An apparatus for collecting or culturing cells or cell colonies includes: a common substrate formed from a flexible resilient polymeric material and having a plurality of wells formed therein; and a plurality of rigid cell carriers releasably connected to said common substrate, with said carriers arranged in the form of an array, and with each of the carriers resiliently received in one of the wells. A method of collecting or culturing cells or cell colonies with such an apparatus is carried out by depositing a liquid media carrying cells on the apparatus so that said cells settle on or adhere to said the carriers; and then (c) releasing at least one selected carrier having said cells thereon by gradual application of release energy to each carrier from the cavity in which it is received (e.g., by pushing with a probe).

A system and method for growing and maintaining biological material including producing a protein associated with the tissue, selecting cells associated with the tissue, expanding the cells, creating at least one tissue bio-ink including the expanded cells, printing the at least one tissue bio-ink in at least one tissue growth medium mixture, growing the tissue from the printed at least one tissue bio-ink, and maintaining viability of the tissue.

Cell culture and/or seeding device (10) comprising:

at least one culture chamber having at least one transparent optical window (11),

at least one fluid inlet (12) and at least one fluid outlet (13) communicating with the culture chamber,

at least one three-dimensional culture scaffold (20) arranged in the culture chamber, having surfaces (21, 22) spaced out along an axis (X) of the culture scaffold, the culture scaffold being arranged in the culture chamber in such a way as to be traversed from one surface to the other by the flow circulating between the fluid inlet and the fluid outlet, and in such a way that one of the surfaces thereof, preferably the fluid inlet face, is situated at least partially facing the optical window (11).

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 culture plate including: an array of light sources formed inside and on top of a semiconductor substrate; a transparent planarization layer coating the array of light sources; and an array of wells formed on said layer, each light source being located vertically in line with a well.

The present application is directed to a sampling system for sampling a fluid from a vessel, where the sampling system includes a sterile dispenser assembly operatively connected to the vessel, the sterile dispenser assembly including a valve operatively connected to the vessel, a membrane, and a needle, and a detachable sterile sampling container assembly operatively connected to the sterile dispenser assembly, the detachable sterile sampling container assembly including a sampling container, a membrane attached to the sampling container, and a sampling container housing enclosing the sampling container, where the sampling container housing includes a compressible portion having a deflated configuration and an expanded configuration.

The invention relates to a bioprocess container (10) having an optical measuring device (100) for non-invasive spectroscopic measurement comprising: a container housing (12), a port housing (102), which is connected to the container housing (12) and is sealed off with respect to the interior (18) of the container housing (12); at least one radiation-emitting element (124), which is designed to transmit electromagnetic radiation through the at least one fluid contained in the container housing (12); at least one radiation-receiving element (126), which is designed to at least partly receive the radiation which was transmitted by the radiation-emitting element (124); and at least one measuring insert (122), which holds and supports the at least one radiation-emitting element (124) and/or the at least one radiation-receiving element (126).

A method for directly bonding a metal to a transparent substrate includes providing a substrate; placing a metal foil directly on a face of the substrate; irradiating a portion of the metal foil with a laser beam so that metal corresponding to the portion melts and bonds directly to the substrate and forms a metal pad; and pumping a gas above the portion to prevent oxidation of the melted metal.

A method may be provided for stimulating the growth of a biomass, which is mixed with a liquid inside a bioreactor, by means of ionising radiation. The following method steps are used: a) exposing a first partial volume of the liquid in the bioreactor to ionising radiation, the first partial volume comprising at most 10% of the liquid volume in the bioreactor; b) mixing the first partial liquid volume, which has been exposed to ionising radiation, with the second partial liquid volume, which has not been exposed to ionising radiation, in the bioreactor; c) repeating method steps a) and b) multiple times, each partial volume of the liquid in the bioreactor being exposed to a total radiation dose of at most 50 Gy on statistical average.

A method for characterizing contractions in cell cultures of contractile cells, the method comprising: acquiring a series of images of the contractile cells; for each image in the series of images, computing a movement index characterizing the rate of change in mean absolute pixel intensity variations across the whole image; and using the movement index to assess the contractions of the contractile cells. Also, applications of the method to the study of cardiac tissue analogs and other cell cultures, and a culture system used to implement the method.