Abstract: A cell culture insert for use in culturing cells to promote the formation of spheroids and methods of using these spheroid-promoting cell culture inserts. The cell culture insert includes a porous membrane and one or more sidewalls that are non-adherent to cells and cause the cells in the insert to associate with each other and form spheroids.

Abstract: A multilayered cell culture apparatus for the culturing of cells is disclosed. The cell culture apparatus is defined as an integral structure having a plurality of cell culture chambers in combination with tracheal space(s). The body of the apparatus has imparted therein gas permeable membranes in combination with tracheal spaces that will allow the free flow of gases between the cell culture chambers and the external environment. The flask body also includes an aperture that will allow access to the cell growth chambers by means of a needle or cannula. The size of the apparatus, and location of an optional neck and cap section, allows for its manipulation by standard automated assay equipment, further making the apparatus ideal for high throughput applications.

Abstract: A cell monitoring plate comprises a flat surface on which multiple cell culturing vessels may be stacked. The flats surface has multiple optical imaging systems embedded therein to fully image a cell culture vessels stacked on the plate. Each one of the multiple optical imaging systems provides both illumination and imaging through a single aperture in the surface of the monitoring plate.

Abstract: A multilayered cell culture apparatus for the culturing of cells is disclosed. The cell culture apparatus is defined as an integral structure having a plurality of cell culture chambers in combination with tracheal space(s). The body of the apparatus has imparted therein gas permeable membranes in combination with tracheal spaces that will allow the free flow of gases between the cell culture chambers and the external environment. The flask body also includes an aperture that will allow access to the cell growth chambers by means of a needle or cannula. The size of the apparatus, and location of an optional neck and cap section, allows for its manipulation by standard automated assay equipment, further making the apparatus ideal for high throughput applications.

Abstract: An ex vivo cell culture sustained release composition, including: a mixture comprising: a sustenant; and a non-biodegradable binder; and a non-biodegradable and water insoluble encapsulant coat that encapsulates the mixture, as defined herein. Also disclosed is a method for sustainably providing a sustenant to a cell culture in aqueous media, including contacting a cell culture with the sustained release composition.

Abstract: Various implementations of a system and method for analyzing extracellular vesicles (EVs) are disclosed having a number of innovative features. In one implementation, a method for analyzing EVs includes binding EVs to an optical waveguide biosensor and phenotyping the bound EVs. Phenotyping can include binding a labeled ligand to the EVs and/or rupturing the EVs and analyzing their cargo. In another implementation, a system for analyzing EVs includes EVs bound to an optical waveguide biosensor and a labeled ligand bound to the EVs. In another implementation, a kit for analyzing EVs includes a micro plate having wells containing optical waveguide biosensors functionalized with a binding agent configured to bind to EVs and at least one of: (a) labeled ligands configured to bind to the extracellular vesicles or (b) a reagent configured to rupture the extracellular vesicles.

Abstract: Multi-layer cell culture devices and systems for culturing suspension and adherent cells via continuous gravity flow of culture media without the use of motorized equipment minimize the risk of contamination of the cell culture. A multi-layer cell culture device includes at least first and second chambers configured to contain fluid and to be fluidly connected such that fluid in the first chamber unidirectionally and continuously flows by gravity flow from the first chamber and into the second chamber. A multi-layer cell culture device can further include a third chamber configured to contain fluid and positioned below the second chamber such that fluid in the second chamber unidirectionally and continuously flows by gravity flow from the second chamber and into the third chamber. Methods of culturing cells using these devices and systems are also described.

Abstract: A pipette structure (160B) includes first and second body sections (164, 166) connected at a junction and including first and second fluid passages, respectively, with the pipette structure including (i) a bellows joint (165) permitting pivotal movement between the first and second body sections (164, 165), and/or (ii) the second fluid passage of the second body section includes greater width dimension at a sample introduction end than a width dimension at the junction. Such a pipette structure may be embodied in a unitary measuring pipette or an extension tip device for a measuring pipette. A method is provided for transferring material between an interior of a cell culture housing that includes a structured surface defining an array of microwells suitable for three-dimensional culture of multi-cell aggregates and an external environment. A method for fabricating a pipette structures is further provided.

Abstract: A cell culture vessel includes a vessel body, support columns, and a stabilizer device. The vessel body defines a cell culture chamber enclosed between a bottom wall and a top wall. The support column is within the cell culture chamber and extends between the top wall and the bottom wall. The stabilizer device covers a width and length of the cell culture chamber and has a column engaging structure that is sized to slidingly engage the support column such that the stabilizer device is movable along the support column as a liquid culture medium is received in the cell culture chamber. The support column guides the stabilizer device along a length of the support column as the stabilizer device rises with rising liquid level in the cell culture chamber during a liquid culture medium filling operation.

Abstract: A structured bag for cell culture is provided herein. The structured bag includes a top portion, a bottom portion having a shape, and a sidewall extending between the top portion and the bottom portion and at least partially defining an interior compartment for receiving fluid. The bottom portion is configured to maintain the shape to support the structured bag such that the structured bag is free standing when placed on a surface.

Abstract: A pipette may comprise a length, a longitudinal axis, and an inner curved surface enclosing a space. The pipette may have a tip region having a tip thickness. The tip region may be connected to a body region having a body thickness. The tip thickness may be greater than the body thickness. The body region may be connected to a mouth region having a mouth thickness. The mouth thickness may be greater than the body thickness. The inner curved surface may not contain bumps or ridges either between the tip region and the body region or between the body region and the mouth region. The pipette may be formed by blow molding or vacuum forming.

Abstract: A cell culture apparatus includes a cell culture module including multiple cell culture chambers. A manifold connects the multiple cell culture chambers together along a side of the cell culture module. The manifold includes a side wall base structure connected to the side of the cell culture module and a column structure that is formed as a monolithic part of the side wall base structure. The column structure defines a fluid flow pathway through the manifold and to inlets to the cell culture chambers to allow filling and emptying of the cell culture chambers of liquid medium.

Abstract: An article including either a frame having an interior cavity, and a flexible liner situated within the interior cavity; or a deformable frame having an interior cavity. Either frame can receive a sample, such as liquid having suspended live cells, and cooling freezes the sample to a solid sample. The solid sample can be readily ejected from the article having either a frame with the flexible liner, or the deformable frame, without extensive thawing. The solid sample can be rapidly displaced from the article.

Abstract: A microcavity dish (10) for cultivating cells includes a dish body including a sidewall (16) that encloses a cell culture chamber within the dish body. The dish body has a top and a bottom (12). The bottom includes a cell culturing substrate comprising an array of microcavities (46). The sidewall includes a transition portion (30) that divides the sidewall into an upper portion and a lower portion that is offset inward relative to the upper portion defining a liquid medium delivery surface (26) that extends at least partially along an interior surface (28) of the sidewall and slopes toward the bottom.

Abstract: A fluidic device for culturing cells includes a microplate and plate lid. The microplate includes multiple wells and channels, the channels extending between the wells such that the channels interconnect the wells. The plate lid releasably engages the microplate to thereby enclose the wells and the channels The wells include a culture surface such that a cell culture medium received therein is deposited over the culture surface. At least one channel that extends between adjacent ones of the wells is spaced from the culture surfaces of the adjacent wells defining a gap between the at least one channel and the culture surfaces of the adjacent wells for collection of the cell culture medium.

Abstract: A remote monitoring system configured to non-invasively measure a cell culture is provided. The system includes a plurality of cell culture layers comprising a cell culture chamber configured to operate as a closed-system, the at least one cell culture chamber having at least one surface to which cells adhere. The system further includes at least one monitoring layer comprising an outer wall surrounding a monitoring layer cell culture chamber configured to operate as a closed-system and having at least one surface to which cells adhere, the at least one monitoring layer comprising at least one indentation in the outer wall. The system also includes at least one monitoring module disposed in at least one of the at least one indentation and comprising at least one of a confluence monitor and an analyte monitor.

Abstract: The present disclosure relates to methods for evaluating the interaction of a candidate compound on 3D hepatocyte spheroid in an invitro culture, including evaluating the metabolism of a candidate compound, for use in various biochemical and molecular biology studies. The methods are performed in labware that combine 3D spheroid culture with micro-patterned design that allows for multiple to several hundreds of spheroids to be treated under the same conditions and to produce sufficient materials (e.g., parent drug, drug metabolites, DNA, RNA, and proteins from cells) and higher detection signal intensity for ADME/Tox (absorption, distribution, metabolism, excretion and toxicity) studies. The methods allow for, among other uses, the investigation and generation of accurate invitro intrinsic clearance data and thus more accurate prediction of in vivo clearance, particularly with low clearance compounds.

Abstract: A spheroid cell culture article including: a chamber including: an opaque side wall surface; a top aperture; and a gas-permeable, liquid impermeable bottom including at least one concave surface, wherein at least a portion of the bottom is transparent, wherein at least a portion of the bottom includes a low-adhesion or no-adhesion material in or on the at least one concave surface, and wherein the gas permeable, liquid impermeable bottom includes polystyrene.

Abstract: A cell separation device configured for separating cells from microcarriers or spheroids in a liquid is provided. The cell separation device includes a vessel comprising a first port, a second port, and a cavity; and a porous mesh disposed within the cavity to divide the cavity into a first compartment and a second compartment, wherein the first port is in communication with the first compartment of the cavity, the first port located to a first side of the porous mesh, wherein the second port is in communication with the second compartment of the cavity, the second port located to a second side of the porous mesh, and wherein the porous mesh is positioned within the cavity to have a substantially vertical orientation or an inclined orientation with respect to a flow of liquid through the porous mesh.

Abstract: A cell monitoring plate comprises a flat surface on which multiple cell culturing vessels may be stacked. The flats surface has multiple optical imaging systems embedded therein to fully image a cell culture vessels stacked on the plate. Each one of the multiple optical imaging systems provides both illumination and imaging through a single aperture in the surface of the monitoring plate.