In an aspect, disclosed herein are physiological devices and systems, and components thereof, used to evaluate cardiac parameters and arrhythmogenic mechanisms. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present invention.

A scalable, real-time, label-free, electrode- or optical-based cell monitoring system for integration into a cell culture incubator is described herein. An example system includes (1) cell culture consumables with integrated electrodes and/or optics for growing and monitoring cells, (2) incubator trays for consumable organization and recording, and (3) a system console, external to the incubator, for connecting multiple incubator trays. Without perturbing the cell culture, the system is capable of monitoring multiple culture attributes for each cell culture consumable simultaneously. These attributes can include, but are not limited to, cell growth, proliferation, morphology, media pH, or media oxygen. The system can support multiple trays, which permits monitoring dozens to hundreds of consumables simultaneously, including a mixture of consumables of various sizes. In addition to monitoring adherent cells, the disclosed technology can be readily adapted for monitoring of cell suspensions.

A device for analysis of cells comprises: an active sensor area (104) presenting a surface for cell growth; a microelectrode array (102) comprising a plurality of pixels (110) in the active sensor area (104), wherein each pixel (110) comprises at least one electrode (120) at the surface, wherein each pixel (110) is configured to control the configuration of the pixel circuitry and set a measurement modality of the pixel; recording circuitry having a plurality of recording channels (130), wherein each pixel (110) is connected to a recording channel (130), wherein each recording channel (130) comprises a reconfigurable component (131), which is selectively controlled between being set to a first mode, in which the reconfigurable component (131) is configured to amplify a received pixel signal, and being set to a second mode, in which the reconfigurable component (131) is configured to selectively pass a frequency band of the received pixel signal.

Methods for identifying compounds that modulate cellular responses stimulated by IgE, which include providing an impedance-based system that monitors cell-substrate impedance of cells on a substrate; introducing cells to the substrate of the system; adding at least one test compound and IgE to the cells, wherein the at least one test compound is suspected of modulating cell responses stimulated by the IgE; adding an antigen to the cells; monitoring the cell-substrate impedance of cells on the substrate; and analyzing the cell-substrate impedance to evaluate whether the at least one test compound alters a cellular response to stimulation with the IgE.

A system for monitoring cells, which includes a device for monitoring cell-substrate impedance, the device having a plurality of wells on a nonconductive substrate, where each of the plurality of wells has an electrode array fabricated on the substrate for measurement of cell-substrate impedance; an impedance analyzer that measures cell-substrate impedance from the plurality of wells; electronic circuitry with multiple analogue-to-digital conversion channels, where the electronic circuitry electrically connects the electrode arrays to the impedance analyzer such that the electrode arrays are electrically monitored at millisecond time resolution; and a software program that analyzes the measured cell-substrate impedance.

Various cell analysis systems of the present teachings can measure the electrical and metabolic activity of single, living cells with subcellular addressability and simultaneous data acquisition for between about 10 cells to about 500,000 cells in a single analysis. Various sensor array devices of the present teachings can have sensor arrays with between 20 million to 660 million ChemFET sensors built into a massively paralleled array and can provide for simultaneous measurement of cells with data acquisition rates in the kilohertz (kHz) range. As various ChemFET sensor arrays of the present teachings can detect chemical analytes as well detect changes in cell membrane potential, various cell analysis systems of the present teachings also provide for the controlled chemical and electrical interrogation of cells.

Analyzing cells disposed on a sensor array surface of a ChemFET sensor array, may include flowing a solution having a step change in pH across the sensor array surface, wherein ChemFET sensors of the sensor array generate signals in response to the step change in pH to produce electroscopic image data. Multiple frames of the electroscopic image data are acquired during an acquisition time interval. Each frame corresponds to signal samples generated by the sensor array measured at a sampling time during the acquisition time interval. Each frame comprises pixels, wherein a given pixel in the frame corresponds to a signal sample from a given sensor in the sensor array. The electroscopic image data is segmented, based on characteristics of the signal samples, into cell regions corresponding to locations of the cells on the sensor array surface and background regions corresponding to areas on the sensor array having no cells.

A method of recording intracellular action potentials in electrogenic cells through pores in membranes of cells formed by optoporation includes positioning a sample that includes the cells on a multi-electrode array; incubating or perfusing the sample; focusing a laser on the surface of the array electrodes, the surface contacting the sample; applying one or more laser pulses to one or more array electrodes to perform a localized breakdown of the membrane of the cells of the sample; and recording the intracellular action potentials. The surface of the electrodes is porous and has cavities and protrusions at the nanoscale level, and the electric field produced by the laser is localized and amplified to perform the localized breakdown of the membrane of the cells of the sample.

A cell-containing structure is provided that allows ready-to-use nerve drug response evaluation with high reproducibility to be easily performed. The cell-containing structure for evaluating an electrical property of neurons includes: (a) a culture surface to which the neurons are able to be adhered; (b) a cell mass that is adhered to the culture surface and contains at least one of the neurons; and (c) a plurality of electrodes for measuring the electrical property of the cell mass, wherein a spontaneous firing frequency of cells contained in the cell mass is 0.25 Hz or more per electrode.

An electrophysiological recording and stimulation system includes an electrophysiological device coupled to neural tissue and configured to measure neural electrophysiological signals. The system also includes a computing device coupled to the electrophysiological device and configured to receive neural electrophysiological signals from the electrophysiological device, and transmit neural stimulating signals to the neural tissue through the electrophysiological device based on the neural electrophysiological signals.