The present invention relates to a fibrocartilage preparation method and fibrocartilage prepared by the method.

Methods to form a surface coating and surface pattern, which are based on adsorption of hydrocarbon chains that can be used with imaging optics to visualize macrophage fusion and multinucleated giant cell formation with living specimens are described.

The present disclosure provides compositions and methods for producing hydrogel matrix constructs. Methods of using hydrogel matrix constructs for tissue repair and regeneration and for the oxygenation of red blood cells are also disclosed.

The present disclosure relates to, at least, a vacuum-assisted method for infiltrating cadaver bone with a cryoprotectant and a method for rapidly warming the cryopreserved cadaver bone for bone marrow processing.

Described are devices for tethering biological materials, which in applicable embodiments support the growth and differentiation thereof. In a specific embodiment, the biological materials are cells and the cells grow/differentiate into tethered three-dimensional aggregates. The devices disclosed herein may be used in various methods/assays relating to tethered biological materials, such as to tethered three-dimensional aggregates of cells.

The method of culturing cells disclosed herein includes printing cells onto a substrate that includes cell adhesive regions and cell repulsive regions. The cells are suspended in a printing medium to create a cell suspension, and a volume of the cell suspension is loaded into a printer. A cell adhesive region of the substrate is aligned beneath the printing channel of the printer, and droplets of the cell suspension are dispensed from the printing channel directly onto the cell adhesive region. Contact of the dispensed droplets with cell repulsive regions of the substrate is limited, either by targeting of the droplets to the cell adhesive regions, by repulsions generated by the cell repulsive areas, or both. The cells adhere to the cell adhesive regions to create a cell pattern, and are maintained thereafter in a physiologically suitable environment.

The present invention relates to a process of preparation of a biomaterial comprising the steps of: a) Preparing a solution comprising at least one protein having a solubility in water superior or equal to about 10 mg/mL and at least one salt having solubility in water superior or equal to about 500 mg/mL, b) Evaporating the solution obtained in step a) as is, as a foam obtained by foaming the solution obtained in step a), or as a mixture thereof, at a temperature comprised of from 4 to 50° C. in atmospheric pressure or at lower temperatures under vacuum or at a pressure lower than atmospheric pressure, until the formation of two non-miscible phases or until obtaining a substantially dry solid, thereby obtaining a biomaterial.

The present invention also relates to a biomaterial obtainable by the process, and to the use of the biomaterial as a support for in vitro tissue engineering and/or for in vitro cell culture and in vitro expansion and/or as an implantable medical device, or as a drug.

A method and system for processing an adipose tissue material sample to create and collect fat aspirate particles having particle diameters less than or equal to a selected size are disclosed. A filter screen assembly having an interface part, a closed end opposite to the interface part, and a screen portion therebetween is inserted through a first port in a lid of a container, with the interface part providing access to an interior of the container for insertion of a transfer cannula connected to a syringe filled with the adipose tissue material. The screen portion includes a plurality of apertures having diameters of the selected size. Adipose tissue material is expelled from the transfer cannula through the apertures of the filter screen assembly into the container to create and collect the fat aspirate particles having particle diameters less than or equal to the selected size.

Disclosed herein is a method for covalent immobilization of molecular compounds on a substrate surface, comprising the steps: Providing a substrate surface; Treating the substrate surface with a plasma at atmospheric pressure, thereby generating an activated surface site; Exposing at least the activated surface site, or some fraction of the activated surface site, to molecular compounds, thereby establishing a covalent bond between the molecular compounds and the substrate surface.

A structured artificial construct that allows corneal endothelium to be regenerated from isolated cells outside the human or animal body is provided. The structured artificial construct is formed from a dome-shaped base body with a honeycomb structure formed in a concave side of the base body. Methods for generating the structured artificial construct are also provided.