An object of the present invention is to provide an artificial tissue perfusion device capable of analyzing the interaction between a vascular cell layer and a parenchymal cell layer with high accuracy. An artificial tissue perfusion device includes a co-culture system (C) in which a plurality of types of cell are cultured. The co-culture system has a tubular well part (10) having a culture space (11) inside; a base material (20) having a perfusion flow path (26) which extends in a predetermined direction and is perfused with a medium, and a holding part (23) which opens to the perfusion flow path and holds the well part attachably and detachably; and a gel membrane (30) having a form of a porous membrane and disposed at an end portion of the well part facing the perfusion flow path in a case where the well part is held by the holding part. A tissue-based cell is cultured on a surface side of the gel membrane facing the culture space, and a luminal cell is cultured on a surface side of the gel membrane facing the perfusion flow path.

A liquid thickness of a medium in a culture bag used in cell culture can be controlled. A liquid thickness controlling mechanism that controls the liquid thickness of the medium filled in the culture bag provided with at least one port and formed of a soft packing material includes a detection portion that measures a change caused by a change in the liquid thickness of the medium and a control portion that controls operation of liquid delivery means disposed in a tubular member connecting the culture bag and a medium bag based on detection information inputted from the detection portion so as to control delivery of the medium between the culture bag and the medium bag. Using the liquid thickness controlling mechanism makes it possible to control the liquid thickness of the medium in the culture bag being used.

Systems and methods for algae cultivation and, more particularly, systems and methods for controlling algae cultivation water slurry temperature to optimize algae facility production and facilitation of algae facility commercial deployment in a wide spectrum of environmental locations. Thermal reservoirs comprising temperature-based, phase-transitioning material(s) are integrated with algae cultivation vessels to provide temperature control of cultivating algae slurries.

Described herein are methods and systems for cell processing or, more specifically, for introducing various payloads into cells. These methods and systems use a mechanoporation approach in which cells are rapidly compressed and then released to relax while absorbing the payload. More specifically, these methods and systems enable high-throughput mechanoporation with various clogging mitigation features. A cell processing apparatus comprises a shell with an inner shell cylindrical surface, a core with an outer core cylindrical surface, and ridges, supported on and protruding away from one of the inner shell cylindrical surface and the outer core cylindrical surface. The core is disposed inside the shell. The outer core cylindrical surface is concentric with the inner shell cylindrical surface. Each of the ridges forms a ridge gap with the other one of the inner shell cylindrical surface and the outer core cylindrical surface.

A small-volume liquid container for dispensing a liquid medium, especially biological medium, into a bioprocessing system, especially into a bioreactor, wherein the liquid container provides an accommodation volume for the liquid medium, wherein the liquid container comprises two dimensionally stable container parts, which are movable relative to one another between an initial position and an end position, and an outlet connection for discharge of the liquid medium. It is proposed that the liquid container comprises a shape-changeable delimitation means which at least sectionally delimits the accommodation volume and which is connected to the dimensionally stable container parts in such a way that a relative movement of the dimensionally stable container parts to one another, causing a change in volume of the accommodation volume, is associated with a change in shape of the delimitation means.

A device for seeding cells includes a container with a wall, a bottom and a lid. The wall extends between the bottom and the lid. The container can be equipped to be loaded with cells, in particular with cells form a cell suspension. The container defines a rotation axis. The device is further equipped to rotate the container around the rotation axis. The container includes a structured surface that can be arranged at the inner surface of the container. The structured surface has structures equipped to receive the cells. The rotation exerts a (g-)force in direction of the structured surface, such that the g-force acts perpendicular to the structured surface. The exerted force in the direction of the structured surface resembles a g-force required for sedimentation of the cells into the structures.

The invention relates to a process and equipment for cultivating and producing a biomass from microalgae, primarily plankton. A microalgal biomass is cultivated in a single bioreactor chamber in the shape of a vertically oriented parallelepiped. The culture mixture is illuminated by artificial light sources mounted on the inner side of one of the broad walls of the bioreactor chamber in horizontal rows throughout the height of the bioreactor chamber. The culture mixture is illuminated cyclically. Spray heads are mounted on the inner side of the opposite wall of the bioreactor chamber so that 4 spray heads are arranged symmetrically around each artificial light source. The pH value of the culture mixture is maintained in a range of 8.5-9.5 by the addition thereto of a lactic acid bacteria-containing solution at the beginning of each light cycle in an amount of 1-3 ml per litre of culture mixture, said solution having a pH value selected in a range of 4.0-5.0.

A bioreactor system having an expanding volume is provided. The system includes a bioreactor assembly comprising a plurality of bioreactors including at least a first bioreactor and a second bioreactor proximate the first bioreactor. The bioreactor system further includes a first gate between the first bioreactor and the second bioreactor such in a first configuration the gate is closed and the first bioreactor is isolated from the second bioreactor and in a second configuration the gate is open and the first bioreactor is contiguous with the second bioreactor and media and cells form a homogenous mixture within a combined volume formed by the first bioreactor in combination with the second bioreactor. The bioreactor system may further include a microdispenser for each of the plurality of bioreactors for controlling dispensement of media into each of the plurality of bioreactors.

This disclosure provides a tissue-engineered transcatheter vein valve and methods of making such a tissue-engineered transcatheter vein valve. Methods of making the valve include casting or molding a polymer into a tubular structure having a first end and a second end, where the first end of the tubular structure is cast or molded around a tubular support structure and where the second end of the tubular structure is cast or molded in the absence of the support structure; everting the polymer at the second end through the support structure; anchoring the second end of the tubular structure to the support structure at a first position and a second position, where the anchored first position and the anchored second position result in commissures, forming leaflets therebetween.

A gliding wave reactor includes a base, a tank, a suspension bracket, and an actuator. The tank is configured to hold a liquid. The suspension bracket is configured to suspend the tank over the base. The actuator is fixed to the base and configured to move the tank to create an environment in the liquid for cultivating marine life.