A culture information processing device includes: a feature value computing unit that computes growth feature values indicating features of growth characteristics of cells from data acquired in a particular first subculturing process selected from among a plurality of subculturing processes included in a culture period of the cells; a condition setting unit that sets culturing conditions of a second subculturing process one process after the first subculturing process; and an information computing unit that computes, on the basis of the growth feature values computed by the feature value computing unit and the culturing conditions set by the condition setting unit, characteristics-related information related to growth characteristics in the second subculturing process.

A device for analysis of cells comprises: an integrated circuit arrangement on a substrate; a dielectric layer formed above the integrated circuit arrangement; a microelectrode array layer formed above the dielectric layer, said microelectrode array layer comprising a plurality of individual electrodes, wherein each electrode is connected to the integrated circuit arrangement through a via in the dielectric layer; and wherein a plurality of longitudinal trenches in the dielectric layer and the microelectrode array layer are for stimulating cell growth on a surface of the device

Described are interdigitated electrodes, which may optionally be plasmonic, useful for in vitro biosensing applications. Such devices may significantly reduce undesired background noise by separating the excitation source (light) from the detection signal (current), and thereby, leading to higher sensitivity for bioanalysis compared with conventional interdigitated electrodes. Also described are methods of making such interdigitated electrodes, which allow a substrate, which may optionally be plasmonic, to be tuned not only to maximize the targeted interaction of the cells with the nanoscale geometry, but also for the excitation wavelength to minimize biological sample interference.

A dynamic incubator system and method for mammalian cells. The dynamic incubator system includes an incubator and a programming device communicatively coupled to the incubator. The programming device includes a memory, one or more processors, a display, and an input mechanism. The programming device is adapted to enable at least one preset temperature and gas concentration sequence to be one or more of designed for the interior of the incubator, saved to the memory of the programming device and/or selected for implementation within the interior of the incubator. The at least one temperature and gas concentration sequence includes programmed changes to the temperature and a CO.sub.2 gas concentration. A purging mechanism is coupled to the incubator and releases a portion of a gas concentration to enable rapid changes in the temperature and gas concentration in the incubator.

A method of ranking embryos to indicate their development potential. The method comprises: obtaining values for a plurality of characteristics relating to the morphological development of the embryos during an observation period; determining for respective ones of the embryos whether or not the embryo has undergone a direct cleavage event, and ranking the embryos determined to have undergone a direct cleavage event with a ranking that indicates a lower development potential than for the embryos not determined to have undergone a direct cleavage event; and for the embryos not determined to have undergone a direct cleavage event, determining whether or not a duration of a predefined developmental stage for the embryo exceeds a predefined threshold duration, and ranking embryos for which the duration of the predefined developmental stage is determined to exceed the predefined threshold duration with a ranking that indicates a lower development potential than for the embryos for which the duration of the predefined developmental stage is not determined to exceed the predefined threshold duration; and for the embryos for which the duration of the predefined developmental stage is not determined to exceed the predefined threshold duration, determining whether or not the relative durations of two predefined developmental stages for the embryo is outside a predefined range, and ranking embryos for which the relative durations of two predefined developmental stages for the embryo is outside a predefined range with a ranking that indicates a lower development potential than for the embryos for which the relative durations of two predefined developmental stages for the embryo is not outside the predefined range.

An improved cell culture monitoring system and method that detects cell growth and concentration in a dynamic environment of incubator/shaker. In order to reduce power consumption and make a wireless cell culture monitoring system practical, several methods of temperature compensation are used to replace a method of controlling the temperature of sensing module. Furthermore its power consumption can be significantly reduced by using an adaptive and synchronized light pulse detection technique.

A system, device and method for electroporation of living cells and the introduction of selected molecules into the cells utilizes a fluidic system where living cells and biologically active molecules flow through a channel that exposes them to electric fields, causing the molecules to be transferred across the cell membrane. The device is structured in a manner that allows precise control of the cells location, motion, and exposure to electric fields within the flow channel device. The method is particularly well suited for the introduction of DNA, RNA, drug compounds, and other biologically active molecules into living cells.

Methods of treating cells are disclosed. The methods include introducing a media comprising at least about 1×10.sup.6 cells/mL into a perfusion chamber having a volume of 50 mL or less, introducing a volume effective to treat the cells of at least one additive selected from cell culture media, a transducing agent, a pH control agent, and a cell activator into the perfusion chamber, and withdrawing cell waste and byproducts from the perfusion chamber, and harvesting the treated cells. The methods may include introducing the media comprising at least about 3×10.sup.6 cells/mL into the perfusion chamber. The methods may include measuring and/or controlling at least one parameter of the cells or the media selected from pH, optical density, dissolved oxygen concentration, temperature, and light scattering.

The invention relates to a method for analyzing the effect of a gaseous medium on a biological test system using an extracellular metabolization system. The method consists of the following steps: a biological test sample is cultivated on a permeable carrier, the gaseous medium is guided over the surface of the biological test system in order to form an exposition atmosphere over the biological test system, the extracellular metabolization system is added to a conservation medium and the permeable carrier is brought into contact with a conservation medium that comprises the extracellular metabolization system below the permeable carrier, in such a manner that the extracellular metabolization system only passes through the permeable carrier and that the biological test system is not submerged by the conservation medium containing the extracellular metabolization system.

A method for accelerating the migration of cells by applying a time-varying magnetic field to induce eddy currents that promote electrotaxis (galvanotaxis) of cells. The method of the present invention accelerates the healing of wounds by electrotaxis of cells.