The Emerging Frontiers and Applications of High-Resolution 3D Printing

Mao, Mao; He, Jiankang; Li, Xiao; Zhang, Bing; Qi, Lei; Liu, Yaxiong; Li, Dichen

doi:10.3390/mi8040113

Cited by 161 publications

(99 citation statements)

References 115 publications

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“…Despite the differences in their operating principles, they all utilize a layer-by-layer fabrication method to create 3D objects. Extensive research has been put forth to advance the resolution of additive manufacturing technologies to the micro and nano-scale for its 7 potential applications in MEMS, lab-on-a-chip and energy storage (Mao et al, 2017).…”

Section: Review Of Vat Polymerization Additive Manufacturing Technologymentioning

confidence: 99%

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Fabrication of 3D conjugated polymer structures via vat polymerization additive manufacturing

Cullen

Price

2019

Smart Mater. Struct.

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Conjugated polymers are a class of electromechanically active materials that can produce motion in response to an electric potential. This motion can be harnessed to perform mechanical work, and therefore these materials are particularly well suited for use as sensors and actuators in microelectromechanical systems. Conventional methods to fabricate conjugated polymer actuators result in planar morphologies that limit fabricated devices to simplistic linear or bending actuation modes. To overcome this limitation, this work develops a conjugated polymer formulation and associated additive manufacturing method capable of realizing three-dimensional conductive polymer structures. A light-based additive manufacturing technique known as vat polymerization is employed due to its ability to fabricate complex microscale features. A specially-formulated photosensitive polypyrrole resin was optimized for the production of microscale 3D structures. The transduction properties of the photosensitive polymer formulation were characterized to evaluate the material's application in mechanical sensing and actuation technologies.

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Section: Review Of Vat Polymerization Additive Manufacturing Technologymentioning

confidence: 99%

“…Spatial resolutions of 80 nm have been achieved with the two-photon polymerization method by utilizing high precision lasers and positioning systems (Mao et al, 2017).…”

Section: Review Of Vat Polymerization Additive Manufacturing Technologymentioning

confidence: 99%

Fabrication of 3D conjugated polymer structures via vat polymerization additive manufacturing

Cullen

Price

2019

Smart Mater. Struct.

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“…The quality of the printed model defined by the viscosity of the material and deposition speed. This fast and effective method easily print the complex structure in flexible manner [24] .…”

Section: B Printing Methodsmentioning

confidence: 99%

“…3D printing of Electronics also have the same processing steps of normal 3d printing such as 1.Prototype making, 2.Faster time-to-market, 3.Design flexibility, 4.Customisation and 5.Simplified Post process. More number of electronic devices are small miniature components which can have the minimal circuit element that are connected together in a specific area to influencing the flow of electrical current to make controlling the processing of data [3] . This 3d printing method is applied to printing an integrated circuits has initiated the modern electronics manufacturing to make trend in worldwide.…”

Section: Introductionmentioning

confidence: 99%

Experimental Analysis of Electrical Conductivity of the 3D Printed Graphene

R*¹,

Deepthi²

2019

IJEAT

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To develop a 3D printed material system for extracting the electrical conductivity of the piezoelectric material, to fabricate the integrated piezoelectric prototype and it’s always have a good availability with the more number of variety of materials for making with special characteristics. This paper introduces with direct ink writing method for printing the piezoelectric material by using multi materials such as terphinal, ethyl cellulose, methanol and graphene. The materials and processing steps for the manufacturing the 3d printed piezoelectric component, the individual material characteristics and the equivalent circuit is provided. Electrical Conductivity analysis on the 3D printed piezoelectric done with the above mentioned material and the result has been discussed by using the four point probe method.

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“…Microextrusion-based cell printing has the drawbacks of low printing resolution as well as the side effect of flow-induced shear stress on cell viability [9][10][11] . Electrohydrodynamic jetting or printing recently attracts extensive attentions in fabricating highresolution features based on the principle of elec tro hydro dy namically induced material flows [12][13][14][15][16][17][18] . Several process parameters had been investigated to achieve stable electrohydrodynamic printing process, such as applied voltage, moving speed, feeding rate of materials and inter diameter of nozzle [19][20][21][22][23][24][25][26] .…”

Section: Introductionmentioning

confidence: 99%

Coaxial nozzle-assisted electrohydrodynamic printing for microscale 3D cell-laden constructs

Liang¹,

He²,

Chang³

et al. 1970

IJB

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Cell printing has found wide applications in biomedical fields due to its unique capability in fabricating living tissue constructs with precise control over cell arrangements. However, it is still challenging to print cell-laden 3D structures simultaneously with high resolution and high cell viability. Here a coaxial nozzle-assisted electrohydrodynamic cell printing strategy was developed to fabricate living 3D cell-laden constructs. Critical process parameters such as feeding rate and stage moving speed were evaluated to achieve smaller hydrogel filaments. The effect of CaCl 2 feeding rate on the printing of 3D alginate hydrogel constructs was also investigated. The results indicated that the presented strategy can print 3D hydrogel structures with relatively uniform filament dimension (about 80 μm) and cell distribution. The viability of the encapsulated cells was over 90%. We envision that the coaxial nozzle-assisted electrohydrodynamic printing will become a promising cell printing strategy to advance biomedical innovations. Keywords: electrohydrodynamic printing; cell printing; bioprinting; biofabrication; tissue engineering

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The Emerging Frontiers and Applications of High-Resolution 3D Printing

Cited by 161 publications

References 115 publications

Fabrication of 3D conjugated polymer structures via vat polymerization additive manufacturing

Fabrication of 3D conjugated polymer structures via vat polymerization additive manufacturing

Experimental Analysis of Electrical Conductivity of the 3D Printed Graphene

Coaxial nozzle-assisted electrohydrodynamic printing for microscale 3D cell-laden constructs

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