Cell patterning with a heptagon acoustic tweezer--application in neurite guidance.

Accurate control over positioning of cells is a highly desirable feature in tissue engineering applications since it allows, for example, population of substrates in a controlled fashion, rather than relying on random seeding. Current methods to achieve a differential distribution of cells mostly use passive patterning methods to change chemical, mechanical or topographic properties of surfaces, making areas differentially permissive to the adhesion of cells. However, these methods have no ad hoc control over the actual deposition of cells. Direct patterning methods like bioprinting offer good control over cell position, but require sophisticated instrumentation and are often cost- and time-intensive. Here, we present a novel electronically controlled method of generating dynamic cell patterns by acoustic trapping of cells at a user-determined position, with a heptagonal acoustic tweezer device. We demonstrate the capability of the device to create complex patterns of cells using the device's ability to re-position acoustic traps by using a phase shift in the acoustic wave, and by switching the configuration of active piezoelectric transducers. Furthermore, we show that by arranging Schwann cells from neonatal rats in a linear pattern we are able to create Bands of Büngner-like structures on a non-structured surface and demonstrate that these features are able to guide neurite outgrowth from neonatal rat dorsal root ganglia.

[1]  Xiang Peng,et al.  Laser-guided cell micropatterning system. , 2011, The Review of scientific instruments.

[2]  F. N. van de Vosse,et al.  Experimental investigation of collagen waviness and orientation in the arterial adventitia using confocal laser scanning microscopy , 2011, Biomechanics and Modeling in Mechanobiology.

[3]  W. Thompson,et al.  Schwann cell processes guide regeneration of peripheral axons , 1995, Neuron.

[4]  S. Mallapragada,et al.  Micropatterned Schwann cell-seeded biodegradable polymer substrates significantly enhance neurite alignment and outgrowth. , 2001, Tissue engineering.

[5]  R. Midha,et al.  Advances in Nerve Repair , 2012, Current Neurology and Neuroscience Reports.

[6]  J. Weisel,et al.  Binding strength and activation state of single fibrinogen-integrin pairs on living cells , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[7]  J. Jansen,et al.  Dynamic cell adhesion and migration on nanoscale grooved substrates. , 2012, European cells & materials.

[8]  Y. Nahmias,et al.  Laser-guided direct writing for three-dimensional tissue engineering. , 2005, Biotechnology and bioengineering.

[9]  Giuseppe Gigli,et al.  Mechanical Gradient Cues for Guided Cell Motility and Control of Cell Behavior on Uniform Substrates , 2009 .

[10]  Christopher S. Chen,et al.  Simple approach to micropattern cells on common culture substrates by tuning substrate wettability. , 2004, Tissue engineering.

[11]  A. Lloyd,et al.  EphB Signaling Directs Peripheral Nerve Regeneration through Sox2-Dependent Schwann Cell Sorting , 2010, Cell.

[12]  T. Boland,et al.  Inkjet printing of viable mammalian cells. , 2005, Biomaterials.

[13]  T. Okano,et al.  Novel patterned cell coculture utilizing thermally responsive grafted polymer surfaces. , 2001, Journal of biomedical materials research.

[14]  Ronald Deumens,et al.  Repairing injured peripheral nerves: Bridging the gap , 2010, Progress in Neurobiology.

[15]  J A Barron,et al.  Biological Laser Printing: A Novel Technique for Creating Heterogeneous 3-dimensional Cell Patterns , 2004, Biomedical microdevices.

[16]  A. L. Bernassau,et al.  Direct patterning of mammalian cells in an ultrasonic heptagon stencil , 2012, Biomedical microdevices.

[17]  Diane Dalecki,et al.  Controlling the spatial organization of cells and extracellular matrix proteins in engineered tissues using ultrasound standing wave fields. , 2010, Ultrasound in medicine & biology.

[18]  H M Buettner,et al.  Schwann cell response to micropatterned laminin surfaces. , 2001, Tissue engineering.

[19]  H. Buettner,et al.  Oriented Schwann Cell Monolayers for Directed Neurite Outgrowth , 2004, Annals of Biomedical Engineering.

[20]  Robert Langer,et al.  Principles of tissue engineering , 2014 .

[21]  H. Davies,et al.  Engineered neural tissue for peripheral nerve repair. , 2013, Biomaterials.

[22]  B. Schlosshauer,et al.  Strategies for inducing the formation of bands of Büngner in peripheral nerve regeneration. , 2009, Biomaterials.

[23]  Daniel I. C. Wang,et al.  Engineering cell shape and function. , 1994, Science.

[24]  Ingo Heschel,et al.  In vitro cell alignment obtained with a Schwann cell enriched microstructured nerve guide with longitudinal guidance channels. , 2009, Biomaterials.

[25]  Daniel Ahmed,et al.  Acoustic tweezers: patterning cells and microparticles using standing surface acoustic waves (SSAW). , 2009, Lab on a chip.

[26]  M. Dembo,et al.  Cell movement is guided by the rigidity of the substrate. , 2000, Biophysical journal.

[27]  S. Hall The Biology of Chronically Denervated Schwann Cells , 1999, Annals of the New York Academy of Sciences.

[28]  J. Voldman Electrical forces for microscale cell manipulation. , 2006, Annual review of biomedical engineering.

[29]  C. S. Chen,et al.  Geometric control of cell life and death. , 1997, Science.

[30]  Takehisa Matsuda,et al.  Photocontrol of Cell Adhesion and Proliferation by a Photoinduced Cationic Polymer Surface¶ , 2003, Photochemistry and photobiology.

[31]  Zhuojing Luo,et al.  Schwann cell-seeded scaffold with longitudinally oriented micro-channels for reconstruction of sciatic nerve in rats , 2013, Journal of Materials Science: Materials in Medicine.

[32]  A. L. Bernassau,et al.  Two-dimensional manipulation of micro particles by acoustic radiation pressure in a heptagon cell , 2011, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[33]  D. Cumming,et al.  Controlling acoustic streaming in an ultrasonic heptagonal tweezers with application to cell manipulation. , 2014, Ultrasonics.

[34]  M. Mrksich,et al.  Using electroactive substrates to pattern the attachment of two different cell populations , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[35]  Tomoyuki Yasukawa,et al.  Negative dielectrophoretic patterning with different cell types. , 2008, Biosensors & bioelectronics.

[36]  Tomaso Zambelli,et al.  Rapid and Serial Quantification of Adhesion Forces of Yeast and Mammalian Cells , 2012, PloS one.

[37]  T Gordon,et al.  Contributing factors to poor functional recovery after delayed nerve repair: prolonged denervation , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[38]  C. Wilkinson,et al.  A biodegradable and biocompatible regular nanopattern for large-scale selective cell growth. , 2010, Small.

[39]  E. Benes,et al.  A study of the spatial organisation of microbial cells in a gel matrix subjected to treatment with ultrasound standing waves , 2001, Bioseparation.

[40]  James B Phillips,et al.  Neural tissue engineering: a self-organizing collagen guidance conduit. , 2005, Tissue engineering.

[41]  Micropatterned polymer substrates control alignment of proliferating Schwann cells to direct neuronal regeneration , 2005 .

[42]  U. Windhorst,et al.  Comprar Encyclopedia of Neuroscience | Binder, Marc D. | 9783540237358 | Springer , 2009 .

[43]  B. Fuss,et al.  Electric field-induced astrocyte alignment directs neurite outgrowth. , 2006, Neuron glia biology.

[44]  M. Bunge,et al.  Actin Plays a Role in Both Changes in Cell Shape and Gene- Expression Associated with Schwann Cell Myelination , 1997, The Journal of Neuroscience.

[45]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[46]  Nicolas Blondiaux,et al.  Use of force spectroscopy to investigate the adhesion of living adherent cells. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[47]  G. Whitesides,et al.  Patterned deposition of cells and proteins onto surfaces by using three-dimensional microfluidic systems. , 2000, Proceedings of the National Academy of Sciences of the United States of America.