3D Microfabrication using Stimuli-Responsive Self-Folding Polymer Films

References

• Leong , T. G. , Zarafshar , A. M. and Gracias , D. H. 2010 . Three-Dimensional Fabrication at Small Size Scales, . Small , 6 ( 7 ) : 792 – 806 .
   PubMedGoogle Scholar
• Whitesides , G. M. and Grzybowski , B. 2002 . Self-Assembly at All Scales, . Science , 295 ( 5564 ) : 2418 – 2421 .
   PubMed Web of Science ®Google Scholar
• Harrington , M. J. , Razghandi , K. , Ditsch , F. , Guiducci , L. , Rueggeberg , M. , Dunlop , J. W.C. , Fratzl , P. , Neinhuis , C. and Burgert , I. 2011 . Origami-like unfolding of hydro-actuated ice plant seed capsules, . Nat. Commun. , 2 : 337
   PubMedGoogle Scholar
• Burgert , I. and Fratzl , P. 2009 . Actuation systems in plants as prototypes for bioinspired devices, . Philos. T. R. Soc. A. , 367 ( 1893 ) : 1541 – 1557 .
   Google Scholar
• Fratzl , P. and Barth , F. G. 2009 . Biomaterial systems for mechanosensing and actuation, . Nature , 462 ( 7272 ) : 442 – 448 .
   PubMed Web of Science ®Google Scholar
• Elbaum , R. , Zaltzman , L. , Burgert , I. and Fratzl , P. 2007 . The role of wheat awns in the seed dispersal unit, . Science , 316 ( 5826 ) : 884 – 886 .
   PubMed Web of Science ®Google Scholar
• Reyssat , E. and Mahadevan , L. 2009 . Hygromorphs: from pine cones to biomimetic bilayers, . J. R. Soc. Interface. , 6 ( 39 ) : 951 – 957 .
   PubMed Web of Science ®Google Scholar
• Ionov , L. 2010 . Actively-moving materials based on stimuli-responsive polymers, . J. Mater. Chem. , 20 ( 17 ) : 3382 – 3390 .
   Google Scholar
• Tokarev , I. and Minko , S. 2009 . Stimuli-responsive hydrogel thin films, . Soft. Matter. , 5 ( 3 ) : 511 – 524 .
   Web of Science ®Google Scholar
• Qiu , Y. and Park , K. 2001 . Environment-sensitive hydrogels for drug delivery, . Adv. Drug. Deliver. Rev. , 53 ( 3 ) : 321 – 339 .
   PubMed Web of Science ®Google Scholar
• Ionov , L. 2011 . Soft microorigami: self-folding polymer films, . Soft. Matter. , 7 : 6786 – 6791 .
   Web of Science ®Google Scholar
• Yang , S. , Khare , K. and Lin , P. C. 2010 . Harnessing Surface Wrinkle Patterns in Soft Matter, . Adv. Funct. Mater. , 20 ( 16 ) : 2550 – 2564 .
   Web of Science ®Google Scholar
• Hendricks , T. R. , Wang , W. and Lee , I. 2010 . Buckling in nanomechanical films, . Soft. Matter. , 6 ( 16 ) : 3701 – 3706 .
   Google Scholar
• Chen , X. and Yin , J. 2010 . Buckling patterns of thin films on curved compliant substrates with applications to morphogenesis and three-dimensional micro-fabrication, . Soft. Matter. , 6 ( 22 ) : 5667 – 5680 .
   Google Scholar
• Schweikart , A. , Pazos-Perez , N. , Alvarez-Puebla , R. A. and Fery , A. 2011 . Controlling inter-nanoparticle coupling by wrinkle-assisted assembly, . Soft. Matter. , 7 ( 9 ) : 4093 – 4100 .
   Google Scholar
• Schweikart , A. and Fery , A. 2009 . Controlled wrinkling as a novel method for the fabrication of patterned surfaces, . Microchim. Acta. , 165 ( 3–4 ) : 249 – 263 .
   Google Scholar
• Huang , G. and Mei , Y. 2012 . Thinning and Shaping Solid Films into Functional and Integrative Nanomembranes, . Adv. Mater. , 24 ( 19 ) : 2517 – 2546 .
   PubMedGoogle Scholar
• Cendula , P. , Kiravittaya , S. , Monch , I. , Schumann , J. and Schmidt , O. G. 2011 . Directional Roll-up of Nanomembranes Mediated by Wrinkling, . Nano. Lett. , 11 ( 1 ) : 236 – 240 .
   PubMedGoogle Scholar
• Genzer , J. and Groenewold , J. 2006 . Soft matter with hard skin: From skin wrinkles to templating and material characterization, . Soft. Matter. , 2 ( 4 ) : 310 – 323 .
   Google Scholar
• Stuart , M. A.C. , Huck , W. T.S. , Genzer , J. , Muller , M. , Ober , C. , Stamm , M. , Sukhorukov , G. B. , Szleifer , I. , Tsukruk , V. V. , Urban , M. , Winnik , F. , Zauscher , S. , Luzinov , I. and Minko , S. 2010 . Emerging applications of stimuli-responsive polymer materials, . Nat. Mater. , 9 ( 2 ) : 101 – 113 .
   PubMed Web of Science ®Google Scholar
• Sidorenko , A. , Krupenkin , T. , Taylor , A. , Fratzl , P. and Aizenberg , J. 2007 . Reversible switching of hydrogel-actuated nanostructures into complex micropatterns, . Science , 315 ( 5811 ) : 487 – 490 .
   PubMed Web of Science ®Google Scholar
• Zarzar , L. D. , Kim , P. and Aizenberg , J. 2011 . Bio-inspired Design of Submerged Hydrogel-Actuated Polymer Microstructures Operating in Response to pH, . Adv. Mater. , 23 ( 12 ) : 1442 – 1446 .
   PubMedGoogle Scholar
• Schweikart , A. , Horn , A. , Boker , A. and Fery , A. 2010 . Controlled Wrinkling as a Novel Method for the Fabrication of Patterned Surfaces, . Adv. Polym. Sci. , 227 : 75 – 99 .
   Google Scholar
• Huang , J. , Juszkiewicz , M. , de Jeu , W. H. , Cerda , E. , Emrick , T. , Menon , N. and Russell , T. P. 2007 . Capillary wrinkling of floating thin polymer films, . Science , 317 ( 5838 ) : 650 – 653 .
   PubMedGoogle Scholar
• Singamaneni , S. , McConney , M. E. and Tsukruk , V. V. 2010 . Spontaneous Self-Folding in Confined Ultrathin Polymer Gels, . Adv. Mater. , 22 ( 11 ) : 1263 – 1268 .
   PubMedGoogle Scholar
• Horn , A. , Schoberth , H. G. , Hiltl , S. , Chiche , A. , Wang , Q. , Schweikart , A. , Fery , A. and Boker , A. 2009 . Nanostructured wrinkled surfaces for templating bionanoparticles-controlling and quantifying the degree of order, . Faraday Discussions , 143 : 143 – 150 .
   PubMedGoogle Scholar
• Kwon , G. H. , Choi , Y. Y. , Park , J. Y. , Woo , D. H. , Lee , K. B. , Kim , J. H. and Lee , S.-H. 2010 . Electrically-driven hydrogel actuators in microfluidic channels: fabrication, characterization, and biological application, . Lab. Chip. , 10 ( 12 ) : 1604 – 1610 .
   PubMedGoogle Scholar
• Ohm , C. , Brehmer , M. and Zentel , R. 2010 . Liquid Crystalline Elastomers as Actuators and Sensors, . Adv. Mater. , 22 ( 31 ) : 3366 – 3387 .
   PubMed Web of Science ®Google Scholar
• Klein , Y. , Efrati , E. and Sharon , E. 2007 . Shaping of Elastic Sheets by Prescription of Non-Euclidean Metrics, . Science , 315 ( 5815 ) : 1116 – 1120 .
   PubMedGoogle Scholar
• Zhou , F. , Biesheuvel , P. M. , Chol , E. Y. , Shu , W. , Poetes , R. , Steiner , U. and Huck , W. T.S. 2008 . Polyelectrolyte brush amplified electroactuation of microcantilevers, . Nano. Lett. , 8 ( 2 ) : 725 – 730 .
   PubMedGoogle Scholar
• Py , C. , Reverdy , P. , Doppler , L. , Bico , J. , eacute; Roman , B. and icirc; Baroud , C. N. 2007 . Capillary Origami: Spontaneous Wrapping of a Droplet with an Elastic Sheet, . Phys. Rev. Lett. , 98 ( 15 ) : 156103
   PubMedGoogle Scholar
• Luchnikov , V. , Sydorenko , O. and Stamm , M. 2005 . Self-rolled polymer and composite polymer/metal micro- and nanotubes with patterned inner walls, . Adv. Mater. , 17 ( 9 ) : 1177 – 1182 .
   Google Scholar
• Zakharchenko , S. , Puretskiy , N. , Stoychev , G. , Stamm , M. and Ionov , L. 2010 . Temperature controlled encapsulation and release using partially biodegradable thermo-magneto-sensitive self-rolling tubes, . Soft. Matter. , 6 ( 12 ) : 2633 – 2636 .
   Google Scholar
• Smela , E. , Inganas , O. and Lundstrom , I. 1995 . Controlled Folding of Micrometer-Size Structures, . Science , 268 ( 5218 ) : 1735 – 1738 .
   PubMedGoogle Scholar
• Gracias , D. H. , Kavthekar , V. , Love , J. C. , Paul , K. E. and Whitesides , G. M. 2002 . Fabrication of Micrometer-Scale, Patterned Polyhedra by Self-Assembly, . Adv. Mater. , 14 ( 3 ) : 235 – 238 .
   Google Scholar
• Kim , J. , Hanna , J. A. , Byun , M. , Santangelo , C. D. and Hayward , R. C. 2012 . Designing Responsive Buckled Surfaces by Halftone Gel Lithography, . Science , 335 ( 6073 ) : 1201 – 1205 .
   PubMed Web of Science ®Google Scholar
• Stoychev , G. , Zakharchenko , S. , Turcaud , S. , Dunlop , J. W.C. and Ionov , L. 2012 . Shape programmed folding of stimuli-responsive polymer bilayers ACS Nano . 6 ( 5 ) : 3925 – 3934 .
   Google Scholar
• Timoshenko , S. 1925 . Analysis of bi-metal thermostats, . J. Opt. Soc. Am. Rev. Sci. Instrum. , 11 ( 3 ) : 233 – 255 .
   Google Scholar
• Mansfield , E. H. 1962 . Bending, buckling and curling of a heated thin plate, . Proc. R. Soc. A. , 268 ( 1334 ) : 316 – 237 .
   Google Scholar
• Mansfield , E. H. 1965 . Bending buckling and curling of a heated elliptical plate, . Proc. R. Soc. A. , 288 ( 1414 ) : 396 – 417 .
   Google Scholar
• Freund , L. B. 2000 . Substrate curvature due to thin film mismatch strain in the nonlinear deformation range, . J. Mech. Phys. Solids. , 48 ( 6-7 ) : 1159 – 1174 .
   Google Scholar
• Alben , S. , Balakrisnan , B. and Smela , E. 2011 . Edge Effects Determine the Direction of Bilayer Bending, . Nano. Lett. , 11 ( 6 ) : 2280 – 2285 .
   PubMedGoogle Scholar
• Chun , I. S. , Challa , A. , Derickson , B. , Hsia , K. J. and Li , X. 2010 . Geometry Effect on the Strain-Induced Self-Rolling of Semiconductor Membranes, . Nano. Lett. , 10 ( 10 ) : 3927 – 3932 .
   PubMedGoogle Scholar
• Stoychev , G. , Turcaud , S. , Dunlop , J. W.C. and Ionov , L. Hierarchical multi-step folding of polymer bilayers Adv, . Funct. Mater. , 10.1002/adfm.201203245
   Google Scholar
• Kim , J. , Hanna , J. A. , Hayward , R. C. and Santangelo , C. D. 2012 . Thermally responsive rolling of thin gel strips with discrete variations in swelling, . Soft. Matter. , 8 ( 8 ) : 2375 – 2381 .
   Google Scholar
• Serak , S. , Tabiryan , N. , Vergara , R. , White , T. J. , Vaia , R. A. and Bunning , T. J. 2010 . Liquid crystalline polymer cantilever oscillators fueled by light, . Soft. Matter. , 6 ( 4 ) : 779 – 783 .
   Google Scholar
• Kalaitzidou , K. and Crosby , A. J. 2008 . Adaptive polymer particles, . Appl. Phys. Lett. , 93 ( 4 ) : 041910
   Google Scholar
• Simpson , B. , Nunnery , G. , Tannenbaum , R. and Kalaitzidou , K. 2010 . Capture/release ability of thermo-responsive polymer particles, . J. Mater. Chem. , 20 ( 17 ) : 3496 – 3501 .
   Google Scholar
• He , H. Y. , Guan , J. J. and Lee , J. L. 2006 . An oral delivery device based on self-folding hydrogels, . J. Control. Release. , 110 ( 2 ) : 339 – 346 .
   PubMed Web of Science ®Google Scholar
• Guan , J. J. , He , H. Y. , Lee , L. J. and Hansford , D. J. 2007 . Fabrication of particulate reservoir-containing, capsulelike, and self-folding polymer microstructures for drug delivery, . Small , 3 ( 3 ) : 412 – 418 .
   PubMedGoogle Scholar
• Guan , J. J. , He , H. Y. , Hansford , D. J. and Lee , L. J. 2005 . Self-folding of three-dimensional hydrogel microstructures, . J. Phys. Chem. B. , 109 ( 49 ) : 23134 – 23137 .
   PubMedGoogle Scholar
• Stoychev , G. , Puretskiy , N. and Ionov , L. 2011 . Self-folding all-polymer thermoresponsive microcapsules, . Soft. Matter. , 7 : 3277 – 3279 .
   Web of Science ®Google Scholar
• Jeong , K.-U. , Jang , J.-H. , Kim , D.-Y. , Nah , C. , Lee , J. H. , Lee , M.-H. , Sun , H.-J. , Wang , C.-L. , Cheng , S. Z.D. and Thomas , E. L. 2011 . Three-dimensional actuators transformed from the programmed two-dimensional structures via bending, twisting and folding mechanisms, . J. Mater. Chem. , 21 : 6824 – 6830 .
   Google Scholar
• Azam , A. , Laflin , K. E. , Jamal , M. , Fernandes , R. and Gracias , D. H. 2011 . Self-folding micropatterned polymeric containers, . Biomed. Microdevices , 13 ( 1 ) : 51 – 58 .
   PubMed Web of Science ®Google Scholar
• Bassik , N. , Abebe , B. T. , Laflin , K. E. and Gracias , D. H. 2010 . Photolithographically patterned smart hydrogel based bilayer actuators, . Polymer , 51 ( 26 ) : 6093 – 6098 .
   Google Scholar
• Kelby , T. S. , Wang , M. and Huck , W. T.S. 2011 . Controlled Folding of 2D Au–Polymer Brush Composites into 3D Microstructures, . Adv. Funct. Mater. , 21 ( 4 ) : 652 – 657 .
   Google Scholar
• Laflin , K. E. , Morris , C. J. , Muqeem , T. and Gracias , D. H. 2012 . Laser triggered sequential folding of microstructures, . Appl. Phys. Lett. , 101 ( 13 ) : 131901
   Google Scholar
• Bassik , N. , Brafman , A. , Zarafshar , A. M. , Jamal , M. , Luvsanjav , D. , Selaru , F. M. and Gracias , D. H. 2010 . Enzymatically Triggered Actuation of Miniaturized Tools, . J. Am. Chem. Soc. , 132 ( 46 ) : 16314 – 16317 .
   PubMedGoogle Scholar
• Liang , H. Y. and Mahadevan , L. 2011 . Growth, geometry, and mechanics of a blooming lily, . Proc. Natl. Acad. Sci. U. S. A. , 108 ( 14 ) : 5516 – 5521 .
   PubMedGoogle Scholar
• Liang , H. and Mahadevan , L. 2009 . The shape of a long leaf, . Proc. Natl. Acad. Sci. U. S. A. , 106 ( 52 ) : 22049 – 22054 .
   PubMedGoogle Scholar
• Luchnikov , V. A. , Saito , Y. and Tzanis , L. 2012 . A Novel Fibrous Material Created by Self-Rolling of a Patterned Polymer Thin Film, . Macromol. Rapid. Comm. , 33 ( 16 ) : 1404 – 1408 .
   PubMedGoogle Scholar
• Kumar , K. , Nandan , B. , Luchnikov , V. , Simon , F. , Vyalikh , A. , Scheler , U. and Stamm , M. 2009 . A Novel Approach for the Fabrication of Silica and Silica/Metal Hybrid Microtubes, . Chem. Mat. , 21 ( 18 ) : 4282 – 4287 .
   Google Scholar
• Kumar , K. , Luchnikov , V. , Nandan , B. , Senkovskyy , V. and Stamm , M. 2008 . Formation of self-rolled polymer microtubes studied by combinatorial approach, . Eur. Polym. J. , 44 ( 12 ) : 4115 – 4121 .
   Google Scholar
• Singamaneni , S. , McConney , M. E. and Tsukruk , V. V. 2010 . Swelling-Induced Folding in Confined Nanoscale Responsive Polymer Gels, . ACS. Nano. , 4 ( 4 ) : 2327 – 2337 .
   PubMedGoogle Scholar
• Shim , T. S. , Kim , S.-H. , Heo , C.-J. , Jeon , H. C. and Yang , S.-M. 2012 . Controlled Origami Folding of Hydrogel Bilayers with Sustained Reversibility for Robust Microcarriers, . Angew. Chem. Int. Edit. , 51 ( 6 ) : 1420 – 1423 .
   PubMedGoogle Scholar
• Tanaka , T. , Okayama , M. , Kitayama , Y. , Kagawa , Y. and Okubo , M. 2010 . Preparation of “Mushroom-like” Janus Particles by Site-Selective Surface-Initiated Atom Transfer Radical Polymerization in Aqueous Dispersed Systems, . Langmuir , 26 ( 11 ) : 7843 – 7847 .
   PubMed Web of Science ®Google Scholar
• Leong , T. G. , Benson , B. R. , Call , E. K. and Gracias , D. H. 2008 . Thin Film Stress Driven Self-Folding of Microstructured Containers, . Small , 4 ( 10 ) : 1605 – 1609 .
   PubMed Web of Science ®Google Scholar
• Leong , T. G. , Randall , C. L. , Benson , B. R. , Zarafshar , A. M. and Gracias , D. H. 2008 . Self-loading lithographically structured microcontainers: 3D patterned, mobile microwells, . Lab. Chip. , 8 ( 10 ) : 1621 – 1624 .
   PubMedGoogle Scholar
• Leong , T. G. , Randall , C. L. , Benson , B. R. , Bassik , N. , Stern , G. M. and Gracias , D. H. 2009 . Tetherless thermobiochemically actuated microgrippers, . Proc. Natl. Acad. Sci. U. S. A. , 106 ( 3 ) : 703 – 708 .
   PubMed Web of Science ®Google Scholar
• Behl , M. , Razzaq , M. Y. and Lendlein , A. 2010 . Multifunctional Shape-Memory Polymers, . Adv. Mater. , 22 ( 31 ) : 3388 – 3410 .
   PubMed Web of Science ®Google Scholar
• Zhang , X. , Pint , C. L. , Lee , M. H. , Schubert , B. E. , Jamshidi , A. , Takei , K. , Ko , H. , Gillies , A. , Bardhan , R. , Urban , J. J. , Wu , M. , Fearing , R. and Javey , A. 2011 . Optically- and Thermally-Responsive Programmable Materials Based on Carbon Nanotube-Hydrogel Polymer Composites, . Nano. Lett. , 11 ( 8 ) : 3239 – 3244 .
   PubMed Web of Science ®Google Scholar
• Liu , Y. , Boyles , J. K. , Genzer , J. and Dickey , M. D. 2012 . Self-folding of polymer sheets using local light absorption, . Soft. Matter. , 8 : 1764 – 1769 .
   Web of Science ®Google Scholar
• Jager , E. W.H. , Inganas , O. and Lundstrom , I. 2000 . Microrobots for micrometer-size objects in aqueous media: Potential tools for single-cell manipulation, . Science , 288 ( 5475 ) : 2335 – 2338 .
   PubMed Web of Science ®Google Scholar
• Feinberg , A. W. , Feigel , A. , Shevkoplyas , S. S. , Sheehy , S. , Whitesides , G. M. and Parker , K. K. 2007 . Muscular thin films for building actuators and powering devices, . Science , 317 ( 5843 ) : 1366 – 1370 .
   PubMed Web of Science ®Google Scholar
• Zakharchenko , S. , Sperling , E. and Ionov , L. 2011 . Fully biodegradable self-rolled polymer tubes: a candidate for tissue engineering scaffolds, . Biomacromolecules , 12 ( 6 ) : 2211 – 2215 .
   PubMed Web of Science ®Google Scholar
• Randall , C. L. , Kalinin , Y. V. , Jamal , M. , Shah , A. and Gracias , D. H. 2011 . Self-folding immunoprotective cell encapsulation devices, . Nanomed.-Nanotechnol. , 7 ( 6 ) : 686 – 689 .
   PubMedGoogle Scholar
• Randall , C. L. , Kalinin , Y. V. , Jamal , M. , Manohar , T. and Gracias , D. H. 2011 . Three-dimensional microwell arrays for cell culture, . Lab. Chip. , 11 ( 1 ) : 127 – 131 .
   PubMedGoogle Scholar
• Jamal , M. , Bassik , N. , Cho , J. H. , Randall , C. L. and Gracias , D. H. 2010 . Directed growth of fibroblasts into three dimensional micropatterned geometries via self-assembling scaffolds, . Biomaterials , 31 ( 7 ) : 1683 – 1690 .
   PubMedGoogle Scholar
• Kalinin , Y. V. , Randhawa , J. S. and Gracias , D. H. 2011 . Three-Dimensional Chemical Patterns for Cellular Self-Organization, . Angew. Chem. Int. Edit. , 50 ( 11 ) : 2549 – 2553 .
   PubMedGoogle Scholar
• Pedron , S. , van Lierop , S. , Horstman , P. , Penterman , R. , Broer , D. J. and Peeters , E. 2011 . Stimuli Responsive Delivery Vehicles for Cardiac Microtissue Transplantation, . Adv. Funct. Mater. , 21 ( 9 ) : 1624 – 1630 .
   Web of Science ®Google Scholar
• Yuan , B. , Jin , Y. , Sun , Y. , Wang , D. , Sun , J. , Wang , Z. , Zhang , W. and Jiang , X. 2012 . A Strategy for Depositing Different Types of Cells in Three Dimensions to Mimic Tubular Structures in Tissues, . Adv. Mater. , 24 ( 7 ) : 890 – 896 .
   PubMed Web of Science ®Google Scholar
• Kumar , K. , Nandan , B. , Formanek , P. and Stamm , M. 2011 . Fabrication of carbon microtubes from thin films of supramolecular assemblies via self-rolling approach, . J. Mater. Chem. , 21 ( 29 ) : 10813 – 10817 .
   Google Scholar
• Jamal , M. , Zarafshar , A. M. and Gracias , D. H. 2011 . Differentially photo-crosslinked polymers enable self-assembling microfluidics, . Nat. Commun. , 2 : 527
   PubMedGoogle Scholar