There is provided a tubular vitrigel composed of a laminate in which a plurality of plate-like vitrigels each having a through-hole are laminated in a thickness direction so that the through-holes are continuous.

A cell retention device includes a structured support with a plurality of circumferentially distributed ribs to retain the active filtering surface of a flexible, porous membrane filter medium. The filter medium surrounds the support in contact with the peaks of the ribs, thereby forming axial voids between the rib peaks. This arrangement imparts sufficient structural support over small regions of the filter medium to facilitate its use in a circular (or other rounded) configuration while providing sufficient channel volume to support high throughput of fluid sparse of cells.

An apparatus for enhancing bacterial sporulation can include a laminar flow chamber including multiple laminar flow tubes that smooth flow of coolant, a coolant input port that is coupled to the laminar flow chamber that supplies the coolant to the laminar flow chamber, a transparent tube section that is coupled to the laminar flow chamber and includes light-emitting diode (“LED”) light modules, the transparent tube section receives the smoothed flow of coolant from the laminar flow chamber, a culture solution tube that traverses through the laminar flow chamber and the transparent tube section, wherein a portion of the culture solution tube that is within the transparent tube section is surrounded by the coolant and is exposed to light from the LED light modules, and a culture solution input port that is coupled to the culture solution tube and supplies a culture solution to the culture solution tube.

The invention relates to a cell culture carrier comprising a first channel and a reservoir, where the first channel and the reservoir are formed in the interior of the cell culture carrier, where the first channel has an inlet opening in an outer side of the cell culture carrier and an outlet opening in the outer side of the cell culture carrier, where the reservoir has at least two openings arranged next to one another, where the first channel is connected to the reservoir by the at least two openings, and where the reservoir is connected to the outer side of the cell culture carrier by no other channel.

The method for analysis and cell culture comprises the following steps: generating a train (14) of ordered drops (16) in a carrier fluid (40), the train (14) of drops (16) comprising at least one culture drop (42), the culture drop (42) comprising a culture medium (50) and at least one cell (4), circulating the train (14) of drops (16) in a tube (10), incubating the train (14) of drops (16) in the tube (10), measuring at least one parameter indicative of the content of the culture drop (42) in the tube (10) at different times, recovering the culture drop (42) at one end (36) of the tube (10),

the steps being carried out in a controlled atmosphere (6).

The present disclosure relates generally to a tubing apparatus for separating and concentrating stem and stromal cells, also known as regenerative cells, from adipose tissue, more specifically to a defined process of extracting, separating and concentrating clinically useful regenerative cells from adipose tissue using a combination of mechanical disruption and filtration-centrifugation to obtain a highly enriched heterogeneous population of stem stromal cells. The centrifuge tube comprising a threaded top cap with male luer access port to be adapted to female luer of a syringe, a tapered main tubular barrel, a thin disk filter, and a bottom conical cap with luer access port for withdrawal of stem stromal cells via a syringe.

A gut bioreactor includes a fold region and a flow region. The fold regions include members that cooperate to form crypts. The members may have protuberances extending from a surface of the members into the crypts. The gut bioreactors may include multimaterial fibers that are configured to detect aspects of the crypts or may mechanically move portions of the gut bioreactor.

The present invention relates to a rotary rod for 3D bio-printing, in which the rotary rod is arranged horizontally and is driven to rotate, the rotary rod has a hollow structure and provided with at least one hole in a surface thereof, such that during a 3D bio-printing process, a nutrition solution passes through the hollow structure and a portion of the nutrition solution exudes via at least one hole. The present invention further provides a 3D bio-printing platform for supplying nutrition, comprising the rotary rod and a nutrition supply system, and a method of printing a tubular tissue using the bio-printing platform. The present invention, which reduces the possibility of resulting in tissue collapse from the effect of gravity, provides a new method of 3D bio-printing a tubular tissue and supplying nutrition in a printing process, with a wide application prospect.

The apparatuses described herein relate to preparation of a meat product. Apparatuses, systems comprising the apparatuses, and methods of making and use the systems and apparatuses are described herein. These are useful for controlling one or more of growth on and separation of a meat product from an enclosed substrate. The apparatuses and systems are configured to receive fluid and grow the meat product and/or separate the meat product from the substrate in a scalable manner.

Method and apparatus for biomass cultivation (preferably using algae) incorporating photo bio-reactor (PBR) technology coupled with a heat sink to increase energy efficiency. An external PBR array is coupled to an indoor storage tank system with a volume equal to or greater than the volume of the PBR array. A controller can be used to optimize the growth of biomass by optimizing three key growth parameters: exposure to sunlight, temperature and nutrients. The indoor tank system serves as a reservoir where algae can be protected from harsh ambient conditions, minimizing the cost of energy for heating and cooling that would normally be incurred to accommodate ambient temperature swings caused by weather if the biomass is always stored in an outdoor PBR array. During cold winter nights, the biomass can be brought indoors to conserve thermal energy. High energy efficiency can be achieved when the heat sink consists of a second holding tank and a second tubing array, and the swings in the ambient temperature are exploited to add or reject energy from the biomass cultivation.