A filter unit for a mixing apparatus includes a hydrophilic filter and a hydrophobic vent filter. The hydrophilic filter is configured to receive a fluid including a liquid and gas. The hydrophilic filter is further configured to sterilize the liquid. The hydrophobic vent filter is configured to receive the gas from the hydrophilic filter. The hydrophobic vent filter further includes a vent and a membrane configured to separate an interior of the filter unit from an exterior of the filter unit, the gas being vented from the filter unit by flowing across the membrane and out of the vent. In some embodiments, the filter unit further includes a defoaming device configured to receive gas, foam comprised the liquid containing trapped gas, and some of the liquid from the hydrophilic filter and is further configured to release at least some of the gas from the foam.

Disclosed herein are details of a hermetically or aseptically sealed bioreactor. The bioreactor comprises a bioreactor chamber, a membrane wall, a scaffold structure, a linear actuator, a linear transfer means, and a control system. Use of the bioreactor permits the inner scaffold structure to be moved and manipulated while still preserving a hermetic or aseptic seal inside the bioreactor chamber during operation.

The invention relates to a tubing device for sterile media including a container for storing sterile media, a discharge port for discharging liquid sterile media, an inlet port for introducing fluid into the tubing device and a multiple-way-connector. The multiple-way-connector is connected to the container, the discharge port, the inlet port, and an apparatus for preparing, mixing and discharging a sterile medium for use with a tubing device, including a water inlet port for introducing water, a water outlet port configured to be connected to the inlet port of the tubing device, a fluid pump for conveying the fluid, the fluid pump is connected to the fluid inlet port and the water outlet port and a container support for supporting the container of the tubing device.

The present set of embodiments relate to a system, method, and apparatus for hydrating and mixing a liquid medium from a dry medium. Such systems, methods, and apparatuses can be used in the biotech industry because they can be used to provide prepackaged dry media in a format that can be quickly rehydrated free of issues with operator error found in more conventional media rehydration systems using mixing tanks and reactors.

A target particle transferring device is disclosed, which comprises: (a) a substrate with a thickness of T and a width of W, having top and bottom portions, the top portion having a top surface and the bottom portion having a bottom surface; (b) a notch structure formed in the bottom portion of the substrate, comprising: a groove with a width of W1, located at a distance oft below the top surface of the substrate, wherein the groove is formed in the bottom portion from the bottom surface extending toward the top portion; and (c) a target substrate portion with a width of W2 and a thickness of T, located in the top and bottom portions of the substrate and being surrounded by the groove. Methods of transferring a target particle from one device to another is also disclosed.

The present disclosure relates to agarose and methylcellulose storage and transport mediums, systems for cell storage and transport, and cell storage and transport methods. The instantly-disclosed agarose and methylcellulose storage and transport medium is ideally suited for 3D spheroid cell culture storage and transport. In particular aspects, the storage and transport mediums, systems, and methods are used in combination with or performed in labware that combine 3D spheroid culture with a gas permeable, micro-patterned design that allows for protection and prolonged maintenance of spheroid cell (e.g. hepatocytes) viability and functionality during storage and transport.

This disclosure provides a method of fingerprinting and analyzing cell culture samples using Raman spectroscopy to detect cell culture media preparation errors, degradation, or other changes in the media that may render it suboptimal for cell culture use.

The present invention relates to a method for decomposing peracetic acid and a method for culturing microorganisms using the decomposition method. The cultivation of microorganisms using the method of the present invention allows an effective removal of the peracetic acid used in a culture medium for sterilization.

Embodiments of the present disclosure can include a method for convective intracellular delivery including providing cells and molecules to a microchannel having compressive surfaces, wherein the compressive surfaces define compression gaps having a height of from 20 and 80% of the average cell diameter, and a plurality of relaxation spaces disposed between the compressive surfaces, flowing the cell medium through the microchannel, wherein as the cell medium flows through the microchannel, the plurality of cells undergo a convective intracellular delivery process comprising: compressing the plurality of cells, wherein the compressing causes the plurality of cells to undergo a loss in intracellular volume V.sub.loss, and passing the plurality of cells to a first relaxation space, wherein the plurality of cells undergo a gain in volume V.sub.gain and absorb a portion of the plurality of molecules.

A filter unit for a mixing apparatus includes a hydrophilic filter and a hydrophobic vent filter. The hydrophilic filter is configured to receive a fluid including a liquid and gas. The hydrophilic filter is further configured to sterilize the liquid. The hydrophobic vent filter is configured to receive the gas from the hydrophilic filter. The hydrophobic vent filter further includes a vent and a membrane configured to separate an interior of the filter unit from an exterior of the filter unit, the gas being vented from the filter unit by flowing across the membrane and out of the vent. In some embodiments, the filter unit further includes a defoaming device configured to receive gas, foam comprised the liquid containing trapped gas, and some of the liquid from the hydrophilic filter and is further configured to release at least some of the gas from the foam.