3D printed microfluidic circuitry via multijet-based additive manufacturing.

The miniaturization of integrated fluidic processors affords extensive benefits for chemical and biological fields, yet traditional, monolithic methods of microfabrication present numerous obstacles for the scaling of fluidic operators. Recently, researchers have investigated the use of additive manufacturing or "three-dimensional (3D) printing" technologies - predominantly stereolithography - as a promising alternative for the construction of submillimeter-scale fluidic components. One challenge, however, is that current stereolithography methods lack the ability to simultaneously print sacrificial support materials, which limits the geometric versatility of such approaches. In this work, we investigate the use of multijet modelling (alternatively, polyjet printing) - a layer-by-layer, multi-material inkjetting process - for 3D printing geometrically complex, yet functionally advantageous fluidic components comprised of both static and dynamic physical elements. We examine a fundamental class of 3D printed microfluidic operators, including fluidic capacitors, fluidic diodes, and fluidic transistors. In addition, we evaluate the potential to advance on-chip automation of integrated fluidic systems via geometric modification of component parameters. Theoretical and experimental results for 3D fluidic capacitors demonstrated that transitioning from planar to non-planar diaphragm architectures improved component performance. Flow rectification experiments for 3D printed fluidic diodes revealed a diodicity of 80.6 ± 1.8. Geometry-based gain enhancement for 3D printed fluidic transistors yielded pressure gain of 3.01 ± 0.78. Consistent with additional additive manufacturing methodologies, the use of digitally-transferrable 3D models of fluidic components combined with commercially-available 3D printers could extend the fluidic routing capabilities presented here to researchers in fields beyond the core engineering community.

[1]  Donald Wlodkowic,et al.  Three-dimensional printed millifluidic devices for zebrafish embryo tests. , 2015, Biomicrofluidics.

[2]  J. Lewis,et al.  Omnidirectional Printing of 3D Microvascular Networks , 2011, Advanced materials.

[3]  Liwei Lin,et al.  Finger-powered microfluidic systems using multilayer soft lithography and injection molding processes. , 2014, Lab on a chip.

[4]  Rafał Walczak,et al.  Inkjet 3D printing of microfluidic structures—on the selection of the printer towards printing your own microfluidic chips , 2015 .

[5]  J. Lewis,et al.  Chaotic mixing in three-dimensional microvascular networks fabricated by direct-write assembly , 2003, Nature materials.

[6]  Dino Di Carlo,et al.  Research highlights: printing the future of microfabrication. , 2014, Lab on a chip.

[7]  Brendon M. Baker,et al.  Rapid casting of patterned vascular networks for perfusable engineered 3D tissues , 2012, Nature materials.

[8]  Sang Hoon Lee,et al.  Automatic aligning and bonding system of PDMS layer for the fabrication of 3D microfluidic channels , 2005 .

[9]  Daniel C Leslie,et al.  Frequency-specific flow control in microfluidic circuits with passive elastomeric features , 2009 .

[10]  A. Woolley,et al.  3D printed microfluidic devices with integrated valves. , 2015, Biomicrofluidics.

[11]  G. Whitesides The origins and the future of microfluidics , 2006, Nature.

[12]  D. Diamond,et al.  Advances in three-dimensional rapid prototyping of microfluidic devices for biological applications. , 2014, Biomicrofluidics.

[13]  D. Beebe,et al.  The present and future role of microfluidics in biomedical research , 2014, Nature.

[14]  Anthony Atala,et al.  3D bioprinting of tissues and organs , 2014, Nature Biotechnology.

[15]  Liwei Lin,et al.  Unidirectional mechanical cellular stimuli via micropost array gradients , 2011 .

[16]  B. Mosadegh,et al.  Integrated Elastomeric Components for Autonomous Regulation of Sequential and Oscillatory Flow Switching in Microfluidic Devices , 2010, Nature physics.

[17]  Aliaa I. Shallan,et al.  Cost-effective three-dimensional printing of visibly transparent microchips within minutes. , 2014, Analytical chemistry.

[18]  B. Mosadegh,et al.  Uniform cell seeding and generation of overlapping gradient profiles in a multiplexed microchamber device with normally-closed valves. , 2010, Lab on a Chip.

[19]  D. Ingber,et al.  Microfluidic organs-on-chips , 2014, Nature Biotechnology.

[20]  Albert Folch,et al.  Mail-order microfluidics: evaluation of stereolithography for the production of microfluidic devices. , 2014, Lab on a chip.

[21]  Brian Derby,et al.  Printing and Prototyping of Tissues and Scaffolds , 2012, Science.

[22]  Liwei Lin,et al.  Dual-mode hydrodynamic railing and arraying of microparticles for multi-stage signal detection in continuous flow biochemical microprocessors. , 2014, Lab on a chip.

[23]  G. Whitesides,et al.  Rapid Prototyping of Microfluidic Systems in Poly(dimethylsiloxane). , 1998, Analytical chemistry.

[24]  Shuichi Takayama,et al.  Next-generation integrated microfluidic circuits. , 2011, Lab on a chip.

[25]  S. Quake,et al.  Monolithic microfabricated valves and pumps by multilayer soft lithography. , 2000, Science.

[26]  S. Quake,et al.  Multistep Synthesis of a Radiolabeled Imaging Probe Using Integrated Microfluidics , 2005, Science.

[27]  Albert Folch,et al.  3D-printed microfluidic automation. , 2015, Lab on a chip.

[28]  S. Quake,et al.  Long-Term Monitoring of Bacteria Undergoing Programmed Population Control in a Microchemostat , 2005, Science.

[29]  Liwei Lin,et al.  Continuous flow multi-stage microfluidic reactors via hydrodynamic microparticle railing. , 2012, Lab on a chip.

[30]  Seok Jae Lee,et al.  3D printed modules for integrated microfluidic devices , 2014 .

[31]  Mark Horowitz,et al.  Static control logic for microfluidic devices using pressure-gain valves , 2010 .

[32]  Philip N Duncan,et al.  Semi-autonomous liquid handling via on-chip pneumatic digital logic. , 2012, Lab on a chip.