Fluid Bath-Assisted 3D Printing for Biomedical Applications: From Pre- to Postprinting Stages

Hua, Weijian; Mitchell, Kellen; Raymond, Lily; Godina, Beatriz; Zhao, Danyang; Zhou, Wuyi; Jin, Yifei

doi:10.1021/acsbiomaterials.1c00910

Cited by 40 publications

(53 citation statements)

References 117 publications

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“…The nanocomposite recovers its interactive dual microstructure faster than Pluronic F127 but slower than nanoclay with a response time of 0.36 s, which indicates that the interactions between spherical micelles and nanoclay platelets may accelerate the formation of the dual microstructure. For support bath-enabled 3D printing, a short response time is always expected , so that the support bath material can rapidly switch from liquid to solid-like states to fill the crevasse behind the nozzle translation and entrap deposited structures in situ .…”

Section: Resultsmentioning

confidence: 99%

“…As shown in Figure S5a,b, the increase in nozzle diameter and dispensing pressure lead to the increase in filament diameter. In contrast, the increase in path speed, the speed at which the dispensing nozzle moves in the support bath, leads to the decrease in filament diameter, 14,19 as shown in Figure 3a. Also, when the path speed is relatively low, a swelling filament can be formed, which has a diameter larger than the nozzle diameter.…”

Section: Determination Of the Nanoclay And Pluronic F127 Concentratio...mentioning

confidence: 99%

“…Among a variety of support bath materials, − yield-stress fluids − are of great significance, which can switch between liquid and solid-like states under different stressed conditions. The unique advantages that yield-stress fluids offer for support bath-enabled 3D printing include the following: (1) self-healing behavior during printing due to repeatable and rapid transition between liquid and solid-like status, thus eliminating the need for additional fillers; (2) solid-like behavior after printing, which provides excellent in situ supports; and (3) physical and/or chemical stability when prepared with suitable solvents, broadening the application scope of support bath-enabled 3D printing for various fabrication scenarios. ,− As a result, yield-stress support bath-enabled 3D printing presents unimaginable potential in different fields, such as tissue engineering, wearable sensors, , soft robotics, , and more.…”

Section: Introductionmentioning

confidence: 99%

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Three-Dimensional Printing in Stimuli-Responsive Yield-Stress Fluid with an Interactive Dual Microstructure

Hua

Mitchell

Kariyawasam

et al. 2022

ACS Appl. Mater. Interfaces

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Yield-stress support bath-enabled three-dimensional (3D) printing has been widely used in recent years for diverse applications. However, current yield-stress fluids usually possess single microstructures and still face the challenges of on-demand adding and/or removing support bath materials during printing, constraining their application scope. This study aims to propose a concept of stimuli-responsive yield-stress fluids with an interactive dual microstructure as support bath materials. The microstructure from a yield-stress additive allows the fluids to present switchable states at different stresses, facilitating an embedded 3D printing process. The microstructure from stimuli-responsive polymers enables the fluids to have regulable rheological properties upon external stimuli, making it feasible to perfuse additional yield-stress fluids during printing and easily remove residual fluids after printing. A nanoclay-Pluronic F127 nanocomposite is studied as a thermosensitive yield-stress fluid. The key material properties are characterized to unveil the interactions in the formed dual microstructure and microstructure evolutions at different stresses and temperatures. Core scientific issues, including the filament formation principle, surface roughness control, and thermal effects of the newly added nanocomposite, are comprehensively investigated. Finally, three representative 3D structures, the Hall of Prayer, capsule, and tube with changing diameter, are successfully printed to validate the printing capability of stimuli-responsive yield-stress fluids for fabricating arbitrary architectures.

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Section: Resultsmentioning

confidence: 99%

Section: Determination Of the Nanoclay And Pluronic F127 Concentratio...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Three-Dimensional Printing in Stimuli-Responsive Yield-Stress Fluid with an Interactive Dual Microstructure

Hua

Mitchell

Kariyawasam

et al. 2022

ACS Appl. Mater. Interfaces

Self Cite

View full text Add to dashboard Cite

show abstract

“…In this technique, the filaments are deposited directly into a secondary shear-thinning structure that allows self-healing upon nozzle passage [123], restricting the bioink flow and allowing for the fabrication of more complex structures, with different cell types and tunable mechanical proprieties upon crosslinking (figure 4(e)) [4,124]. Recent review papers highlight the emerging solutions to embedded printing and the particular challenges in this area [125,126]. One major requirement is that the supporting bath materials do not interact/mix with the ink materials, allowing deposition with high shape and filament fidelity.…”

Section: Alternative Approaches For 3d Printingmentioning

confidence: 99%

Biomaterials of human source for 3D printing strategies

et al. 2023

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Three-dimensional printing has risen in recent years as a promising approach that fast-tracked the biofabrication of tissue engineering constructs that most resemble utopian tissue/organ replacements for precision medicine. Additionally, by using human-sourced biomaterials engineered towards optimal rheological proprieties of extrudable inks, the best possible scaffolds can be created. These can encompass native structure and function with a low risk of rejection, enhancing overall clinical outcomes; and even be further optimized by engaging in information- and computer-driven design workflows. This paper provides an overview of the current efforts in achieving ink’s necessary rheological and print performance proprieties towards biofabrication from human-derived biomaterials. The most notable step for arranging such characteristics to make biomaterials inks are the employed crosslinking strategies, for which examples are discussed. Lastly, this paper illuminates the state-of-the-art of the most recent literature on already used human-sourced inks; with a final emphasis on future perspectives on the field.

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“…In the work of Roxanne Khalaj et al [ 22 ], coronary stents were manufactured by 3D printing. Weijian Hua et al [ 23 ], showed the 3D printing method to also be a powerful tool for stent manufacturing. Kaitlyn Chua’s work also illustrates how the field of 3D printing and biomedicine can create more innovative devices and products [ 24 ].…”

Section: Introductionmentioning

confidence: 99%

Laser Additive Manufacturing of Anti-Tetrachiral Endovascular Stents with Negative Poisson’s Ratio and Favorable Cytocompatibility

et al. 2022

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Laser additive manufacturing (LAM) of complex-shaped metallic components offers great potential for fabricating customized endovascular stents. In this study, anti-tetrachiral auxetic stents with negative Poisson ratios (NPR) were designed and fabricated via LAM. Poisson’s ratios of models with different diameters of circular node (DCN) were calculated using finite element analysis (FEA). The experimental method was conducted with the LAM-fabricated anti-tetrachiral stents to validate their NPR effect and the simulation results. The results show that, with the increase in DCN from 0.6 to 1.5 mm, the Poisson ratios of anti-tetrachiral stents varied from −1.03 to −1.12, which is in line with the simulation results. The interrelationship between structural parameters of anti-tetrachiral stents, their mechanical properties and biocompatibility was demonstrated. The anti-tetrachiral stents with a DCN of 0.9 mm showed the highest absolute value of negative Poisson’s ratio, combined with good cytocompatibility. The cytocompatibility tests indicate the envisaged cell viability and adhesion of the vascular endothelial cell on the LAM-fabricated anti-tetrachiral auxetic stents. The manufactured stents exhibit great superiority in the application of endovascular stent implantation due to their high flexibility for easy maneuverability during deployment and enough strength for arterial support.

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Fluid Bath-Assisted 3D Printing for Biomedical Applications: From Pre- to Postprinting Stages

Cited by 40 publications

References 117 publications

Three-Dimensional Printing in Stimuli-Responsive Yield-Stress Fluid with an Interactive Dual Microstructure

Three-Dimensional Printing in Stimuli-Responsive Yield-Stress Fluid with an Interactive Dual Microstructure

Biomaterials of human source for 3D printing strategies

Laser Additive Manufacturing of Anti-Tetrachiral Endovascular Stents with Negative Poisson’s Ratio and Favorable Cytocompatibility

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