Isolation of single mammalian cells from adherent cultures by fluidic force microscopy.

The physical separation of individual cells from cell populations for single-cell analysis and proliferation is of wide interest in biology and medicine. Today, single-cell isolation is routinely applied to non-adherent cells, though its application to cells grown on a substrate remains challenging. In this report, a versatile approach for isolating single HeLa cells directly from their culture dish is presented. Fluidic force microscopy is first used to detach the targeted cell(s) via the tunable delivery of trypsin, thereby achieving cellular detachment with single-cell resolution. The cell is then trapped by the microfluidic probe via gentle aspiration, displaced with micrometric precision and either transferred onto a new substrate or deposited into a microwell. An optimised non-fouling coating ensures fully reversible cell capture and the potential for serial isolation of multiple cells with 100% successful transfer rate (n = 130) and a survival rate of greater than 95%. By providing an efficient means for isolating targeted adherent cells, the described approach offers exciting possibilities for biomedical research.

[1]  Sergey S Shevkoplyas,et al.  Biomimetic autoseparation of leukocytes from whole blood in a microfluidic device. , 2005, Analytical chemistry.

[2]  M. Schindler,et al.  Automated analysis and survival selection of anchorage-dependent cells under normal growth conditions. , 1985, Cytometry.

[3]  Yu Sun,et al.  Nanonewton force-controlled manipulation of biological cells using a monolithic MEMS microgripper with two-axis force feedback , 2008 .

[4]  Jiashu Sun,et al.  Simultaneous on-chip DC dielectrophoretic cell separation and quantitative separation performance characterization. , 2012, Analytical chemistry.

[5]  S. Digumarthy,et al.  Isolation of rare circulating tumour cells in cancer patients by microchip technology , 2007, Nature.

[6]  Manoj Kumar,et al.  Fractionation of cell mixtures using acoustic and laminar flow fields. , 2005, Biotechnology and bioengineering.

[7]  F. Bidard,et al.  Microfluidic: an innovative tool for efficient cell sorting. , 2012, Methods.

[8]  Tomaso Zambelli,et al.  FluidFM: combining atomic force microscopy and nanofluidics in a universal liquid delivery system for single cell applications and beyond. , 2009, Nano letters.

[9]  M. Textor,et al.  Optical grating coupler biosensors. , 2002, Biomaterials.

[10]  C. Wallis,et al.  The role of serum and fetuin in the growth of monkey kidney cells in culture. , 1969, Experimental cell research.

[11]  Nancy Allbritton,et al.  Micromolded arrays for separation of adherent cells. , 2010, Lab on a chip.

[12]  T. Graf,et al.  Heterogeneity of embryonic and adult stem cells. , 2008, Cell stem cell.

[13]  Ryosuke Ogaki,et al.  Temperature-induced ultradense PEG polyelectrolyte surface grafting provides effective long-term bioresistance against mammalian cells, serum, and whole blood. , 2012, Biomacromolecules.

[14]  D. D. Mosser,et al.  Use of a micromanipulator for high-efficiency cloning of cells co-expressing fluorescent proteins. , 2000, Methods in cell science : an official journal of the Society for In Vitro Biology.

[15]  S. Bodovitz,et al.  Single cell analysis: the new frontier in 'omics'. , 2010, Trends in biotechnology.

[16]  A Menachery,et al.  Dielectrophoretic tweezer for isolating and manipulating target cells. , 2011, IET nanobiotechnology.

[17]  Abhishek Jain,et al.  Biomimetic postcapillary expansions for enhancing rare blood cell separation on a microfluidic chip. , 2011, Lab on a chip.

[18]  J. Sader,et al.  Calibration of rectangular atomic force microscope cantilevers , 1999 .

[19]  Maryam Tabrizian,et al.  Adhesion based detection, sorting and enrichment of cells in microfluidic Lab-on-Chip devices. , 2010, Lab on a chip.

[20]  Vijay Kumar,et al.  Automated biomanipulation of single cells using magnetic microrobots , 2013, Int. J. Robotics Res..

[21]  Jean-Louis Viovy,et al.  Design, modeling and characterization of microfluidic architectures for high flow rate, small footprint microfluidic systems. , 2011, Lab on a chip.

[22]  K. Schütze,et al.  Going in vivo with laser microdissection. , 2002, Methods in enzymology.

[23]  S. Quake,et al.  A microfabricated fluorescence-activated cell sorter , 1999, Nature Biotechnology.

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

[25]  Klavs F Jensen,et al.  Microfluidic based single cell microinjection. , 2008, Lab on a chip.

[26]  W Hampton Henley,et al.  Laser-based directed release of array elements for efficient collection into targeted microwells. , 2013, The Analyst.

[27]  J. Hubbell,et al.  Self-assembly and steric stabilization at heterogeneous, biological surfaces using adsorbing block copolymers. , 1998, Chemistry & biology.

[28]  J. Vorholt,et al.  Cooperative vaccinia infection demonstrated at the single-cell level using FluidFM. , 2012, Nano letters.

[29]  Ronald Pethig,et al.  Spatial manipulation of cells and organelles using single electrode dielectrophoresis , 2011 .

[30]  M. Roederer,et al.  The history and future of the fluorescence activated cell sorter and flow cytometry: a view from Stanford. , 2002, Clinical chemistry.

[31]  Xiaoning Jiang,et al.  Ultrasound-induced release of micropallets with cells. , 2012, Applied physics letters.

[32]  W. Marsden I and J , 2012 .

[33]  Han Wei Hou,et al.  Pinched flow coupled shear-modulated inertial microfluidics for high-throughput rare blood cell separation. , 2011, Lab on a chip.

[34]  R. Stephenson A and V , 1962, The British journal of ophthalmology.

[35]  J. Kutter,et al.  Integrating advanced functionality in a microfabricated high-throughput fluorescent-activated cell sorter. , 2003, Lab on a chip.

[36]  J. Chalmers,et al.  Flow Through, Immunomagnetic Cell Separation , 1998, Biotechnology progress.

[37]  J. Lichtenberger,et al.  Micromanipulation of retinal neurons by optical tweezers. , 1998, Molecular vision.

[38]  Hongtao Feng,et al.  An automated microfluidic device for assessment of mammalian cell genetic stability. , 2012, Lab on a chip.

[39]  H. Jung,et al.  Continuous separation of breast cancer cells from blood samples using multi-orifice flow fractionation (MOFF) and dielectrophoresis (DEP). , 2011, Lab on a chip.

[40]  Tomaso Zambelli,et al.  Force-controlled fluidic injection into single cell nuclei. , 2013, Small.