Multiplanar microfluidic devices are provided that facilitate direct transverse fluid communication between a first microfluidic channel a plurality of adjacent microfluidic channels, where the adjacent microfluidic channels reside both laterally adjacent and vertically adjacent to the first microfluidic channel, thereby facilitating transverse diffusion to or from the adjacent microfluidic channels in both lateral and vertical directions. Geometrical meniscus-pinning features, such as meniscus-pinning ridge structures, are provided between adjacent microfluidic channels to restrict transverse flow between the microfluidic channels. Accordingly, a gel structure may be formed within the first microfluidic channel and one or more of the adjacent microfluidic channels can function as a perfusion channel, for example, for delivering media to cells residing withing the gel structure. Such devices may be extended and/or arrayed to include multiple channels with laterally and vertically adjacent perfusion microfluidic channels, optionally with shared lateral perfusion microfluidic channels among adjacent pairs of devices.

The present application provides methods for stimulating an immune response in an individual comprising administering a composition of nucleated cells (e.g., PBMCs) comprising an intracellular exogenous antigen in conjunction with administering an immunoconjugate comprising a variant IL-2 polypeptide and a second polypeptide. The variant IL-2 polypeptide exhibits reduced affinity to the α-subunit of the IL-2 receptor. The second polypeptide targets a tumor cell or a T cell.

Provided is a method for the selective differentiation into M1 macrophages under a pressurized environment, and more particularly, a method for the selective differentiation of undifferentiated macrophages into M1 macrophages, the method including incubating the undifferentiated macrophages in an incubator under the pressurized environment. In addition, provided is a method for producing osteoclasts, the method including: incubating undifferentiated macrophages in an incubator under a pressurized environment to differentiate into M1 macrophages; and differentiating the differentiated M1 macrophages into osteoclasts.

Efficient harvesting of cells, cell fragments, free nuclei, and DNA material from female reproductive system is made possible by processing gelatinous part of cervical mucus. Rinsing may be used to separate the gelatinous part of cervical mucus from the remainder of the cervical mucus sample.

A microfluidic device in which microfluidic channels are embedded in a culture medium chamber and have open sides. The microfluidic device is patterned with a fluid moved along a hydrophilic surface due to capillary force, and the fluid may be rapidly and uniformly patterned along an inner corner path and a microfluidic channel. In the microfluidic device, the microfluidic channel is connected to facilitate fluid flow with a culture medium through open sides thereof and openings, and thus may provide a cell culture environment in which high gas saturation is maintained. In addition, several microfluidic devices formed on one common substrate are described. Such microfluidic devices may be manufactured of a hydrophilic engineering plastic by injection molding.

Methods for obtaining purified populations of megakaryocytes and platelets by ex vivo culture of stem cells are provided herein.

The present invention relates to a method for manipulating the high mannose glycoform content of recombinant glycoproteins by regulating ornithine metabolism during cell culture.

A method for dissociating cell aggregates in an agitated reactor. The method comprises providing a cell culture comprising cell aggregates in the agitated reactor, contacting the cell aggregates with a dissociation reagent, generating a dissociation force in the agitated reactor and exposing the contacted cell aggregates to the generated dissociation force under conditions sufficient to dissociate the contacted cell aggregates. The method may be used in a process for passaging cells and/or generating dissociated differentiated cells from stem and/or progenitor cells.

Methods for introducing exogenous material into a cell are provided, which include exposing the cell to a transient decrease in pressure in the presence of the exogenous material. Also provided are devices for performing the method of the invention.

The invention relates to implantable systems for repairing and restoring cartilage. The invention provides methods and products for cartilage repair that use universal chondrocytes. A universal cell line includes cells such as universal chondrocytes that are not immunogenic or allergenic and can be grown in products suitable for use in a number of different people. Use of the universal chondrocytes allows for new processes and products. Where prior art autologous neocartilage constructs required many small reactors (e.g., at least one culture dish per patient to grow one 34 mm disc per patient), using a universal cell line allows, for example, one large batch of cartilage or neocartilage to be made under uniform conditions.