Abstract: A method of identifying a therapeutic compound for treating cancer in a human subject, the method including: providing a device that measures cell-substrate impedance; culturing cancer cells in the at least two wells, wherein the cancer cells are obtained from a human subject and have a receptor tyrosine kinase (RTK) pathway; adding to a first well a proposed therapeutic compound that affects an RTK pathway and an RTK stimulating factor for the RTK pathway to form a test well, and adding to another well the RTK stimulating factor to form a control well; continuously monitoring cell-substrate impedance of the at least two wells; and determining a difference in impedance or optionally in cell index between the test well and control well; and if significantly different, concluding the proposed therapeutic compound is therapeutically active in the RTK pathway within the cancer cells of the human subject.

Abstract: A method of identifying a therapeutic compound for treating cancer in a human subject, the method including: providing a device that measures cell-substrate impedance; culturing cancer cells in the at least two wells, wherein the cancer cells are obtained from a human subject and have a receptor tyrosine kinase (RTK) pathway; adding to a first well a proposed therapeutic compound that affects an RTK pathway and an RTK stimulating factor for the RTK pathway to form a test well, and adding to another well the RTK stimulating factor to form a control well; continuously monitoring cell-substrate impedance of the at least two wells; and determining a difference in impedance or optionally in cell index between the test well and control well; and if significantly different, concluding the proposed therapeutic compound is therapeutically active in the RTK pathway within the cancer cells of the human subject.

Abstract: A method of identifying a potential therapeutic compound that affects a Receptor Tyrosine Kinase (RTK) pathway in cancer cells, which includes: providing a device capable of measuring cell-substrate impedance; culturing cancer cells in serum-free media in at least two wells of the device; adding to a first well a proposed therapeutic compound that affects a RTK pathway and a RTK stimulating factor for the RTK pathway to form a test well, and adding to another well the RTK stimulating factor to form a control well; continuously monitoring cell-substrate impedance of the at least two wells and optionally determining cell indices from the monitored cell-substrate impedance; and determining a difference in impedance or optionally cell index between the test well and control well; and if significantly different, concluding the proposed therapeutic compound is therapeutically active in the RTK pathway within the cancer cells.

Abstract: Use of cell-substrate impedance based methods for screening for agonists of G-Protein Coupled Receptors (GPCRs) or inhibitors of a Receptor Tyrosine Kinases (RTKs), identifying compounds that affect GPCR or RTK pathways, validating molecular targets involved in a GPCR or RTK signaling pathways, monitoring dose-dependent functional activation of GPCR or RTK; determining desensitization of a GPCR and identifying a compound capable of affecting RTK activity in cancer cell proliferation.

Abstract: A method of identifying a potential therapeutic compound that affects a Receptor Tyrosine Kinase (RTK) pathway in cancer cells, which includes: providing a device capable of measuring cell-substrate impedance; culturing cancer cells in serum-free media in at least two wells of the device; adding to a first well a proposed therapeutic compound that affects a RTK pathway and a RTK stimulating factor for the RTK pathway to form a test well, and adding to another well the RTK stimulating factor to form a control well; continuously monitoring cell-substrate impedance of the at least two wells and optionally determining cell indices from the monitored cell-substrate impedance; and determining a difference in impedance or optionally cell index between the test well and control well; and if significantly different, concluding the proposed therapeutic compound is therapeutically active in the RTK pathway within the cancer cells.

Abstract: Use of cell-substrate impedance based methods for screening for agonists of G-Protein Coupled Receptors (GPCRs) or inhibitors of a Receptor Tyrosine Kinases (RTKs), identifying compounds that affect GPCR or RTK pathways, validating molecular targets involved in a GPCR or RTK signaling pathways, monitoring dose-dependent functional activation of GPCR or RTK; determining desensitization of a GPCR and identifying a compound capable of affecting RTK activity in cancer cell proliferation.

Abstract: The present invention includes devices and methods for transfecting a cell or cell population and dynamic monitoring of cellular events. A variety of microelectronic devices are provide that incorporate functions such as electroporation, modulation of a transmembrane potential and dynamic monitoring of cellular functions and mechanisms.

Abstract: Methods for identifying a compound capable of interacting with a Receptor Tyrosine Kinase (RTK) including providing a device capable of measuring cell-substrate impedance, adding test cells expressing a RTK to the device, measuring first impedances, adding a compound to at least one compound well and adding a vehicle control to at least one control well, measuring second impedances of the compound well and the control well, determining the change in the impedance for the compound well and the one control well, comparing the change in impedance between the compound well and the control well, and identifying the compound interacts with the RTK if the comparison demonstrates a significant difference between the change in impedance.

Abstract: Methods for identifying a compound capable of interacting with a Receptor Tyrosine Kinase (RTK) including providing a device capable of measuring cell-substrate impedance, adding test cells expressing a RTK to the device, measuring first impedances, adding a compound to at least one compound well and adding a vehicle control at least one control well, measuring second impedances of the compound well and the control well, determining the change in the impedance for the compound well and the one control well, comparing the change in impedance between the compound well and the control well, and identifying the compound interacts with the RTK if the comparison demonstrates a significant difference between the change in impedance.

Abstract: The present application includes systems and methods for identifying a compound capable of interacting with a G-Protein Coupled Receptor (GPCR) or Receptor Tyrosine Kinase (RTK) including providing a device capable of measuring cell-substrate impedance operably connected to an impedance analyzer, adding test cells expressing a GPCR or a RTK to wells of the device, measuring first impedances of the wells and optionally determining first cell indices from the first impedances, adding a compound to at least one well containing test cells to form at least one compound well and adding a vehicle control to at least another well containing test cells to form at least one control well, measuring second impedances of the compound well and the control well and optionally determining second cell indices from the second impedances, determining the change in the impedance or cell index for the compound well and the one control well, comparing the change in impedance or cell index between the compound well and the control

Abstract: The present invention includes devices and methods for transfecting a cell or cell population and dynamic monitoring of cellular events. A variety of microelectronic devices are provide that incorporate functions such as electroporation, modulation of a transmembrane potential and dynamic monitoring of cellular functions and mechanisms.

Abstract: The present invention includes devices and methods for transfecting a cell or cell population and dynamic monitoring of cellular events. A variety of microelectronic devices are provide that incorporate functions such as electroporation, modulation of a transmembrane potential and dynamic monitoring of cellular functions and mechanisms.

Abstract: The present invention includes devices and methods for dynamically monitoring cell adhesion and cell spreading. Cells are added to a microelectronic cell sensor array operably connected to an impedance analyzer. The device also includes a coating including biological molecule or organic compound capable of interacting with the cell. Cell adhesion and cell mobility is determined by detecting changes in impedance and comparing impedance or cell index values between samples.

Abstract: The present invention includes devices and methods for transfecting a cell or cell population and dynamic monitoring of cellular events. A variety of microelectronic devices are provide that incorporate functions such as electroporation, modulation of a transmembrane potential and dynamic monitoring of cellular functions and mechanisms.

Abstract: The present invention includes devices and methods for dynamically monitoring cell adhesion and cell spreading. Cells are added to a microelectronic cell sensor array operably connected to an impedance analyzer. The device also includes a coating including biological molecule or organic compound capable of interacting with the cell. Cell adhesion and cell mobility is determined by detecting changes in impedance and comparing impedance or cell index values between samples.

Abstract: The present application includes systems and methods for identifying a compound capable of interacting with a G-Protein Coupled Receptor (GPCR) or Receptor Tyrosine Kinase (RTK) including providing a device capable of measuring cell-substrate impedance operably connected to an impedance analyzer, adding test cells expressing a GPCR or a RTK to wells of the device, measuring first impedances of the wells and optionally determining first cell indices from the first impedances, adding a compound to at least one well containing test cells to form at least one compound well and adding a vehicle control to at least another well containing test cells to form at least one control well, measuring second impedances of the compound well and the control well and optionally determining second cell indices from the second impedances, determining the change in the impedance or cell index for the compound well and the one control well, comparing the change in impedance or cell index between the compound well and the control

Abstract: Provided herein are methods for identifying a subject at risk of breast cancer, reagents and kits for carrying out the methods, methods for identifying candidate therapeutics for treating breast cancer, and therapeutic methods for treating breast cancer in a subject. These embodiments are based upon an analysis of polymorphic variations in nucleotide sequences within the human genome.