The invention relates to an apparatus (200) for incubation of a viable biological material (2); said apparatus comprises: a housing (4) having an extension in a longitudinal direction X, in a transversal direction Y, and in a direction Z perpendicular to the longitudinal direction and the transversal direction; said housing comprising: two or more culture dish compartments (6), each being adapted to accommodate, one or more culture dishes (8) comprising a biological material (2); wherein said apparatus comprises an image capturing device (10); wherein said apparatus comprises a control unit (12) for controlling the operation thereof; wherein at least part of said image capturing device is being configured to be movable in relation to the two or more culture dish compartments (6), thereby allowing capture of images of one or more of said biological materials (2) accommodated in said one or more culture dishes (8); and wherein said apparatus comprises a FLIM unit (11) (fluorescent lifetime imaging microscope); wherein at least part of said FLIM unit (11) is being configured to be movable in relation to the two or more culture dish compartments (6), thereby allowing capture of FLIM spectra of one or more of said biological materials (2) accommodated in said one or more culture dishes (8).

Methods and apparatuses to non-destructively and periodically sample a small quantity of intracellular proteins and mRNA from the same single cell or cells for an extended period of time. Specifically, describe herein are non-perturbative methods for time-resolved, longitudinal extraction and quantitative measurement of intracellular proteins and nucleic acids from a variety of cell types using systems including nanostraws.

Cell monitoring apparatus includes sensing chip and channel module. Sensing chip includes channel region, source and drain regions, and sensing film. The channel region includes first semiconductor material. The source and drain regions are disposed at opposite sides of the channel region, and include a second semiconductor material. Sensing film is disposed on the channel region at a sensing surface of the sensing chip. Channel module is disposed on the sensing surface of sensing chip. A microfluidic channel is formed between the sensing surface of the sensing chip and a proximal surface of the channel module. The microfluidic channel includes a culture chamber and a micro-well. The culture chamber is concave into the proximal surface of the channel module, and overlies the channel region. The micro-well is concave into a side of the culture chamber, and directly faces the sensing film.

A method of controlling a bioreactor system includes providing a cell culture in a bioreactor, wherein conditions in the bioreactor enable the cell culture to produce a protein of interest (POI), measuring process parameters (PPs) of the culture within the bioreactor by RAMAN, wherein the process parameters are selected from the group consisting of nutrient concentration, viable cell concentration, and protein attributes, measuring a predetermined weight of the bioreactor with the cell culture, removing cell-free spent media from the cell culture using a first output conduit at a first specified rate, removing cells from the cell culture using a second output conduit at a second specified rate, and introducing one or both of fresh media or nutrients into the cell culture using an input conduit at a third specified rate.

Aspects of the present invention provide improved methods and apparatus for use in in vitro modeling of the interaction of cells with cellular constructs/parts/axons, including axon mimetics and use of three-dimensional fibers.

A method of controlling a bioreactor system includes providing a cell culture in a bioreactor, wherein conditions in the bioreactor enable the cell culture to produce a protein of interest (POI), measuring process parameters (PPs) of the culture within the bioreactor by RAMAN, wherein the process parameters are selected from the group consisting of nutrient concentration, viable cell concentration, and protein attributes, measuring a predetermined weight of the bioreactor with the cell culture, removing cell-free spent media from the cell culture using a first output conduit at a first specified rate, removing cells from the cell culture using a second output conduit at a second specified rate, and introducing one or both of fresh media or nutrients into the cell culture using an input conduit at a third specified rate.

A method of controlling a bioreactor system includes providing a cell culture in a bioreactor, wherein conditions in the bioreactor enable the cell culture to produce a protein of interest (POI), measuring process parameters (PPs) of the culture within the bioreactor by RAMAN, wherein the process parameters are selected from the group consisting of nutrient concentration, viable cell concentration, and protein attributes, measuring a predetermined weight of the bioreactor with the cell culture, removing cell-free spent media from the cell culture using a first output conduit at a first specified rate, removing cells from the cell culture using a second output conduit at a second specified rate, and introducing one or both of fresh media or nutrients into the cell culture using an input conduit at a third specified rate.

The disclosure relates to a method and device for detecting and quantifying biological molecules such as cell surface or intracellular ligands/receptors in a dynamic system with high sensitivity and specificity; the method of using such platform optionally in combination with an optical detection system and kits comprising the optical platform.

Cell monitoring apparatus includes sensing chip and channel module. Sensing chip includes channel region, source and drain regions, and sensing film. The channel region includes first semiconductor material. The source and drain regions are disposed at opposite sides of the channel region, and include a second semiconductor material. Sensing film is disposed on the channel region at a sensing surface of the sensing chip. Channel module is disposed on the sensing surface of sensing chip. A microfluidic channel is formed between the sensing surface of the sensing chip and a proximal surface of the channel module. The microfluidic channel includes a culture chamber and a micro-well. The culture chamber is concave into the proximal surface of the channel module, and overlies the channel region. The micro-well is concave into a side of the culture chamber, and directly faces the sensing film.

An apparatus to simulate biocide performance in crude oil pipeline conditions is disclosed. The apparatus includes: a reactor to simulate a two-phase crude oil pipeline which includes a crude oil phase above a water phase. The reactor has an agitator to control a flow of the water phase in the reactor in response to a motor that drives an agitation rate of the agitator. A crude oil inlet supplies crude oil to the reactor for the crude oil phase. A water inlet supplies water to the reactor for the water phase. A control circuit is configured by code to control a proportion of the water to the crude oil supplied to the reactor and to control the motor to drive a desired agitation rate of the agitator. A biocide inlet supplies biocide to the reactor. A water sample outlet enables sampling of the water phase of the reactor.