Three-dimensional printing of freeform helical microstructures: a review.

Three-dimensional (3D) printing is a fabrication method that enables creation of structures from digital models. Among the different structures fabricated by 3D printing methods, helical microstructures attracted the attention of the researchers due to their potential in different fields such as MEMS, lab-on-a-chip systems, microelectronics and telecommunications. Here we review different types of 3D printing methods capable of fabricating 3D freeform helical microstructures. The techniques including two more common microfabrication methods (i.e., focused ion beam chemical vapour deposition and microstereolithography) and also five methods based on computer-controlled robotic direct deposition of ink filament (i.e., fused deposition modeling, meniscus-confined electrodeposition, conformal printing on a rotating mandrel, UV-assisted and solvent-cast 3D printings) and their advantages and disadvantages regarding their utilization for the fabrication of helical microstructures are discussed. Focused ion beam chemical vapour deposition and microstereolithography techniques enable the fabrication of very precise shapes with a resolution down to ∼100 nm. However, these techniques may have material constraints (e.g., low viscosity) and/or may need special process conditions (e.g., vacuum chamber) and expensive equipment. The five other techniques based on robotic extrusion of materials through a nozzle are relatively cost-effective, however show lower resolution and less precise features. The popular fused deposition modeling method offers a wide variety of printable materials but the helical microstructures manufactured featured a less precise geometry compared to the other printing methods discussed in this review. The UV-assisted and the solvent-cast 3D printing methods both demonstrated high performance for the printing of 3D freeform structures such as the helix shape. However, the compatible materials used in these methods were limited to UV-curable polymers and polylactic acid (PLA), respectively. Meniscus-confined electrodeposition is a flexible, low cost technique that is capable of fabricating 3D structures both in nano- and microscales including freeform helical microstructures (down to few microns) under room conditions using metals. However, the metals suitable for this technique are limited to those that can be electrochemically deposited with the use of an electrolyte solution. The highest precision on the helix geometry was achieved using the conformal printing on a rotating mandrel. This method offers the lowest shape deformation after printing but requires more tools (e.g., mandrel, motor) and the printed structure must be separated from the mandrel. Helical microstructures made of multifunctional materials (e.g., carbon nanotube nanocomposites, metallic coated polymer template) were used in different technological applications such as strain/load sensors, cell separators and micro-antennas. These innovative 3D microsystems exploiting the unique helix shape demonstrated their potential for better performance and more compact microsystems.

[1]  Jean-Charles Bolomey,et al.  Analysis of Dual-Band Helical Antenna for Diversity on Mobile Phones , 2009, Wirel. Pers. Commun..

[2]  Mohsen A. Jafari,et al.  Processing of advanced electroceramic components by fused deposition technique , 2001 .

[3]  Martin Wegener,et al.  Three‐Dimensional Bi‐Chiral Photonic Crystals , 2009 .

[4]  Robert Puers,et al.  Focused ion beam induced deposition: fabrication of three-dimensional microstructures and Young's modulus of the deposited material , 2000 .

[5]  Qing Yang,et al.  Facile fabrication of true three-dimensional microcoils inside fused silica by a femtosecond laser , 2012, Journal of Micromechanics and Microengineering.

[6]  John A. Rogers,et al.  Omnidirectional Printing of Flexible, Stretchable, and Spanning Silver Microelectrodes , 2009, Science.

[7]  Sheng Liu,et al.  Single-walled carbon nanotube network/poly composite thin film for flow sensor , 2010 .

[8]  Daniel Therriault,et al.  Properties of polylactide inks for solvent-cast printing of three-dimensional freeform microstructures. , 2014, Langmuir : the ACS journal of surfaces and colloids.

[9]  Qinglin Sheng,et al.  A sandwich-type phenolic biosensor based on tyrosinase embedding into single-wall carbon nanotubes and polyaniline nanocomposites , 2013 .

[10]  Koji Ikuta,et al.  A three-dimensional microfabrication system for biodegradable polymers with high resolution and biocompatibility , 2008 .

[11]  Paul Crozat,et al.  Two- and three-dimensional microcoil fabrication process for three-axis magnetic sensors on flexible substrates , 2006 .

[12]  C. Christodoulou,et al.  3-D helical THz antennas , 2000 .

[13]  J. Lewis,et al.  Conformal Printing of Electrically Small Antennas on Three‐Dimensional Surfaces , 2011, Advanced materials.

[14]  Masanori Komuro,et al.  Three-dimensional nanostructure fabrication by focused-ion-beam chemical vapor deposition , 2000 .

[15]  J. Lewis,et al.  Phase behavior and rheological properties of polyelectrolyte inks for direct-write assembly. , 2005, Langmuir : the ACS journal of surfaces and colloids.

[16]  J. Lewis,et al.  Fugitive Inks for Direct‐Write Assembly of Three‐Dimensional Microvascular Networks , 2005 .

[17]  A. Amis,et al.  Rapid prototyping techniques for anatomical modelling in medicine. , 1997, Annals of the Royal College of Surgeons of England.

[18]  Ahmad Safari,et al.  Processing of advanced electroceramic components by fused deposition technique , 2001 .

[19]  Jean-Pierre Kruth,et al.  Composites by rapid prototyping technology , 2010 .

[20]  D. Therriault,et al.  Solvent-cast three-dimensional printing of multifunctional microsystems. , 2013, Small.

[21]  N. Hu,et al.  Tunneling effect in a polymer/carbon nanotube nanocompositestrain sensor , 2008 .

[22]  J. Cesarano,et al.  Directed colloidal assembly of 3D periodic structures , 2002 .

[23]  K. Leong,et al.  Solid freeform fabrication of three-dimensional scaffolds for engineering replacement tissues and organs. , 2003, Biomaterials.

[24]  Mark A. Ganter,et al.  A review of process development steps for new material systems in three dimensional printing (3DP) , 2008 .

[25]  Daniel Therriault,et al.  Ultraviolet‐Assisted Direct‐Write Fabrication of Carbon Nanotube/Polymer Nanocomposite Microcoils , 2010, Advanced materials.

[26]  Caroline Sunyong Lee,et al.  Measurement of anisotropic compressive strength of rapid prototyping parts , 2007 .

[27]  Daniel Therriault,et al.  Processing parameters investigation for the fabrication of self-supported and freeform polymeric microstructures using ultraviolet-assisted three-dimensional printing , 2014 .

[28]  D. Therriault,et al.  Helical Dielectrophoretic Particle Separator Fabricated by Conformal Spindle Printing , 2014 .

[29]  Robert N. Dean,et al.  Novel method for fabricating 3D helical THz antennas directly on semiconductor substrates , 1999, Photonics West.

[30]  J. Lewis,et al.  Microperiodic structures: Direct writing of three-dimensional webs , 2004, Nature.

[31]  Hejun Du,et al.  A 3D paired microelectrode array for accumulation and separation of microparticles , 2006 .

[32]  D Therriault,et al.  Chaotic mixing in three-dimensioned microvascular networks fabricated by direct-write assembly (vol 2, pg 265, 2002) , 2003 .

[33]  M. Kotaki,et al.  A review on polymer nanofibers by electrospinning and their applications in nanocomposites , 2003 .

[34]  Saeid Nahavandi,et al.  Dielectrophoretic-activated cell sorter based on curved microelectrodes , 2010 .

[35]  Lina Zhang,et al.  Preparation of helical fibers from cellulose–cuprammonium solution based on liquid rope coiling , 2014 .

[36]  Paul J. Campagnola,et al.  Submicron Multiphoton Free-Form Fabrication of Proteins and Polymers: Studies of Reaction Efficiencies and Applications in Sustained Release , 2000 .

[37]  Vivek Subramanian,et al.  Progress Toward Development of All-Printed RFID Tags: Materials, Processes, and Devices , 2005, Proceedings of the IEEE.

[38]  Pál Ormos,et al.  Two-photon polymerization with optimized spatial light modulator , 2011 .

[39]  Qing Yang,et al.  Fabrication of three-dimensional helical microchannels with arbitrary length and uniform diameter inside fused silica. , 2012, Optics letters.

[40]  Satoshi Kawata,et al.  Finer features for functional microdevices , 2001, Nature.

[41]  A.R. Djordjevic,et al.  Optimization of Helical antennas [Antenna Designer's Notebook] , 2006, IEEE Antennas and Propagation Magazine.

[42]  Martin Wegener,et al.  3D Bi‐chiral Photonic Crystals: Three‐Dimensional Bi‐Chiral Photonic Crystals (Adv. Mater. 46/2009) , 2009 .

[43]  J. Muth,et al.  3D Printing of Free Standing Liquid Metal Microstructures , 2013, Advanced materials.

[44]  Min-Feng Yu,et al.  Meniscus-Confined Three-Dimensional Electrodeposition for Direct Writing of Wire Bonds , 2010, Science.

[45]  H. Fukunaga,et al.  A carbon nanotube/polymer strain sensor with linear and anti-symmetric piezoresistivity , 2011 .

[46]  Jongbaeg Kim,et al.  Batch-processed carbon nanotube wall as pressure and flow sensor , 2010, Nanotechnology.

[47]  Ian W. Hunter,et al.  Three-dimensional microfabrication by localized electrochemical deposition , 1996 .

[48]  Ryan B. Wicker,et al.  Cure depth control for complex 3D microstructure fabrication in dynamic mask projection microstereolithography , 2009 .

[49]  Yibing Huang,et al.  Role of Helicity on the Anticancer Mechanism of Action of Cationic-Helical Peptides , 2012, International journal of molecular sciences.

[50]  Martin Lévesque,et al.  Direct-write fabrication of freestanding nanocomposite strain sensors , 2012, Nanotechnology.

[51]  Koji Takahashi,et al.  Submicroscale Flow Sensor Employing Suspended Hot Film with Carbon Nanotube Fins , 2010 .

[52]  C. Decker,et al.  Photoinitiated crosslinking polymerisation , 1996 .

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

[54]  D. Mainwaring,et al.  Electromechanical response of semiconducting carbon-polyimide nanocomposite thin films , 2009 .

[55]  Behrokh Khoshnevis,et al.  Automated construction by contour craftingrelated robotics and information technologies , 2004 .