Disclosed are a method and a device for determining an operating condition of a bioreactor. Each of the method and the device receives N experimental data sets, models the bioreactor using the N experimental data sets to construct a bioreactor model, and determines an optimal operation condition based on an operation scheme of the bioreactor, using the constructed bioreactor model.

Embodiments relate to a unique design of a cell growth vessel stack system that provides for inter-communication of cell growth levels arranged in a parallel configuration so to facilitate environmental uniformity of the inter-connected growth surface tiers. The unique design also facilitates a fine-tuning of optimized gas and media flow to each cell growth level within the vessel stack. The unique architecture facilitates media refreshment at conveniently scheduled intervals and/or allows constant perfusion from a media reservoir that can be replenished without interrupting the cell proliferation rate. The perfusion rate, nutrient medium condition, CO2 content and osmolality can be controlled to optimize the desired cell proliferation rate, thereby improving cell quantity, quality, and viability.

A bioreactor includes a culture medium vessel housing culture medium. The culture medium vessel further includes a first side surface including a first transparent optical window; and a second side surface parallel to the first surface and including one or more sensor adapters to fix optical sensors. A cell retention vessel is disposed underneath and connected to the culture medium vessel, the cell retention vessel housing biological cells and having: a top surface that intersects a base of the culture medium vessel, and a second transparent optical window indented into the top surface at a first corner of the top surface. A semipermeable membrane is disposed at a bottom of the cell retention vessel, and a frame comprising a grid is disposed underneath the semipermeable membrane.

Incubators including an enclosure with an internal chamber configured to support a cell culture plate comprising a plurality of wells are disclosed. The enclosure includes a plurality of openings configured to allow access to the wells. The incubators include a sealing element configured to seal the plurality of openings in the enclosure. The sealing element comprises a plurality of openings corresponding to at least a subset of the plurality of openings in the enclosure. Access to the internal chamber can be provided by aligning the plurality of openings in the sealing element with the plurality of openings in the enclosure. Methods for using the incubators are also provided.

Algae harvesting and cultivating systems and methods for producing high concentrations of algae product with minimal energy. In an embodiment, a dead-end filtration system and method includes at least one tank and a plurality hollow fiber membranes positioned in the at least one tank. An algae medium is pulled through the hollow fiber membranes such that a retentate and a permeate are produced.

An automatic and continuous glucose monitoring apparatus and method of using same based on binding proteins. The apparatus integrates an aseptic sampling technique, a specially modified chromatography column to hold immobilized binding protein, and a microfluorometer into a compact portable device. The apparatus permits the measurement of a very wide range of concentrations—from a few micromolar to several hundreds of millimolar of glucose.

Algae harvesting and cultivating systems and methods for producing high concentrations of algae product with minimal energy. In an embodiment, a dead-end filtration system and method includes at least one tank and a plurality hollow fiber membranes positioned in the at least one tank. An algae medium is pulled through the hollow fiber membranes such that a retentate and a permeate are produced.

Provided is a cell culture apparatus including a cell supply unit that supplies cells; a culture medium supply unit that supplies a culture medium; an additive supply unit that supplies an additive for inducing the differentiation of undifferentiated cells; a stirring unit that stirs a processing target; a separation unit that separates a component contained in the processing target; a culture vessel that cultures the cells; a first flow channel that forms a circulation route passing through the cell supply unit, the stirring unit, the separation unit, and the culture vessel; a second flow channel that connects the culture medium supply unit and the first flow channel; a third flow channel that connects the additive supply unit and the first flow channel; and a control unit that controls the feeding of liquid through the first flow channel, the second flow channel, and the third flow channel.

A device of measuring an amount of lipid accumulation in microalgae includes a flow cell through which a fluid containing the microalgae is supplied to flow, an excitation light source irradiating the flow cell with excitation light, a fluorescence detector detecting autofluorescence generated from a chloroplast of each of the microalgae that have been irradiated with the excitation light, a scattered light detector detecting scattered light caused by each of the microalgae that have been irradiated with the excitation light, and an arithmetic unit calculating a size of the microalga from intensity of the scattered light, calculating a fluorescence density corresponding to intensity of the autofluorescence generated from the chloroplast per unit size of the microalga based on both the intensity of the autofluorescence generated from the chloroplast and the size of the microalga, and calculating an amount of lipid accumulation per microalga from the fluorescence density.

The present invention provides a parallel bioreactor system, comprising: an oscillator for generating oscillating motion; a plurality of culture vessels mounted on the oscillator, wherein each culture vessel is provided with an inner cavity, the inner cavity comprises a cylindrical portion at the upper part and an inverted truncated conical bottom at the lower part, a cross section of the cylindrical portion is consistent with the cross section of the top of the inverted truncated conical bottom, and the bottom of the cylindrical portion is joined with the top of the inverted truncated conical bottom; disposable culture bags arranged in the inner cavities of the culture vessels and used for accommodating culture solution, wherein each disposable culture bag is provided with a multifunctional cover plate, and the multifunctional cover plate is connected to the top of the culture bag to seal the culture bag, and is provided with a plurality of connection holes leading to interior of the disposable culture bag; and a control system, wherein the control system controls the oscillating motion of the oscillator and parameters of the culture solution in the disposable culture bags.