Laser jetting of femto-liter metal droplets for high resolution 3D printed structures

Zenou, Michael; Sa’ar, A.; Kotler, Zvi

doi:10.1038/srep17265

Cited by 96 publications

(79 citation statements)

References 44 publications

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“…Laser-induced transfer, which relies on the energy of an incident laser pulse to transfer a deposit (or variously termed voxel) of material (the donor) from a carrier substrate towards a receiver substrate, encompasses a range of techniques for rapid microfabrication of electronic, photonic and biomedical devices [1][2][3][4][5]. Recent results have shown the lateral shaping of deposits in a dynamic fashion for laser-induced forward transfer (LIFT), via the use of a digital micromirror device (DMD) acting as a spatial light modulator [6,7], hence enabling the rapid prototyping of complex shapes with micron-scale fabrication resolution.…”

Section: Introductionmentioning

confidence: 99%

Laser-induced backward transfer of nanoimprinted polymer elements

et al. 2016

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Femtosecond laser-induced backward transfer of transparent photopolymers is demonstrated in the solid state, assisted by a digital micromirror spatial light modulator for producing shaped deposits. Through use of an absorbing silicon carrier substrate, we have been able to successfully transfer solid-phase material, with lateral dimensions as small as *6 lm. In addition, a carrier of silicon incorporating a photonic waveguide relief structure enables the transfer of imprinted deposits that have been accomplished with surface features exactly complementing those present on the substrate, with an observed minimum feature size of 140 nm.

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Section: Introductionmentioning

confidence: 99%

Laser-induced backward transfer of nanoimprinted polymer elements

et al. 2016

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“…Second, the copper structure serves as a template to precisely define the shape and size of the channel inside the hydrogel tubular networks. Third, the available techniques [39][40][41][42][43][44] to mass-produce 3-D microstructures in copper make our method scalable (however, in this work, we simply used hand-made copper templates for demonstration). Finally, we successfully developed a convenient and cost-efficient method to replace the copper ions with calcium ions to eliminate the potential toxicity that the copper ions may have on cells.…”

Section: Resultsmentioning

confidence: 99%

“…[35][36][37][38] To create branched 3-D tubular structures made of hydrogel, we employed a copper template that could be prepared by reported mass-production strategies [39][40][41] or recent 3-D printing strategies. [42][43][44] We immersed the copper template in alginate, a natural polysaccharide derived from brown sea algae, which has been widely used to fabricate bio-scaffolds in biomedical and biological applications; 19,45-49 then we conducted electrolysis, during which the released copper ions from the template quickly cross-linked the alginate in the solution and formed gel. The reaction was so quick that all the generated Cu 2þ ions were consumed before diffusing away, resulting in a uniform thin layer of hydrogel coating covering the copper template.…”

Section: Introductionmentioning

confidence: 99%

Freestanding 3-D microvascular networks made of alginate hydrogel as a universal tool to create microchannels inside hydrogels

Sun

Liu

et al. 2016

Biomicrofluidics

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The diffusion of molecules such as nutrients and oxygen through densely packed cells is impeded by blockage and consumption by cells, resulting in a limited depth of penetration. This has been a major hurdle to a bulk (3-D) culture. Great efforts have been made to develop methods for generating branched microchannels inside hydrogels to support mass exchange inside a bulk culture. These previous attempts faced a common obstacle: researchers tried to fabricate microchannels with gels already loaded with cells, but the fabrication procedures are often harmful to the embedded cells. Herein, we present a universal strategy to create microchannels in different types of hydrogels, which effectively avoids cell damage. This strategy is based on a freestanding alginate 3-D microvascular network prepared by in-situ generation of copper ions from a sacrificial copper template. This alginate network could be used as implants to create microchannels inside different types of hydrogels. This approach effectively addresses the issue of cell damage during microfabrication and made it possible to create microchannels inside different types of gels. The microvascular network produced with this method is (1) strong enough to allow handling, (2) biocompatible to allow cell culturing, and (3) appropriately permeable to allow diffusion of small molecules, while sufficiently dense to prevent blocking of channels when embedded in different types of gels. In addition, composite microtubules could be prepared by simply pre-loading other materials, e.g., particles and large biomolecules, in the hydrogel. Compared with other potential strategies to fabricate freestanding gel channel networks, our method is more rapid, low-cost and scalable due to parallel processing using an industrially massproducible template. We demonstrated the use of such vascular networks in creating microchannels in different hydrogels and composite gels, as well as with a cell culture in a nutrition gradient based on microfluidic diffusion. In this way, the freestanding hydrogel vascular network we produced is a universal functional unit that can be embedded in different types of hydrogel; users will be able to adopt this strategy to achieve vascular mass exchange in the bulk culture without changing their current protocol. The method is readily implementable to applications in vascular tissue regeneration, drug discovery, 3-D culture, etc. Published by AIP Publishing. [http://dx

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“…Beyond a certain radiant exposure, the irradiation leads to rapid heating, followed by changes in metal film phase due to explosive boiling, and formation of a bubble of the vaporized material . Previous reports on imaging of the ejection process during laser irradiation of gold films suggested that propulsion of the material can be characterized as a fast jetting or protrusion of molten Au with ejection velocities of approximately tens to several hundreds of m/s depending on the radiant exposure used . This implies that a fast directional velocity can be achieved by the jetting molten Au, enabling the injection of the particles through the biofilm.…”

Section: Discussionmentioning

confidence: 99%

“…In order to obtain a uniform damage throughout the entire biofilm, our approach is to utilize the effects of laser pulse interaction with gold films to induce both photothermal and mechanical damage to the surrounding biofilm structure. Pulsed laser interaction on metal thin films has been previously utilized as a means to transfer metallic patterns with controlled dimensions and precise nanostructures . The absorption of the laser energy by the metal film leads to non‐uniform heating and localized melting of the film resulting to its ejection to an adjacent substrate .…”

Section: Introductionmentioning

confidence: 99%

Structural damage of Bacillus subtilis biofilms using pulsed laser interaction with gold thin films

et al. 2016

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There is a huge interest in developing strategies to effectively eliminate biofilms due to their negative impact in both industrial and clinical settings. In this study, structural damage was induced on two day-old B. subtilis biofilms using the interaction of 532 nm pulsed laser with gold thin films. Radiant exposure of 225 mJ/cm induced distinct changes on the surface structure and overall morphology of the matured biofilms after laser irradiation. Moreover, at the radiant exposure used, changes in the colour and viscosity of the biofilm were observed which may indicate a compromised extracellular matrix. Irradiated biofilms in the presence of gold film also showed strong propidium iodide signal which implies an increase in the number of dead bacterial cells after laser treatment. Thus, this laser-based technique is a promising approach in targeting and eradicating matured biofilms attached on surfaces such as medical implants.

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Laser jetting of femto-liter metal droplets for high resolution 3D printed structures

Cited by 96 publications

References 44 publications

Laser-induced backward transfer of nanoimprinted polymer elements

Laser-induced backward transfer of nanoimprinted polymer elements

Freestanding 3-D microvascular networks made of alginate hydrogel as a universal tool to create microchannels inside hydrogels

Structural damage of Bacillus subtilis biofilms using pulsed laser interaction with gold thin films

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