A high-performance elastomeric patch clamp chip.

Ion channels play key roles in cell physiology and underlie a broad spectrum of disorders. To this day, the gold standard for studying ion channels is the patch clamp technique. Patch clamping involves careful positioning of a fine-tipped glass micropipette onto the surface of the cell to form a high-resistance (>1 Gohms) seal ("gigaseal"), a procedure that is laborious, vibration-sensitive, and not easily amenable to automation. In addition, the solution inside the pipette cannot be easily exchanged. Recently reported patch clamp chips offer the potential of increased throughput, but to date the overall per-cell performance of most designs has been very low when compared to pipettes, and/or the fabrication process is prohibitively expensive. Here we demonstrate a replica-molded elastomeric patch clamp chip incorporating nanofabricated constrictions, which delivers high-stability gigaseals, with success rates comparable to those of pipettes, using rat basophilic leukemia (RBL) cells. The high stability enables exchanges of both the extracellular and intracellular solution during whole-cell recordings. In a sample of 103 experiments, 66 cells (64%) were successfully immobilized at the patch aperture; 38 cells (58% of immobilized cells, 37% of all cells) were successfully gigasealed; and 25 cells (65% of gigasealed cells, 34% of immobilized cells, 24% of all cells) were successfully perforated for whole-cell access. In the last group of 27 experiments, 79% of the cells could be immobilized, of which 68% could be gigasealed and 46% perforated for whole-cell access, indicating that dexterity is important.

[1]  B. Hille,et al.  Potassium channels as multi-ion single-file pores , 1978, The Journal of general physiology.

[2]  Yoshihiro Kubo,et al.  Primary structure and functional expression of a mouse inward rectifier potassium channel , 1993, Nature.

[3]  C. Trautmann,et al.  Microstructured glass chip for ion-channel electrophysiology. , 2001, Physical review. E, Statistical, nonlinear, and soft matter physics.

[4]  N. Fertig,et al.  Activity of single ion channel proteins detected with a planar microstructure , 2002 .

[5]  Albert Folch,et al.  Parallel mixing of photolithographically defined nanoliter volumes using elastomeric microvalve arrays , 2005, Electrophoresis.

[6]  D. Rothwarf,et al.  A benchmark study with sealchip planar patch-clamp technology. , 2003, Assay and drug development technologies.

[7]  Margit Asmild,et al.  Characterization of potassium channel modulators with QPatch automated patch-clamp technology: system characteristics and performance. , 2003, Assay and drug development technologies.

[8]  Horst Vogel,et al.  Chip based biosensor for functional analysis of single ion channels , 2000 .

[9]  B. Sakmann,et al.  Improved patch-clamp techniques for high-resolution current recording from cells and cell-free membrane patches , 1981, Pflügers Archiv.

[10]  D. Lüthi,et al.  Mg‐Atp Binding: Its Modification by Spermine, the Relevance to Cytosolic Mg2+ Buffering, Changes in the Intracellular Ionized Mg2+ Concentration and the Estimation of Mg2+ by 31P‐NMR , 1999, Experimental physiology.

[11]  B Sakmann,et al.  Conductance properties of single inwardly rectifying potassium channels in ventricular cells from guinea‐pig heart. , 1984, The Journal of physiology.

[12]  E Neher,et al.  Nobel lecture. Ion channels for communication between and within cells. , 1992, The EMBO journal.

[13]  R. Penner,et al.  The Store-Operated Calcium Current ICRAC: Nonlinear Activation by InsP3 and Dissociation from Calcium Release , 1997, Cell.

[14]  N. Melosh,et al.  Silicon chip-based patch-clamp electrodes integrated with PDMS microfluidics. , 2004, Biosensors & bioelectronics.

[15]  Luke P. Lee,et al.  Mammalian electrophysiology on a microfluidic platform. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[16]  N. Fertig,et al.  Stable integration of isolated cell membrane patches in a nanomachined aperture: a step towards a novel device for membrane physiology , 1999, cond-mat/9910217.

[17]  M. Reed,et al.  Micromolded PDMS planar electrode allows patch clamp electrical recordings from cells. , 2002, Biosensors & bioelectronics.

[18]  Robert H Blick,et al.  Microstructured apertures in planar glass substrates for ion channel research. , 2003, Receptors & channels.

[19]  Fred J. Sigworth,et al.  An air-molding technique for fabricating PDMS planar patch-clamp electrodes , 2004, Pflügers Archiv.

[20]  Zhe Lu,et al.  Electrostatic tuning of Mg2+ affinity in an inward-rectifier K+ channel , 1994, Nature.

[21]  Luke P. Lee,et al.  Integrated multiple patch-clamp array chip via lateral cell trapping junctions , 2004 .

[22]  Donglin Guo,et al.  IRK1 Inward Rectifier K+ Channels Exhibit No Intrinsic Rectification , 2002, The Journal of general physiology.

[23]  Alfred Stett,et al.  CYTOCENTERING: a novel technique enabling automated cell-by-cell patch clamping with the CYTOPATCH chip. , 2003, Receptors & channels.

[24]  Robert H Blick,et al.  Whole cell patch clamp recording performed on a planar glass chip. , 2002, Biophysical journal.

[25]  H. Lester,et al.  The inward rectifier potassium channel family , 1995, Current Opinion in Neurobiology.

[26]  Bert Sakmann,et al.  Elementary steps in synaptic transmission revealed by currents through single ion channels , 1992, Neuron.

[27]  C. Vandenberg Inward rectification of a potassium channel in cardiac ventricular cells depends on internal magnesium ions. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[28]  Martin A. M. Gijs,et al.  Realization of hollow SiO2 micronozzles for electrical measurements on living cells , 2002 .

[29]  E. Neher Ion channels for communication between and within cells , 1992, Neuron.