Application of inkjet printing to tissue engineering

Boland, Thomas; Xu, Tao; Damon, Brook; Cui, Xiaofeng

doi:10.1002/biot.200600081

Cited by 695 publications

(417 citation statements)

References 33 publications

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“…1 It could also set a new era in tissue engineering applications, allowing the construction of artificial organs combining the deposition of cells and biomaterials, in the so called organ printing. 2 Moreover, among others, it could allow the fabrication of miniaturized devices in areas such as biosensing and biochemical analysis, in which miniaturization presents advantages such as lab-ona-chip integration, multianalyte detection, and minimization of sample volumes. 3 In all the previous cases, and especially in those in which biological elements come into play, the demanded printing technologies must assure the functionality of the transferred specimens, and should try to minimize the difficulties that may appear during the printing process, such as contamination.…”

Section: Introductionmentioning

confidence: 99%

Time-resolved imaging of the laser forward transfer of liquids

Duocastella¹,

Fernández-Pradas²,

Morenza³

et al. 2009

Journal of Applied Physics

136

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Time-resolved imaging is carried out to study the dynamics of the laser-induced forward transfer of an aqueous solution at different laser fluences. The transfer mechanisms are elucidated, and directly correlated with the material deposited at the analyzed irradiation conditions. It is found that there exists a fluence range in which regular and well-defined droplets are deposited. In this case, laser pulse energy absorption results in the formation of a plasma, which expansion originates a cavitation bubble in the liquid. After the further expansion and collapse of the bubble, a long and uniform jet is developed, which advances at a constant velocity until it reaches the receptor substrate. On the other hand, for lower fluences no material is deposited. In this case, although a jet can be also generated, it recoils before reaching the substrate. For higher fluences, splashing is observed on the receptor substrate due to the bursting of the cavitation bubble. Finally, a discussion of the possible mechanisms which lead to such singular dynamics is also provided.

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Section: Introductionmentioning

confidence: 99%

Time-resolved imaging of the laser forward transfer of liquids

Duocastella¹,

Fernández-Pradas²,

Morenza³

et al. 2009

Journal of Applied Physics

136

View full text Add to dashboard Cite

show abstract

“…34 Defined droplets can be dispensed with a computer-controlled pump 34 or through inkjet printing. 35,36 For all methods the biomolecule diffuses away from its source into the gel forming a concentration gradient over the cells that evolves in both space and time (Fig. 1c).…”

Section: Biological Hydrogelsmentioning

confidence: 99%

Biomolecular gradients in cell culture systems

2008

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Biomolecule gradients have been shown to play roles in a wide range of biological processes including development, inflammation, wound healing, and cancer metastasis. Elucidation of these phenomena requires the ability to expose cells to biomolecule gradients that are quantifiable, controllable, and mimic those that are present in vivo. Here we review the major biological phenomena in which biomolecule gradients are employed, traditional in vitro gradient-generating methods developed over the past 50 years, and new microfluidic devices for generating gradients. Microfluidic gradient generators offer greater levels of precision, quantitation, and spatiotemporal gradient control than traditional methods, and may greatly enhance our understanding of many biological phenomena. For each method, we outline the salient features, capabilities, and applications.

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“…Inkjet printing has been used for instance to fabricate organic thin film transistors (OTFTs), organic light emitting diodes (OLEDs), solar cells, supercapacitors, sensing devices and biomaterials. [3][4][5][6] Nowadays, it is used in many research laboratories and it is approaching the industrial production level.…”

Section: Introductionmentioning

confidence: 99%

Inkjet Printing Meets Electrochemical Energy Conversion

Lesch

Cortés‐Salazar

Bassetto

et al. 2015

Chimia

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Inkjet printing is a very powerful digital and mask-less microfabrication technique that has attracted the attention of several research groups working on electrochemical energy conversion concepts. In this short review, an overview is given about recent efforts to employ inkjet printing for the search of new electrocatalyst materials and for the preparation of catalyst layers for polymer electrolyte membrane fuel cell applications. Recent approaches of the Laboratory of Physical and Analytical Electrochemistry (LEPA) at the École Polytechnique Fédérale de Lausanne for the inkjet printing of catalyst layers and membrane electrode assemblies are presented and future energy research directions of LEPA based on inkjet printing in the new Energypolis campus in the Canton of Valais are summarized.

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Application of inkjet printing to tissue engineering

Cited by 695 publications

References 33 publications

Time-resolved imaging of the laser forward transfer of liquids

Time-resolved imaging of the laser forward transfer of liquids

Biomolecular gradients in cell culture systems

Inkjet Printing Meets Electrochemical Energy Conversion

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