In some embodiments, the present disclosure provides a method for fabricating a three-dimensional artificial cardiac patch construct. In some embodiments, such method includes the steps of coating a substrate with an organic polymer; allowing the organic polymer coating to air dry; mounting anchors on the organic polymer coating; and sterilizing the organic polymer coating and the anchors. In further embodiments, the method includes the steps of forming a biodegradable gel-based support scaffold on top of the organic polymer coating and seeding the biodegradable gel-based support scaffold with neonatal cardiac cells. In yet further embodiments, the method comprises culturing the neonatal cardiac cells in vitro to form a real cardiac layer, under culture conditions that are suitable for the cells to self-organize into a monolayer and detach from the substrate to form the three-dimensional cardiac patch. In some embodiments, the present disclosure pertains to a method of treatment of cardiac tissue injury in a subject in need thereof. In some embodiments, the method includes implanting the three-dimensional artificial cardiac patch described above in the injured area of the subject. In another embodiment the present disclosure provides a composition comprising the three-dimensional artificial cardiac patch described above. Additional embodiments of the present disclosure pertain to a medicament including the three-dimensional artificial cardiac patch described above.

The present invention relates to a micro-fluid chip for blood vessel formation. The micro-fluid chip of the present invention is constituted by first to fifth channels arranged adjacent to one another on a substrate in sequence, and two or more micro-structures or micro-posts having a gap therebetween are disposed on the interface that each channel forms together with an adjacent channel while contacting the same. Each channel performs a fluidic interaction with a different channel through the gap formed by the micro-structures, and biochemical materials can move therethrough. The micro-fluid chip, according to the present invention, provides a micro-blood vessel having a flat and continuous blood vessel interface outside a body. Furthermore, cancer angiogenesis, cancer intravasation, and cancer extravasation can be modeled using the micro-fluid chip of the present invention. In addition, the micro-fluid chip of the present invention can be used to screen candidate anti-cancer drugs.

The invention relates to a method for manufacturing a bio-ink by additive deposition, which comprises supplying: a first solution including between 5 and 40 wt. % gelatin; a second solution including between 15 and 35 .wt. % alginate; a third solution including between 1 and 15 wt. % fibrinogen, and optionally living cells in suspension; and creating a mixture including: around 35 to 65 vol. % of the first solution; around 15 to 35 vol. % of the second solution; and around 15 to 35 vol. % of the third solution, said proportions being selected so that they add up to 100%. Said bio-ink allows the additive deposition of objects that can be polymerised by means of a solution including calcium ions and thrombin. Said objects can be incubated and can be used as a substitute for body tissue, for example (with added fibroblasts) as skin substitute.

Tissue engineered constructs and methods for fabricating the disclosed constructs are provided. Some of the disclosed tissue engineered constructs are designed to fill a void in the body due to surgical resection, for example from mastectomy or lumpectomy, wounds and the like. Some disclosed constructs comprise one or more projections designed to mimic the appearance of a structural feature when implanted into a host.

A high-throughput, high-content assay to screen for an agent which overcomes remyelination inhibition by an extrinsic inhibitor.

The present disclosure generally relates, in certain aspects to cultivated meat and other cultivated animal-derived products. In some embodiments, the cultivated meat product comprises a fat replica, muscle replica, and a cell lysate. e.g., forming a tissue mass. The muscle replica may comprise microcarriers and non-human muscle cells. The fat replica may comprise a fat emulsion and non-human blood plasma. The lysate may comprise a lysate of non-human red blood cells. In some cases, these may form a cultivated meat product, for example, a ground beef replica. Other embodiments are generally directed to methods of making or using such fat replicas, the microcarriers, or the cultivated meat products, kits involving these, or the like.

The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.

In some embodiments, the present disclosure provides a method for fabricating a three-dimensional artificial cardiac patch construct. In some embodiments, such method includes the steps of coating a substrate with an organic polymer; allowing the organic polymer coating to air dry; mounting anchors on the organic polymer coating; and sterilizing the organic polymer coating and the anchors. In further embodiments, the method includes the steps of forming a biodegradable gel-based support scaffold on top of the organic polymer coating and seeding the biodegradable gel-based support scaffold with neonatal cardiac cells. In yet further embodiments, the method comprises culturing the neonatal cardiac cells in vitro to form a real cardiac layer, under culture conditions that are suitable for the cells to self-organize into a monolayer and detach from the substrate to form the three-dimensional cardiac patch. In some embodiments, the present disclosure pertains to a method of treatment of cardiac tissue injury in a subject in need thereof. In some embodiments, the method includes implanting the three-dimensional artificial cardiac patch described above in the injured area of the subject. In another embodiment the present disclosure provides a composition comprising the three-dimensional artificial cardiac patch described above. Additional embodiments of the present disclosure pertain to a medicament including the three-dimensional artificial cardiac patch described above.

The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.

The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.