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.

This new application can be administered completely by artificial Intelligence or manually while utilizing the artificial intelligence platform enabling cost savings. This new artificial intelligence application is a breakthrough in that it is based on highly accurate data which leads to learned behaviors of micro-organisms. This data is applied to accurate management and elimination of threats from micro-organisms to people, plants and animals using biosurfactants. This new cost-efficient AI conveyor belt micro-organism application gets us closer to understanding what lurks around us.

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.

Disclosed herein are devices including a substrate, one or more regions of electrically active material, and optionally at least one electrode. Also disclosed herein are devices or systems including a substrate, one or more regions of electrically active material including muscle cells and neuronal cells, and optionally at least one electrode. In some embodiments, the muscle cells and neuronal cells form one or more neuromuscular junctions at defined locations on the electrically active material. Also disclosed are methods of using the devices and systems for analyzing the effect of compounds on neuronal cell, muscle cell and/or neuromuscular junction activity.

A high-throughput, three-dimensional microelectrode array for in vitro electrophysiological applications includes a 3D printed well plate having a top face and bottom face, and a plurality of culture wells formed on the top face of the well plate. Each culture well includes a plurality of vertical microchannels on the top face and microtroughs formed on the bottom face and communicating with the microchannels. A conductive paste fills the microtroughs and the microchannels and forms self-isolated microelectrodes in each culture well and conductive traces that communicate with the self-isolated microelectrodes.

A method of producing a cell-containing container is provided, including a process in which pluripotent stem cells that have been induced to differentiate into neurons, and astrocytes are mixed and seeded in a cell culture container in which an electrode array is arranged on a culture surface, and a process in which the cell culture container is incubated, and as a result, the pluripotent stem cells and the astrocytes adhere to the culture surface, and the pluripotent stem cells differentiate into neurons.

Dynamic polymer surfaces are provided that include alternating micropatterns of adhesive domains and environmental stimuli-responsive repulsive domains, where application of a select environmental stimulus activates polymer structures of the repulsive domains to change conformation with respect to the adhesive domains. The dynamic polymer surfaces are useful for sorting, screening, and enriching target particles (such as cells) in a sample and for culturing and harvesting cells. Products, such as cell culture systems, including the dynamic polymer surfaces are also provided.

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 method of forming a high-throughput, three-dimensional (3D) microelectrode array for in vitro electrophysiological applications includes 3D printing a well plate having a top face and bottom face. A plurality of culture well each includes a plurality of 3D printed, vertical microchannels and microtroughs communicating with the microchannels. The microtroughs and the microchannels are filled with a conductive paste to form self-isolated microelectrodes in each of the culture wells and conductive traces that communicate with the self-isolated microelectrodes.

A cell culture substrate is provided that includes a substrate lattice having an ordered array of fibers and pores disposed between the fibers. The ordered array of fibers includes a cell culture surface to support adherent or semi-adherent cells during cell culture. The cell culture substrate further includes a positive charge coating disposed on the cell culture surface to promote adhesion of cells to the cell culture surface.