69. Ultrafast Droplets Trajectories Modulation of Electrohydrodynamic Jet Printing for Pattern Refinement Using Electrostatic Deflection.

Author

Li, Xiaojian, Zhu, Long, Zhang, Fan, Zhang, Yu, Wang, Huaan, Sun, Lujing, Yin, Penghe, Chen, Li, Wang, Dazhi, and Liang, Junsheng

Subjects

*ELECTRIC field effects, *NUMERICAL calculations, *PRINTING ink

Abstract

Electrohydrodynamic jet (E‐Jet) printing is a highly promising non‐contact additive manufacturing technology. However, the fast jets generated by E‐Jet may cause droplet accumulation on small curvature features due to the slow motion control achieved by the mechanical stage, leading to a degradation of printed patterns in localized areas. Here, a method is proposed for ultrafast modulation of jet trajectories to achieve finely patterned E‐Jet printing by introducing jet‐deflecting electrodes around the jet, which can continuously transform the jet trajectory with lateral acceleration up to 104 ms−2. This extraordinary acceleration is two orders of magnitude higher than that can be achieved by using mechanical stage motion. Through a combination of numerical calculations and experiments, the effects of electric field parameters on the feature size and kinematic properties of jet droplets are investigated. In addition, deposition errors of <5 µm are fabricated by selecting appropriate working parameters and using UV‐curable adhesives as printing ink. Subsequently, complex micropatterns with feature curvatures <4 µm are successfully printed, demonstrating the consistency and reliability of this electrostatic deflection technique in achieving a uniform droplet deposition pitch. This innovative approach holds significant promise in the field of high‐quality microscale additive manufacturing. [ABSTRACT FROM AUTHOR]

Published

2024

70. Formulation and Evaluation of PVA/Gelatin/Carrageenan Inks for 3D Printing and Development of Tissue‐Engineered Heart Valves.

Author

Jafari, Arman, Vahid Niknezhad, Seyyed, Kaviani, Maryam, Saleh, Wael, Wong, Nicholas, Van Vliet, Patrick Piet, Moraes, Christopher, Ajji, Abdellah, Kadem, Lyes, Azarpira, Negar, Andelfinger, Gregor, and Savoji, Houman

Subjects

*HEART valves, *THREE-dimensional printing, *HEART development, *PRINTING ink, *BIOPRINTING

Abstract

Congenital and acquired valvular heart diseases (VHDs) are significant causes of mortality worldwide. With valve replacement being the primary solution for VHD, current options display shortcomings, including calcification, thrombogenicity, and hemodynamic alteration, leading to repetitive surgeries. Tissue engineering, however, has shown great potential for fabricating heart valves (HVs) with fewer complications. Here, a series of inks are developed, combining poly(vinyl alcohol), gelatin, and carrageenan for 3D printing of tissue‐engineered heart valves (TEHVs). The inks/hydrogels are investigated to characterize their physico‐chemical, morphological, mechanical, and rheological characteristics. In vitro and in vivo biocompatibility, immune response, hemolysis, and thrombogenicity of the inks/hydrogels are also evaluated. Moreover, in vitro hydrodynamics of the TEHVs under physiological conditions are reported. Inks demonstrate mechanical characteristics comparable to native leaflets. Subcutaneous implantation reveals that the hydrogels do not induce chronic inflammation and can undergo remodeling. In vitro hemocompatibility assessments of the hydrogels show minimal hemolysis with low thrombogenicity. Different sizes and types of HVs are successfully printed with high fidelity in the air. In vitro hydrodynamic assessment confirms that the TEHVs can withstand aortic conditions. Altogether, the 3D‐printed TEHVs can be a promising alternative for valve replacement to solve the problems associated with the current options. [ABSTRACT FROM AUTHOR]

Published

2024

71. Preparation and properties of alcohol‐resistant thermal transfer printing inks for multifunctional label printing via physical blending of resins.

Author

Luo, Zhuo, Chen, Guangyu, Yang, Yuanhao, Huang, Liuqing, Zhang, Chentong, Luo, Haixiang, Yu, Weiwei, and Luo, Xuetao

Subjects

HEAT transfer, PRINTING ink, TRANSFER printing, LABEL printing, GLASS transition temperature

Abstract

Due to the rise of the logistics industry and the widespread use of ink labels, problems such as the narrow operating temperature range of ink, poor alcohol resistance, and insufficient scratch resistance need to be solved urgently. In this work, creates alcohol‐resistant thermal transfer inks by mixing polypropylene chloride (VP‐365) and epoxidized hydrogenated bisphenol A (P) resin and incorporating them into the ink formulation. The synthetic ink has a lower glass transition temperature (118.2°C), allowing the ink to print at lower temperatures. It has small wetting angles (68°, 63°, 58°, 46°, and 40°) and a large adhesion force (10.44 – 14.4 N) for different labels. Further, to evaluate the printing performance of the ink, the ink was scratched under 1000 g pressure and in the environment of isopropyl alcohol to evaluate its printing performance. The produced ink has high scratch resistance (300 times) and good alcohol resistance (140 times). Moreover, the developed ink showed good printability, printing media versatility, high adhesion, and excellent alcohol resistance. The synthesis method is facile and cost‐effective, which paves a novel way towards high‐performance ink printing and thermal transfer technology industries. [ABSTRACT FROM AUTHOR]

Published

2024

72. Design of Quantum Dot Color Convertors for Inkjet‐Printed Optoelectronic Devices: Violet‐Converted Full Color Mini‐LED.

Author

Lin, Chen‐Te, Zhuan, Yi‐long, Jung, Nian‐Ting, Hoang, Minh‐Son, and Chen, Hsueh‐Shih

Subjects

*OPTOELECTRONIC devices, *INK, *QUANTUM dots, *COLOR printing, *OPACITY (Optics), *PRINTING ink, *COLOR

Abstract

This study presents a strategy of design and development of inkjet‐printable and UV‐curable quantum dot (QD) polymer‐based inks and color conversion (CC) film for use in optoelectronic devices. At first, the preparation of a QD ink is focused on two key aspects, that are QD chemical compatibility and ink printability. In the hybrid organic–inorganic polymer/QDs system, it must be formulated to a well‐dispersed ink, in which a dispersant additive without negative effect on QDs is introduced to enhance the QD suspension. As the optical density of final dried QD film is one of the most critical concerns in color conversion, QD concentration should be as high as possible in the ink, which increases the ink viscosity. Consequently, a trade‐off between QD concentration and the ink viscosity associated with the ink‐jetting temperature is considered to ensure the ink printability. Finally, the designed QD ink is printed as color conversion film on a mini‐LED panel composed of two violet mini‐chips to produce red and green emissions, while blue emission directly comes from a blue mini‐chip. The final conversion efficiency of QDCC on mini‐LED panel are between 35% and 45%, showing the promising applications in optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

73. Bioprint FirstAid: A handheld bioprinter for first aid utilization on space exploration missions.

Author

Warth, Nathanael, Berg, Marco, Schumacher, Laura, Boehme, Matthias, Windisch, Johannes, and Gelinsky, Michael

Subjects

*SPACE exploration, *CONDUCTIVE ink, *CLIMATE change mitigation, *BIOPRINTING, *PRINTING ink, *HUMAN ecology

Abstract

Human exploratory missions to Moon or Mars are considered the next steps in human space exploration. Such activities result in the exposure of humans to the space environment for long time, especially under the constraints of orbital dynamics as with increasing distances from earth quick return possibilities are ruled out. Crews on these kinds of missions must be self-sustaining in medical treatments, as environmental conditions in space, such as the influence of altered gravity, radiation or isolation, raise health issues. Therefore, astronauts may use the here presented Handheld Bioprinter as part of the first-aid strategy for in situ wound treatment. The device consists of a handle capable of holding an exchangeable "Ink Printing Unit" containing two separate gel-like components (Bioink and Crosslinker), which are extruded during a printing process through a nozzle and form a skin-cell containing bioink band-aid. For ISS experiments cell simulants were used, as in-space experiments first demonstrated the general feasibility of handheld bioprinting under space conditions. On-ground human skin cells were mixed with the biogel, printed via the handheld bioprinter and cultivated, to demonstrate the overall feasibility of the "Bioprint FirstAid" technology. Concluding results were that a mobile, handheld tool like the bioprinter shows good applicability and offers a possibility of in situ wound treatment for in-space applications. The "Bioprint FirstAid" project was coordinated by the German Space Agency at the German Aerospace Center (DLR) in Bonn and funded by the Federal Ministry for Economic Affairs and Climate Action (BMWK). • Handheld Bioprinter offers possibility for in-situ wound treatment in future in-space applications • Human skin cells proliferate in biogels after printing with handheld bioprinter • The customizable Ink-printing unit and nozzle can be tailored to specific printing demands • Bioprinter device has low susceptibility to failure, has a robust design, no electronics, and maintenance-free mechanics • German Astronaut Matthias Maurer conducted the Bioprinting experiment successfully on board the ISS [ABSTRACT FROM AUTHOR]

Published

2024

74. Development of textile printing ink using expanded polystyrene waste as a binder.

Author

Obele, Chizoba M, Ugwu, Shadrack C, and Chukwuneke, Jeremiah L

Subjects

*TEXTILE printing, *NATURAL dyes & dyeing, *PRINTING ink, *POLYSTYRENE, *RESPONSE surfaces (Statistics), *DIFFERENTIAL scanning calorimetry, *ALGINATES, *MICROBIAL exopolysaccharides

Abstract

This research produced textile pigment printing paste using expanded polystyrene (EPS) as a binder, sodium alginate as a thickener, and ultramarine pigment. The printing paste production was optimized through response surface methodology, using central composite design (CCD). The dynamic viscosity of the produced printing paste samples ranges from 5200 to 5550.50 cP (Centi Poise). The Fourier infrared transform (FTIR) spectroscopy revealed the functional groups present in the printing paste. The result of the thermogravimetric analysis (TGA) conducted shows a first step decomposition of 94.14% that occurred at the range of 30.96°C–127.75°C. Differential scanning calorimetry (DSC) showed an endothermic transition at 119.44°C due to the absorption of energy during the breaking of printing paste bonds. Textile characterization such as wash fastness, croak fastness, and light fastness was carried out to determine the suitability of the print paste on cotton and polyester fabrics. The results of the fastness tests range from 4 to 5 for wash fastness, 3 to 4/5 for croak fastness, and 4 to 6 for light fastness. The optimum values of the model variables are thickener (50%), binder (40%), and pigment (5%). The performance of the printing paste as revealed from the results is moderate and comparable with textile printing paste suitable for commercial application. Graphical Abstract [ABSTRACT FROM AUTHOR]

Published

2024

75. Prediction of viscoelastic properties of peanut‐based 3D printable food ink.

Author

Kadival, Amaresh, Mitra, Jayeeta, Kaushal, Manish, and Machavaram, Rajendra

Subjects

*ARTIFICIAL neural networks, *PEANUTS, *XANTHAN gum, *PRINTING ink, *THREE-dimensional printing, *INK

Abstract

Viscoelastic properties of 3D printable peanut‐based food ink were investigated using frequency sweep and relaxation test. The incorporation of xanthan gum (XG) improved the shear thinning behavior (n value ranging from 0.139 to 0.261) and lowered the η*, G′, and G′′ values, thus making food ink 3D printable. The addition of XG also caused a downward shift in the relaxation curve. This study evaluates the possibility of an artificial neural network (ANN) approach as a substitute for the Maxwell three‐element and Peleg model for predicting the viscoelastic behavior of food ink. The results revealed that all three models accurately predicted the decay forces. The inclusion of XG decreased the hardness and enhanced the cohesiveness, so enabling the 3D printing of food ink. The hardness was highly positively correlated with Maxwell model parameters Fe, F1, F2, F3, and Peleg constant k2 (0.57) and negatively correlated with k1 (−0.76). [ABSTRACT FROM AUTHOR]

Published

2024

76. A flexible ultra-broadband multi-layered absorber working at 2 GHz–40 GHz printed by resistive ink.

Author

Wang, Tao, Yan, Yu-Lun, Chen, Gong-Hua, Li, Ying, Hu, Jun, and Mao, Jian-Bo

Subjects

*FREQUENCY selective surfaces, *PRINTING ink, *CONDUCTIVE ink, *REFLECTANCE, *CURRENT distribution

Abstract

A flexible extra broadband metamaterial absorber (MMA) stacked with five layers working at 2 GHz–40 GHz is investigated. Each layer is composed of polyvinyl chloride (PVC), polyimide (PI), and a frequency selective surface (FSS), which is printed on PI using conductive ink. To investigate this absorber, both one-dimensional analogous circuit analysis and three-dimensional full-wave simulation based on a physical model are provided. Various crucial electromagnetic properties, such as absorption, effective impedance, complex permittivity and permeability, electric current distribution and magnetic field distribution at resonant peak points, are studied in detail. Analysis shows that the working frequency of this absorber covers entire S, C, X, Ku, K and Ka bands with a minimum thickness of 0.098 λ max (λ max is the maximum wavelength in the absorption band), and the fractional bandwidth (FBW) reaches 181.1%. Moreover, the reflection coefficient is less than −10 dB at 1.998 GHz–40.056 GHz at normal incidence, and the absorptivity of the plane wave is greater than 80% when the incident angle is smaller than 50°. Furthermore, the proposed absorber is experimentally validated, and the experimental results show good agreement with the simulation results, which demonstrates the potential applicability of this absorber at 2 GHz–40 GHz. [ABSTRACT FROM AUTHOR]

Published

2024

77. Fabrication of an Optically Transparent Planar Inverted-F Antenna Using PEDOT-Based Silver Nanowire Clear Ink with Aerosol-Jet Printing Method towards Effective Antennas.

Author

Li, Philip, Fleischer, Jason, Quinn, Edwin, and Park, Donghun

Subjects

ANTENNAS (Electronics), PLANAR antennas, CONDUCTIVE ink, PRINTING ink, NANOWIRES, COPLANAR waveguides, SUBSTRATE integrated waveguides, SILVER

Abstract

We report the design, fabrication, and experimental characterization of an optically transparent printed planar inverted-F antenna (PIFA) operating at 2.45 GHz using the aerosol jet (AJ) printing method. The proposed antenna was fabricated using a clear conductive ink on glass and Delrin. The antenna exhibits a wide fractional bandwidth (FBW) of 20% centered at 2.45 GHz, with a peak realized gain of −3.6 dBi and transparency of ~80%. The proposed fabrication method provides a cost-effective and scalable solution for manufacturing transparent antennas with potential applications in wireless communication, sensing, and wearable devices operating at mmWave frequencies higher than 30 GHz. [ABSTRACT FROM AUTHOR]

Published

2024

78. Reproducción del color en impresión offset con tintas ecológicas. Un estudio de viabilidad.

Author

Prieto Dávila, Pablo R.

Subjects

OFFSET printing, COLOR printing, PRINTING ink, QUALITY control, QUALITY standards

Abstract

Copyright of Cuadernos del Centro de Estudios de Diseño y Comunicación is the property of Cuadernos del Centro de Estudios de Diseno y Comunicacion and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

79. Application of Plant-based Nanocellulose in Food 3D Printing.

Author

Xu Bo, Ma Tao, Hu Xinna, Lu Shuyu, and Song Yi

Subjects

THREE-dimensional printing, FOOD packaging, FUNCTIONAL foods, FOOD additives, FOOD science, PRINTING ink

Abstract

3D printing is particularly important to take adequate advantage of emerging processing technologies and food ingre-dients. This paper introduced the structural characteristics of plant-based nanocellulose and its functional properties com-patible with 3D printing, including high mechanical strength, convenient surface modification, suitability for printing rhe- ological properties, and favorable biosafety, analyzed the properties and uses of both types of two types of plant-based nanocellulose printing inks, hydrogels and emulsions, summarized its application status in food additives, food packaging, food freshness indicators, functional substance carrier, provided an outlook for the future of preparing emerging functional foods and smart food packaging, and made a prospect in order to provide a referential for future development. [ABSTRACT FROM AUTHOR]

Published

2024

80. The effect of thickness of a conductive nanocomposite ink printed on textile co-planar waveguide antenna.

Author

Radi, Nor Hadzfizah Mohd, Ismail, Mohd Muzafar, Zakaria, Zahriladha, and Abd Razak, Jeefferie

Subjects

CONDUCTIVE ink, WAVEGUIDE antennas, TEXTILE printing, PRINTING ink, WEARABLE antennas, SUBSTRATE integrated waveguides, PLANAR waveguides

Abstract

In the area of wearable technology an enhancement of basic microstrip antenna is evolution of wearable textile antenna. A new development of wearable antenna is the incorporated of conductive plane using nanocomposite ink that embedded onto the fabric. In this paper, the performance of variety thickness of conductive Graphene-Ag-Cu ink on a drill fabric is presented. The performances include its resistivity and conductivity measurement. By performing a measurement using scanning electron microscopy, energy-dispersive X-ray spectroscopy, and four-point probe, it can obtain and measure the composition and thickness of nanocomposite layered on a fabric and resistivity respectively. Hence, it can provide detailed information about the surface morphology, roughness, and thickness of the nanocomposite coating on the fabric as well as the electrical conductivity. Finally, the electrical conductivity increased to the fifth layered from 0.1473×104 S/cm up to 0.5393×104 S/cm. [ABSTRACT FROM AUTHOR]

Published

2024

81. Starch as edible ink in 3D printing for food applications: a review.

Author

Chen, Yuanhui, McClements, David Julian, Peng, Xinwen, Chen, Long, Xu, Zhenlin, Meng, Man, Zhou, Xing, Zhao, Jianwei, and Jin, Zhengyu

Subjects

*EDIBLE coatings, *THREE-dimensional printing, *STARCH, *PRINTING ink, *3-D printers, *NUTRITIONAL requirements

Abstract

Three-dimensional (3D) printing has attracted more attention in food industry because of its potential advantages, including the ability to create customized products according to individual's sensory or nutritional requirements. However, the production of high-quality 3D printed foods requires the availability of edible bio-inks with the required physicochemical and sensory attributes. Starch, as one of the important sources of dietary energy, is widely used in food processing and is considered as one kind of versatile polymers. It is not only because starch has low prices and abundant sources, but also because desirable modified starch can be obtained by altering its physicochemical properties through physical, chemical and enzymatic methods. This article focuses on the utilization of starch as materials to create food-grade bio-inks. Initially, several kinds of commonly used 3D printers are discussed. The factors affecting the printing quality of starch-based materials and improvement methods are then reviewed, as well as areas where future researches are required. The applications of 3D printed starch-based materials in food industry are also introduced. Overall, starch appears to be one kind of useful substances for creating edible bio-inks that can be utilized within 3D food printing applications to create a wide variety of food products. [ABSTRACT FROM AUTHOR]

Published

2024

82. Universal Strategy for Regulating Protein‐Based High Internal Phase Emulsions as 3D Printing Materials.

Author

Xiao, Feng, Hu, Sijie, Li, Jinyu, Pan, Jinfeng, Dong, Xiuping, Du, Ming, and Xu, Xianbing

Subjects

*THREE-dimensional printing, *PSEUDOPLASTIC fluids, *INTERFACIAL tension, *CONTACT angle, *PRINTING ink

Abstract

Protein‐stabilized high internal phase emulsions (HIPEs), which are pseudoplastic fluids with shear thinning and high viscoelasticity, are suitable for 3D printing inks. However, owing to the lack of a universal approach to the 3D printing of HIPEs, existing printing materials are unable to meet the developmental, biocompatibility, and safety requirements of various applications. Herein, it is demonstrated that post‐acidification of protein HIPEs enhances 3D printing performance. This method has the advantage of breaking through protein limitations, pH, and other environmental factors. The self‐supporting property required for 3D printing is achieved through the self‐assembly of continuous‐phase proteins into particle aggregates, and interfacial stability is maintained owing to the constant interfacial tension and contact angle. The acid‐induced protein aggregates in the continuous phase do not affect the stability of the modified HIPEs. This work provides a valuable new idea for advancing the application of protein HIPEs in 3D printing through a post‐acidification strategy. [ABSTRACT FROM AUTHOR]

Published

2024

83. Jetting and droplet formation of particle-loaded fluids.

Author

Shi, Jing, Cagney, Neil, Tatum, John, Condie, Angus, and Castrejón-Pita, J. Rafael

Subjects

*PRINTING ink, *FLUIDS, *PSEUDOPLASTIC fluids, *RHEOLOGY

Abstract

Inkjet printing is an attractive method for patterning and fabricating objects across many areas of industry. There is a growing interest in the printing of inks with high particle-loading, such as inks containing glass frit, ceramic and functional inks. However, the use of these inks is often limited due to uncertainty regarding the impact of their rheology on the printing process. Understanding of the role of complex rheology in the jetting of loaded inks is therefore needed to facilitate the wider application of inkjet printing. Here, we characterize the complex rheology and the jetting of model dispersion inks (containing 10, 15, and 23 vol. % TiO2 nanoparticles) and compared them with those without particles. The jetting of the model fluids was conducted with a commercial inkjet printhead (nozzle diameter 34 μm) and visualized with stroboscopic and ultra-high-speed imaging. For low particle concentrations, droplet formation is generally similar to those of unloaded inks, provided their Ohnesorge number and Weber number are matched, although the filament of the loaded model fluid tends to have earlier break-off, having a shorter length. The jetting reliability decreased with increase in particle-loading until reliable jetting can no longer be achieved, due to local particle–particle interactions in the ink channel and in the filament during the fast extensional thinning process. A jetting map is presented which illustrates the influence of particle-loading on the droplet formation, and indicates that the acceptable range of Ohnesorge number for jetting is reduced as the particle-loading is increased. [ABSTRACT FROM AUTHOR]

Published

2024

84. Upcycling imperfect broccoli and carrots into healthy snacks using an innovative 3D food printing approach.

Author

Ahmadzadeh, Safoura, Clary, Taylor, Rosales, Alex, and Ubeyitogullari, Ali

Subjects

*THREE-dimensional printing, *BROCCOLI, *SNACK foods, *CARROTS, *ANALYSIS of colors, *VEGETABLES, *PRINTING ink

Abstract

Vegetables are healthy foods with nutritional benefits; however, nearly one‐third of the world's vegetables are lost each year, and some of the losses happen due to the imperfect shape of the vegetables. In this study, imperfect vegetables (i.e., broccoli and carrots) were upcycled into freeze‐dried powders to improve their shelf‐life before they were formed into food inks for 3D printing. The rheology of the food inks, color analysis of the uncooked and cooked designs, and texture analysis of the cooked designs were determined. The inks with 50% and 75% vegetables provided the best printability and shape fidelity. 3D printing at these conditions retained a volume comparable to the digital file (14.4 and 14.3 cm3 vs. 14.6 cm3, respectively). The control, a wheat flour‐based formulation, showed the lowest level of stability after 3D printing. The viscosity results showed that all the food inks displayed shear‐thinning behavior, with broccoli having the greatest effect on viscosity. There was a significant color difference between uncooked and cooked samples, as well as between different formulations. The hardness of the baked 3D‐printed samples was affected by the type and content of vegetable powders, where carrot‐based snacks were notably harder than snacks containing broccoli. Overall, the results show that 3D food printing can be potentially used to reduce the loss and waste of imperfect vegetables. [ABSTRACT FROM AUTHOR]

Published

2024

85. Influence of PEDOT:PSS coating on screen-printed textile.

Author

PETROVIĆ, SAŠA, DEDIJER, SANDRA, KAŠIKOVIĆ, NEMANJA, ZELJKOVIĆ, ŽELJKO, GVOIĆ, VESNA, JURIČ, IVANA, and STANČIĆ, MLADEN

Subjects

COATED textiles, CONDUCTIVE ink, PRINTING ink, ELECTROTEXTILES, SCREEN process printing

Abstract

Copyright of Industria Textila is the property of Institutul National de Cercetare-Dezvoltare pentru Textile si Pielarie and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

86. Hierarchically Porous Iron Alloys with High Sintering Resistance During Cyclic Steam Oxidation and Hydrogen Reduction.

Author

Pennell, Samuel M., Chappuis, Benoît, Carpenter, Julia A., and Dunand, David C.

Subjects

*HYDROGEN oxidation, *SINTERING, *IRON, *IRON alloys, *FOAM, *MESOPORES, *PRINTING ink

Abstract

Hydrogen release/storage materials for iron/air batteries are fabricated as Fe‐16Mo and Fe‐24Ni (at.%) lattices via 3D‐extrusion printing of foamed inks containing oxide microparticles, followed by H2 reduction and sintering. A hierarchical open porosity is designed: (i) channels between walls created during printing, (ii) mesopores within walls, created during ink foaming, and (iii) micropores within ligaments between mesopores, created from partial sintering metal particles and gas escape during cycling. When subjected to H2/H2O redox cycling at 800 °C, the lattices of both compositions gradually undergo sintering. The Fe‐16Mo lattice remains fully redox‐active after 50 cycles unlike the Fe‐24Ni lattice, which loses 90% of its redox capacity after 30 cycles. The increased lifetime of the Fe‐16Mo lattice is attributed to the sintering inhibition of Mo, the formation of a mixture of oxide phases in the oxidized state, and the cyclic formation of submicron Fe2Mo by reduction of MoO2 and Fe2Mo3O8. The microstructure of the foamed walls is examined throughout cycling to track changes in morphology and composition. These are correlated to volume and porosity changes in the lattice. A comparison is made to previously‐studied Fe‐Mo and Fe‐Ni freeze‐cast lamellar foams, and variations in performance are discussed in the context of the different architectures. [ABSTRACT FROM AUTHOR]

Published

2023

87. Gelation of Uniform Interfacial Diffusant in Embedded 3D Printing.

Author

Shin, Sungchul, Brunel, Lucia G., Cai, Betty, Kilian, David, Roth, Julien G., Seymour, Alexis J., and Heilshorn, Sarah C.

Subjects

*THREE-dimensional printing, *BIOPRINTING, *HYDROGELS, *ENDOTHELIAL cells, *HUMAN body, *GELATION, *PRINTING ink

Abstract

While the human body has many different examples of perfusable structures with complex geometries, biofabrication methods to replicate this complexity are still lacking. Specifically, the fabrication of self‐supporting, branched networks with multiple channel diameters is particularly challenging. Herein, the Gelation of Uniform Interfacial Diffusant in Embedded 3D Printing (GUIDE‐3DP) approach for constructing perfusable networks of interconnected channels with precise control over branching geometries and vessel sizes is presented. To achieve user‐specified channel dimensions, this technique leverages the predictable diffusion of cross‐linking reaction‐initiators released from sacrificial inks printed within a hydrogel precursor. The versatility of GUIDE‐3DP to be adapted for use with diverse physicochemical cross‐linking mechanisms is demonstrated by designing seven printable material systems. Importantly, GUIDE‐3DP allows for the independent tunability of both the inner and outer diameters of the printed channels and the ability to fabricate seamless junctions at branch points. This 3D bioprinting platform is uniquely suited for fabricating lumenized structures with complex shapes characteristic of multiple hollow vessels throughout the body. As an exemplary application, the fabrication of vasculature‐like networks lined with endothelial cells is demonstrated. GUIDE‐3DP represents an important advance toward the fabrication of self‐supporting, physiologically relevant networks with intricate and perfusable geometries. [ABSTRACT FROM AUTHOR]

Published

2023

88. Prediction of ink flow for 3D bioprinting of tubular tissue based on a back propagation neural network.

Author

Wu, Xiaoyan and Wang, Shu

Subjects

*BIOPRINTING, *BACK propagation, *PRINTING ink, *PRINCIPAL components analysis, *3-D printers, *TISSUES

Abstract

Based on the development of the 3D vascular printer, the forming process of ink from the nozzle to the rotating rod was studied. In this study, to online detect the ink flow from the nozzle during 3D bioprinting of tubular tissue, we established a geometric model according to the region of interest (ROI) of the ink flow picture of 3D printing of tubular tissue, selected description features of the ink contour, and studied how to select mathematical expressions of the features. Principal component analysis (PCA) was used to simplify the image features into 15 features. We used a back propagation (BP) neural network to predict the printing ink flow. The results show that the error between the actual ink flow rate and the flow rate based on the BP neural network is within 5%. The BP neural network can be used to monitor the quality status of the printing target in real time, evaluate the 3D bioprinting quality online, and predict the printing ink flow for the subsequent improvement of the 3D bioprinting accuracy of tubular tissue. [ABSTRACT FROM AUTHOR]

Published

2023

89. Synthesize carbon black pigment from empty fruit bunch as a colorant for printing ink.

Author

Susiani, Susiani, Nugraha, Mawan, Ardiani, Septia, Suryadi, Gema S., Latif, Antinah, Situngkir, Yessy Y., and Setiadi, Eko A.

Subjects

*PRINTING ink, *INDUSTRIAL wastes, *MANUFACTURING processes, *FRUIT, *CHEMICAL elements, *CARBON-black

Abstract

Empty Palm oil fruit bunch (EPOFB) are one of the palm oil processing industrial wastes that are abundantly available in Indonesia but are not optimally used. This study aims to synthesize carbon black pigments from EPOFB using the co-precipitation method. The synthesized Carbon black was then characterized by SEM EDX to determine particle size and find out the chemical elements contained in it. The test results showed that the particle size of carbon was in the form of flakes with elemental composition, about 76.8% Carbon, 22.9% Oxygen, and the rest was silicon element. The carbon black resulting from this study has the potential to be used as a black pigment for printing ink. [ABSTRACT FROM AUTHOR]

Published

2023

90. Additive Manufacturing of Elastomeric Composite Lattices with Thermally Grown Micro‐Architectures for Versatile Applications.

Author

Tang, Zhen‐Hua, Xue, Shan‐Shan, Li, Yuan‐Qing, Huang, Pei, Fu, Ya‐Qin, and Fu, Shao‐Yun

Subjects

*MANUFACTURING processes, *ENERGY dissipation, *PRINTING ink, *MICROSPHERES, *THERMAL insulation, *FIBERS, *CARBON nanotubes, *FOAM

Abstract

Microengineering of materials plays an important role in achieving multifunctionality and enhancing performance. However, it is still a major challenge to construct secondary micro‐architectures in composite lattices to date. Herein, a novel microengineering strategy of combining additive manufacturing and thermo‐growth processes is proposed to develop elastomeric composite lattices with micro‐architectures throughout the filaments for versatile applications. The new printing inks are composed of elastomeric matrices, closed‐cell microspheres and carbon nanotubes (CNTs). After printing, microspheres "grow" to form secondary micro‐architectures inside by applying thermal treatment. Such thermo‐growth offers a good opportunity to manufacture objects with exceptional and complex micro‐architectures, and few synthetic materials can "grow" like this. Further investigation shows that the obtained microstructured elastomeric composite lattice has an excellent impact energy dissipation capacity by reducing the impact force by 57% owing to the hierarchical energy dissipation mechanisms, and exhibits a distinctively linear electrical response to impact which endows it a self‐sensing capability. In addition, it also shows a good thermal‐insulation performance endowed by mm‐scale pores and µm‐scale hollow spheres, which is comparable to existing composite foams. This study represents an innovative and effective approach for the development of micro‐engineered composite lattices with excellent multifunctional properties for versatile applications. [ABSTRACT FROM AUTHOR]

Published

2023

91. Pad printing inks based on reduced graphene oxide and various cellulose binders: Rheological properties, printability and application in electrochemical sensors.

Author

Pavličková, Michaela, Đurđić, Slađana, Hatala, Michal, Stanković, Dalibor, Švorc, Ľubomírx, Veteška, Peter, and Gemeiner, Pavol

Subjects

ELECTROCHEMICAL sensors, GRAPHENE oxide, RHEOLOGY, PRINTING ink, CELLULOSE, CELLULOSE fibers

Abstract

Pad printing is not a widely used printing technique, but it offers the possibility of a simple, fast, and low-cost production of various high-resolution electrode structures. Here, the pad-printed reduced graphene oxide (rGO) electrodes are prepared from pad-printable inks containing rGO powder and different concentrations of two cellulose-based polymers: ethylcellulose and cellulose acetate butyrate. The applicability of rGO inks for pad printing is analyzed according to their rheological parameters and printability. Based on viscosity, storage (G0) and loss modulus (G00) values, 10wt% of ethylcellulose and 15 wt% of cellulose acetate butyrate appear to be most suitable for pad printing. The effect of polymer concentration on rGO electrodes homogeneity and mechanical stability is also evaluated. Cyclic voltammetry measurements for [Fe(CN)6]3-/4-redox system are performed with rGO/cellulose inks pad-printed onto transparent conductive oxide substrates with the best results when using ethylcellulose as a binder. Finally, the square-wave voltammetric method assesses the viability of rGO electrodes for the fast detection of ascorbic acid (detection limit of 15 µM) coupled with satisfactory precision (4.5%, n = 5) and long-term stability during electrochemical measurements. [ABSTRACT FROM AUTHOR]

Published

2023

92. Large area inkjet-printed OLED fabrication with solution-processed TADF ink.

Author

Kant, Chandra, Shukla, Atul, McGregor, Sarah K. M., Lo, Shih-Chun, Namdas, Ebinazar B., and Katiyar, Monica

Subjects

DELAYED fluorescence, ORGANIC light emitting diodes, INK-jet printing, LIGHT emitting diodes, PLATINUM group, PRINTING ink

Abstract

This work demonstrates successful large area inkjet printing of a thermally activated delayed fluorescence (TADF) material as the emitting layer of organic light-emitting diodes (OLEDs). TADF materials enable efficient light emission without relying on heavy metals such as platinum or iridium. However, low-cost manufacturing of large-scale TADF OLEDs has been restricted due to their incompatibility with solution processing techniques. In this study, we develop ink formulation for a TADF material and show successful ink jet printing of intricate patterns over a large area (6400 mm2) without the use of any lithography. The stable ink is successfully achieved using a non-chlorinated binary solvent mixture for a solution processable TADF material, 3‐(9,9‐dimethylacridin‐10(9H)‐yl)‐9H‐xanthen‐9‐one dispersed in 4,4'-bis-(N-carbazolyl)-1,1'-biphenyl host. Using this ink, large area ink jet printed OLEDs with performance comparable to the control spin coated OLEDs are successfully achieved. In this work, we also show the impact of ink viscosity, density, and surface tension on the droplet formation and film quality as well as its potential for large-area roll-to-roll printing on a flexible substrate. The results represent a major step towards the use of TADF materials for large-area OLEDs without employing any lithography. Low-cost manufacturing of large-scale thermally activated delayed fluorescence organic light-emitting diodes has been restricted due to their incompatibility with solution processing techniques. Here, authors develop inkjet printing ink formulation to fabricate patterns without use of lithography. [ABSTRACT FROM AUTHOR]

Published

2023

93. Cross‐Linking Strategies for Silk‐Protein‐Based Inks for 3D Printing.

Author

Dong, Xiaoyuan, Liu, Fengqiang, Wang, Liming, Xu, Lihui, Pan, Hong, and Qi, Junhong

Subjects

*THREE-dimensional printing, *PRINTING ink, *SILK fibroin, *REGENERATIVE medicine, *BIOELECTRONICS, *RAW materials

Abstract

Due to excellent biocompatibility, sufficient raw material, robust mechanical properties and easy cross‐linking, Silk Fibroin (SF) is a promising protein for 3D printing inks and an ideal candidate for 3D scaffolds in fields like regenerative medicine, bioelectronics and bio‐optics. In order to meet the requirements of print accuracy, mechanical properties and form retention capabilities, the first step is to prepare SF 3D printing inks using physical, chemical or other strategies of cross‐linking. The basic chemical groups and physical structure of SF determines its ability to form 3D networks under different conditions using various cross‐linking strategies. In the preparation of SF‐based 3D printing inks, physical, chemical or other strategies of cross‐linking improve the qualities of printing, but each strategy has its advantages and disadvantages. This paper discusses different crosslinking strategies for SF to support the development of exciting potential for SF‐based 3D printing inks to meet more needs in the future. [ABSTRACT FROM AUTHOR]

Published

2023

94. Aqueous Calcium Phosphate Cement Inks for 3D Printing.

Author

Weichhold, Jan, Pfeiffle, Maximilian, Kade, Juliane C., Hurle, Katrin, and Gbureck, Uwe

Subjects

CALCIUM phosphate, THREE-dimensional printing, BONE substitutes, CEMENT, PRINTING ink, POWDERS, PASTE

Abstract

Mimicking the native properties and architecture of natural bone is a remaining challenge within the field of regenerative medicine. Due to the chemical similarity of calcium phosphate cements (CPCs) to bone mineral, these cements are well studied as potential bone replacement material. Nevertheless, the processing and handling of CPCs into prefabricated pastes with adequate properties for 3D printing has drawbacks due to slow reaction times, limited design freedom, as well as fabrication issues such as filter pressing during ejection through thin nozzles. Herein, an aqueous cement paste containing α‐tricalcium phosphate powder is proposed, which is stabilized by sodium pyrophosphate (Na4P2O7·10H2O) as additive. Since high powder loadings within pastes can result in filter pressing during extrusion, various concentrations and molecular weights of hyaluronic acid (HyAc) are added to the cement paste, resulting in reduced filter pressing during 3D extrusion‐based printing. These cement pastes are investigated regarding their setting reaction after activation with orthophosphate solution by isothermal calorimetry and X‐ray diffraction, as well as their hardening performance using Imeter measurements, while the processability is assessed by extrusion through 1.2 and 0.8 mm cannulas. The 3D‐printed structures with appropriate HyAc molecular weight and concentration demonstrate suitable mechanical properties and resolution for clinical application. [ABSTRACT FROM AUTHOR]

Published

2023

95. Low-cost fabrication and physicochemical characterization of ZnFe2O4 nanoparticles as an efficient multifunctional inorganic pigment.

Author

Sayed, Mostafa A., Abdelmaksoud, W. M. A., Teleb, Said M., El-Din, Adel M., and Abo-Aly, Mohamed M.

Subjects

METAL coating, PIGMENTS, NANOPARTICLES, SOL-gel processes, X-ray diffraction, PRINTING ink, PAINT materials

Abstract

The pursuit of low-cost manufacturing of newly effective pigments is a pressing economic need. Thus, in this work, low-cost ZnFe2O4 spinel nanoparticles (ZF-NPs) with an average diameter of 20 nm were successfully synthesized using a simple sol–gel method, which can be extended for large-scale fabrication of a reddish nano pigment. TGA/DTA, XRD, DRS, HRTEM, and SEM/EDX investigations were used to characterize the as-prepared product. The color of synthesized NPs was studied using CIE L*a*b* colorimetric method with color coordinates of L* = 41.7, a* = 72.2, and b* = 48.8. The newly developed pigment was examined to be superior to the traditional pigment (M6001/Fe2O3: L* = 30.4, a* = 42.16, and b* = 45.7). After that, the synthesized nano pigment was integrated into both ink and paint formulations as a multifunctional coating. The inclusion of synthesized nano pigment in metal coating printing ink formulation was done to produce a good alternative and cost-effective substitute for the commercially available pigment used in the inks industry. Also, the effect of the fabricated nanoparticles on corrosion resistance and thermal stability of epoxy-based paint formulations was evaluated using different standard tests. Therefore, the ZnFe2O4 pigment should be applied as a highly efficient inorganic nano pigment. [ABSTRACT FROM AUTHOR]

Published

2023

96. Effect of Food 3D Printing Process on the Rheological Properties of Rice Protein Printing Inks †.

Author

Barrios-Rodríguez, Yeison Fernando, Igual-Ramo, Marta, Martínez-Monzó, Javier, and García-Segovia, Purificación

Subjects

*RHEOLOGY, *THREE-dimensional printing, *PRINTING ink, *XANTHAN gum, *RICE

Abstract

Different statistical approaches were used to analyze the rheological properties of a rice-protein-based product before and after printing. The printing ink was composed of 30% rice protein and 70% water, with the addition of 0.5% xanthan gum. Printing parameters: The layer height (1 and 1.5 mm), printing speed (50 and 35 mm/s), and nozzle diameter (1.2 and 1.7 mm) were evaluated. Rheological properties were determined before and after printing using an oscillatory test from 0.1 to 10 Hz at 1 Pa. The decomposition of the curves into principal components helped us better understand the variations of the rheological properties along the frequency, differentiating the samples before and after printing. [ABSTRACT FROM AUTHOR]

Published

2023

97. Additive manufacturing of (MgCoNiCuZn)O high-entropy oxide using a 3D extrusion technique and oxide precursors.

Author

Chen, Ruoyu, Li, Saisai, Yan, Qingfeng, and Wen, Haiming

Subjects

*ELECTRON beam furnaces, *THREE-dimensional printing, *SPECIFIC gravity, *RHEOLOGY, *PERMITTIVITY, *PRINTING ink, *OXIDES

Abstract

This report presents an additive manufacturing approach, for the first time, to producing high-entropy oxides (HEOs) using a 3D extrusion-based technique with oxide precursors. The precursors were prepared by a wet chemical method from sulfates. Additives were utilized to optimize the rheological properties of the printing inks with these precursors, and the properties of the printed HEOs were improved by increasing the solid content of the inks. When ink with a solid content of 78 wt% was used for printing, the resulting HEO exhibited a relative density of 92% and a high dielectric constant after undergoing pressureless sintering at 800 °C. Compared to traditional methods of manufacturing HEOs, the 3D extrusion technique is a very promising method for producing HEOs with complex geometries. [ABSTRACT FROM AUTHOR]

Published

2023

98. MODIFICATION OF VEGETABLE OILS WITH REACTIVE COMPOUNDS FOR THE PRODUCTION OF PRINTING INKS.

Author

Sisyuk, V. G., Zel, L. I., Ugro, N. G., and Ostapiuk, S. M.

Subjects

*VEGETABLE oils, *PRINTING ink, *VARNISH & varnishing, *BLOCK copolymers, *DOUBLE bonds, *OLIGOMERS, *POLYOLS

Abstract

The modification of existing paints and varnishes based on alkyd resins, as well as the creation of new film formers using functionalised oligomers to improve the properties of materials in use, has been carried out. The aim of the work is to study vegetable oils used in the production of printing inks and to modify them in order to improve their technological properties. The work carried out allows the use of printing inks based on modified vegetable oils, with the expansion of their scope of application in the production of various printed products. The modification of vegetable oils was carried out by interaction with synthesised urethane-containing reactive block copolymers. Modification of mustard oil allows to change its structure, to increase its molecular weight by oligomerisation of the oil with obtaining of branched structure. Modified vegetable oils provide fast drying alkyd coatings, even in air. The properties of modified oils, the rate of film formation depend on the chemical nature of the block copolymer, its reactivity. The main processes of oil film structuring are due to oxidative and thermal polymerisation of double bonds of fatty acid residues. Optimisation of the vegetable oil modification process has been carried out, a formulation for the production of printing inks has been developed and production tests have been carried out with positive results. [ABSTRACT FROM AUTHOR]

Published

2023

99. Novel and Accessible Physical Recycling for Expanded Polystyrene Waste with the Use of Acetone as a Solvent and Additive Manufacturing (Direct Ink-Write 3D Printing).

Author

García-Sobrino, Rubén, Cortés, Alejandro, Calderón-Villajos, Rocío, Díaz, Jorge G., and Muñoz, Marta

Subjects

*THREE-dimensional printing, *POLYSTYRENE, *PRINTING ink, *APPROPRIATE technology, *SOLVENTS, *ACETONE, *MICROBIAL exopolysaccharides

Abstract

The current high production of plastics has prompted the exploration of alternative pathways to facilitate recycling, aiming for a progressively sustainable society. This paper presents an alternative and affordable technology for treating waste expanded polystyrene (EPS) mixed with acetone in a 100:1 volume ratio to be used as 3D printing ink for Direct Ink Write technology. In order to optimize the printing parameters, a comprehensive study was conducted, evaluating different needle diameters, printing speeds, and bed temperature values to achieve homogenous pieces and a highly repeatable 3D printing process. Results showed that the main optimum printing parameters were using needles with diameters of 14 to 16 G and printing speeds ranging from 2 to 12 mm/s, which were found to yield the most uniform ribbons. Increasing the bed temperature, despite favoring acetone evaporation, led to the generation of more heterogeneous structures due to void growth inside the printed ribbons. Thus, employing room temperature for the bed proved to be the optimal value. Lastly, a comparative study between the starting material and the EPS after the printing process was conducted using FTIR-ATR and GPC analyses, ensuring the preservation of the original polymer's integrity during physical recycling. [ABSTRACT FROM AUTHOR]

Published

2023

100. Carbon ink printed flexible glove-based aptasensor for rapid and point of care detection of Chikungunya virus.

Author

Sharma, Pradakshina, Hasan, Mohd. Rahil, Khanuja, Manika, and Narang, Jagriti

Subjects

*CHIKUNGUNYA virus, *POINT-of-care testing, *FIELD emission electron microscopy, *FLEXIBLE electronics, *PRINTING ink

Abstract

Printed electronic technologies have sparked interest worldwide because of their capacity to transcend the limitations of existing high-cost electronics based on the fabrication of various devices deploying flexible substrates. Fabricating electrodes on stretchable, bendable, and soft substrates plays a vital role in flexible electronics. Hence this study demonstrates an electrochemical flexible substrate-based aptamer sensor for the Chikungunya virus (CHIKV) antigen over an extensive range of concentrations. In brief, ZnO nanorods were chemically synthesised and characterised by Field emission scanning electron microscopy (FESEM), UV-Vis spectroscopy, Fourier transform infrared (FT-IR) spectroscopy, and X-Ray Diffraction (XRD), providing biocompatibility to the aptamer, a biorecognition element. The aptasensor showed a wide linearity (1 ng/ml-10 μg/ml), deploying a voltammetric identification in the presence of 10 mM methylene blue act as a redox-transition substance, with an estimated limit of detection of 1 ng/ml and 25 s as its optimal response time. The applicability of the sensor was further demonstrated by introducing CHIKV-Antigen into commercial serum samples. The built-in sensor has a shelf-life of approximately a month. CHIKV-Antigen can be detected rapidly on a portable platform. As a result, CHIKV can be diagnosed more quickly, allowing for more effective treatment choices. [Display omitted] • In-house, a flexible glove based three electrode system was developed. • Chemically synthesized and thoroughly characterized zinc oxide nanorods were utilized. • The built electrochemical sensor performed in human serum efficiently. • This sensor could be used to diagnose Chikungunya virus antigen. • The application of the Dengue Virus protein confirmed cross-reactivity. [ABSTRACT FROM AUTHOR]

Published

2023