Ultrathin SU-8 membrane for highly efficient tunable cell patterning and massively parallel large biomolecular delivery.

Cell patterning is a powerful technique for the precise control and arrangement of cells, enabling detailed single-cell analysis with broad applications in therapeutics, diagnostics, and regenerative medicine. This study presents a novel and efficient technique that enables massively parallel high throughput cell patterning and precise delivery of small to large biomolecules into patterned cells. The innovative cell patterning device proposed in this study is a standalone, ultrathin 3D SU-8 micro-stencil membrane, with a thickness of 10 μm. It features an array of micro-holes ranging from 40 μm to 80 μm, spaced apart by 50 μm to 150 μm. By culturing cells on top of this SU-8 membrane, the technique achieves highly efficient cell patterns varying from single-cell to cell clusters on a Petri dish. Utilizing this technique, we have achieved a remarkable reproducible patterning efficiency for mouse fibroblast L929 (80.5%), human cervical SiHa (81%), and human neuroblastoma IMR32 (89.6%) with less than 1% defects in undesired areas. Single-cell patterning efficiency was observed to be highest at 75.8% for L929 cells. Additionally, we have demonstrated massively parallel high throughput uniform transfection of large biomolecules into live patterned cells by employing an array of titanium micro-rings (10 μm outer diameter, 3 μm inner diameter) activated through infrared light pulses. Successful delivery of a wide range of small to very large biomolecules, including propidium iodide (PI) dye (668.4 Da), dextran (3 kDa), siRNA (13.3 kDa), and β-galactosidase enzyme (465 kDa), was accomplished in cell patterns for various cancer cells. Notably, our platform achieved exceptional delivery efficiencies of 97% for small molecules like PI dye and 84% for the enzyme, with corresponding high cell viability of 100% and 90%, respectively. Furthermore, the compact and reusable SU-8-based membrane device facilitates highly efficient cell patterning, transfection, and cell viability, making it a promising tool for diagnostics and therapeutic applications.

[1]  M. Mokhtari-Dizaji,et al.  Magnetoporation: New Method for Permeabilization of Cancerous Cells to Hydrophilic Drugs , 2020, Journal of biomedical physics & engineering.

[2]  Fan-Gang Tseng,et al.  Infrared Pulse Laser-Activated Highly Efficient Intracellular Delivery Using Titanium Microdish Device. , 2020, ACS biomaterials science & engineering.

[3]  L. J. Lee,et al.  On-chip multiplexed single-cell patterning and controllable intracellular delivery , 2020, Microsystems & Nanoengineering.

[4]  Zihui Wang,et al.  Single-cell patterning technology for biological applications. , 2019, Biomicrofluidics.

[5]  A. Ivask,et al.  Propidium iodide staining underestimates viability of adherent bacterial cells , 2018, Scientific Reports.

[6]  Nitin Agrawal,et al.  Microstencil-based spatial immobilization of individual cells for single cell analysis. , 2018, Biomicrofluidics.

[7]  Pallavi Shinde,et al.  Single-cell electroporation: current trends, applications and future prospects , 2018, Journal of Micromechanics and Microengineering.

[8]  Pallavi Shinde,et al.  Current Trends of Microfluidic Single-Cell Technologies , 2018, International journal of molecular sciences.

[9]  N. Melosh,et al.  Universal intracellular biomolecule delivery with precise dosage control , 2018, Science Advances.

[10]  Robert Langer,et al.  Intracellular Delivery by Membrane Disruption: Mechanisms, Strategies, and Concepts. , 2018, Chemical reviews.

[11]  Yu Ting Chow,et al.  Liquid Metal‐Based Multifunctional Micropipette for 4D Single Cell Manipulation , 2018, Advanced science.

[12]  Hui Xie,et al.  Magnetically Actuated Peanut Colloid Motors for Cell Manipulation and Patterning. , 2018, ACS nano.

[13]  J. Y. Sim,et al.  Controlling cell shape on hydrogels using lift-off protein patterning , 2018, PloS one.

[14]  Adrian Martinez-Rivas,et al.  Methods of Micropatterning and Manipulation of Cells for Biomedical Applications , 2017, Micromachines.

[15]  W. D. De Vos,et al.  Fast spatial‐selective delivery into live cells , 2017, Journal of controlled release : official journal of the Controlled Release Society.

[16]  Kuan-Wen Tung,et al.  Heavily doped silicon electrode for dielectrophoresis in high conductivity media , 2017 .

[17]  W. Li,et al.  Three-Dimensional Calcium Alginate Hydrogel Assembly via TiOPc-Based Light-Induced Controllable Electrodeposition , 2017, Micromachines.

[18]  Eric Mazur,et al.  Intracellular Delivery Using Nanosecond-Laser Excitation of Large-Area Plasmonic Substrates. , 2017, ACS nano.

[19]  Hongkai Wu,et al.  Fast Single-Cell Patterning for Study of Drug-Induced Phenotypic Alterations of HeLa Cells Using Time-of-Flight Secondary Ion Mass Spectrometry. , 2016, Analytical chemistry.

[20]  M. Cecchini,et al.  Ultrastructural Characterization of the Lower Motor System in a Mouse Model of Krabbe Disease , 2016, Scientific Reports.

[21]  Ting-Hsiang Wu,et al.  Massively parallel delivery of large cargo into mammalian cells with light pulses , 2015, Nature Methods.

[22]  C. Barner‐Kowollik,et al.  Photolithographic Patterning of 3D‐Formed Polycarbonate Films for Targeted Cell Guiding , 2015, Advanced materials.

[23]  Alexis Gautreau,et al.  Quantitative and unbiased analysis of directional persistence in cell migration , 2014, Nature Protocols.

[24]  C T W Moonen,et al.  Understanding ultrasound induced sonoporation: definitions and underlying mechanisms. , 2014, Advanced drug delivery reviews.

[25]  Kevin Braeckmans,et al.  Comparison of gold nanoparticle mediated photoporation: vapor nanobubbles outperform direct heating for delivering macromolecules in live cells. , 2014, ACS nano.

[26]  Wenfeng Liang,et al.  Extracellular-controlled breast cancer cell formation and growth using non-UV patterned hydrogels via optically-induced electrokinetics. , 2014, Lab on a chip.

[27]  Fan-Gang Tseng,et al.  Tuning nano electric field to affect restrictive membrane area on localized single cell nano-electroporation , 2013 .

[28]  Fan-Gang Tseng,et al.  Recent Trends on Micro/Nanofluidic Single Cell Electroporation , 2013, Micromachines.

[29]  V. Castranova,et al.  Multi-walled carbon nanotubes induce human microvascular endothelial cellular effects in an alveolar-capillary co-culture with small airway epithelial cells , 2013, Particle and Fibre Toxicology.

[30]  H. Hioki,et al.  Drug Screening for ALS Using Patient-Specific Induced Pluripotent Stem Cells , 2012, Science Translational Medicine.

[31]  M. Saif,et al.  A Novel Technique for Micro-patterning Proteins and Cells on Polyacrylamide Gels. , 2012, Soft matter.

[32]  P. Sorger,et al.  Sequential Application of Anticancer Drugs Enhances Cell Death by Rewiring Apoptotic Signaling Networks , 2012, Cell.

[33]  M. Balland,et al.  Thermoresponsive Micropatterned Substrates for Single Cell Studies , 2011, PloS one.

[34]  W. Wen,et al.  Patterning cell using Si-stencil for high-throughput assay , 2011 .

[35]  Pak Kin Wong,et al.  Probing cell migration in confined environments by plasma lithography. , 2011, Biomaterials.

[36]  Helene Andersson-Svahn,et al.  Overview of single-cell analyses: microdevices and applications. , 2010, Lab on a chip.

[37]  Shuichi Takayama,et al.  Single cell trapping in larger microwells capable of supporting cell spreading and proliferation , 2010, Microfluidics and nanofluidics.

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

[39]  Xudong Cao,et al.  Patterning multiple cell types in co-cultures: A review , 2009 .

[40]  Manuel Théry,et al.  Simple and rapid process for single cell micro-patterning. , 2009, Lab on a chip.

[41]  Z. Hartman,et al.  Adenovirus vector induced innate immune responses: impact upon efficacy and toxicity in gene therapy and vaccine applications. , 2008, Virus research.

[42]  Hiroyuki Honda,et al.  Cell patterning using magnetite nanoparticles and magnetic force , 2007, Biotechnology and bioengineering.

[43]  G. Whitesides,et al.  Microfabrication meets microbiology , 2007, Nature Reviews Microbiology.

[44]  M. Hersam,et al.  Microscale features and surface chemical functionality patterned by electron beam lithography: a novel route to poly(dimethylsiloxane) (PDMS) stamp fabrication. , 2006, Langmuir : the ACS journal of surfaces and colloids.

[45]  Ming C. Wu,et al.  Massively parallel manipulation of single cells and microparticles using optical images , 2005, Nature.

[46]  Ronald G. Crystal,et al.  Transfer of Genes to Humans: Early Lessons and Obstacles to Success , 1995, Science.

[47]  P. S. Mahapatra,et al.  Single-cell patterning: a new frontier in bioengineering , 2022, Materials Today Chemistry.

[48]  Nanomaterials and Their Biomedical Applications , 2021 .

[49]  Yang Li,et al.  Recent advances in surface manipulation using micro-contact printing for biomedical applications , 2021 .

[50]  Fan-Gang Tseng,et al.  Essentials of Single-Cell Analysis , 2016 .

[51]  H. Bianco-Peled,et al.  Nanostructuring biosynthetic hydrogels for tissue engineering: a cellular and structural analysis. , 2012, Acta biomaterialia.

[52]  D. Miklavčič,et al.  Electroporation in dense cell suspension--theoretical and experimental analysis of ion diffusion and cell permeabilization. , 2007, Biochimica et biophysica acta.

[53]  T. Park,et al.  Integration of Cell Culture and Microfabrication Technology , 2003, Biotechnology progress.