Abstract: A method for dynamic evolution and/or adaptation and monitoring of characteristics in living cells is provided, wherein the method may be performed at a microfluidic-enabled cell-culture device comprising pneumatic layer for directing flow of fluid to a plurality of individually addressable wells, and one or more sensors configured to detect data regarding environments inside one or more of the plurality of wells. The method may involve culturing a population of cells in a first well of the plurality of wells, perturbing one or more characteristics of an environment in the first well following the culturing of the population of cells, monitoring one or more characteristics of the population of cells in the first well, and removing all or part of the evolved/adapted population of cells from the first well.

Abstract: A method for dynamic evolution and/or adaptation and monitoring of characteristics in living cells is provided, wherein the method may be performed at a microfluidic-enabled cell-culture device comprising pneumatic layer for directing flow of fluid to a plurality of individually addressable wells, and one or more sensors configured to detect data regarding environments inside one or more of the plurality of wells. The method may involve culturing a population of cells in a first well of the plurality of wells, perturbing one or more characteristics of an environment in the first well following the culturing of the population of cells, monitoring one or more characteristics of the population of cells in the first well, and removing all or part of the evolved/adapted population of cells from the first well.

Abstract: Devices, systems, methods, and techniques regarding a microfluidic-enabled multiwell device with closed-loop monitoring and control of various parameters of the microfluidic environment are provided. A microfluidic-enabled multiwell device may have a removable and disposable microfluidics module layer and a reusable sensor module layer. The sensor module layer may be configured to monitor and control parameters of the environment inside the microfluidics module layer, store data regarding the parameters, and wirelessly transmit the data. The device may be configured to individually address flow of fluid to any one of a plurality of wells, using one or more pneumatic micropumps. The device may be configured to automatically execute one or more live cell cultures, assays, and/or protocols. The device may be configured to be received in a docking station and/or portable manifold adapter, and to be fluidly, pneumatically, and/or electronically coupled to the station, adapter, or other laboratory equipment.

Abstract: Devices, systems, methods, and techniques regarding a microfluidic-enabled multiwell device with closed-loop monitoring and control of various parameters of the microfluidic environment are provided. A microfluidic-enabled multiwell device may have a removable and disposable microfluidics module layer and a reusable sensor module layer. The sensor module layer may be configured to monitor and control parameters of the environment inside the microfluidics module layer, store data regarding the parameters, and wirelessly transmit the data. The device may be configured to individually address flow of fluid to any one of a plurality of wells, using one or more pneumatic micropumps. The device may be configured to automatically execute one or more live cell cultures, assays, and/or protocols. The device may be configured to be received in a docking station and/or portable manifold adapter, and to be fluidly, pneumatically, and/or electronically coupled to the station, adapter, or other laboratory equipment.

Abstract: A method for dynamic evolution and/or adaptation and monitoring of characteristics in living cells is provided, wherein the method may be performed at a microfluidic-enabled cell-culture device comprising pneumatic layer for directing flow of fluid to a plurality of individually addressable wells, and one or more sensors configured to detect data regarding environments inside one or more of the plurality of wells. The method may involve culturing a population of cells in a first well of the plurality of wells, perturbing one or more characteristics of an environment in the first well following the culturing of the population of cells, monitoring one or more characteristics of the population of cells in the first well, and removing all or part of the evolved/adapted population of cells from the first well.

Abstract: Devices, systems, methods, and techniques regarding a microfluidic-enabled multiwell device with closed-loop monitoring and control of various parameters of the microfluidic environment are provided. A microfluidic-enabled multiwell device may have a removable and disposable microfluidics module layer and a reusable sensor module layer. The sensor module layer may be configured to monitor and control parameters of the environment inside the microfluidics module layer, store data regarding the parameters, and wirelessly transmit the data. The device may be configured to individually address flow of fluid to any one of a plurality of wells, using one or more pneumatic micropumps. The device may be configured to automatically execute one or more live cell cultures, assays, and/or protocols. The device may be configured to be received in a docking station and/or portable manifold adapter, and to be fluidly, pneumatically, and/or electronically coupled to the station, adapter, or other laboratory equipment.