Abstract: The invention provides isolated achromosomal dynamic active systems (ADAS), including ADAS comprising secretion systems. These ADAS provided by the invention can be obtained by a variety of means. Various associated methods of making and using these ADAS are provided.

Abstract: Described are devices and methods for use in connection with organ replacement or organ assist therapy in a patient.

Abstract: The invention provides isolated achromosomal dynamic active systems (ADAS), including highly active ADAS. These ADAS provided by the invention can be obtained by a variety of means. Various associated methods of making and using these ADAS are provided.

Abstract: Methods of tissue engineering, and more particularly methods and compositions for generating various vascularized 3D tissues, such as 3D vascularized embryoid bodies and organoids are described. Certain embodiments relate to a method of generating functional human tissue, the method comprising embedding an embryoid body or organoid in a tissue construct comprising a first vascular network and a second vascular network, each vascular network comprising one or more interconnected vascular channels; exposing the embryoid body or organoid to one or more biological agents, a biological agent gradient, a pressure, and/or an oxygen tension gradient, thereby inducing angiogenesis of capillary vessels to and/or from the embryoid body or organoid; and vascularizing the embryoid body or organoid, the capillary vessels connecting the first vascular network to the second vascular network, thereby creating a single vascular network and a perfusable tissue structure.

Abstract: Aspects of the present invention provide improved methods and apparatus for use in in vitro modeling of the interaction of cells with cellular constructs/parts/axons, including axon mimetics and use of three-dimensional fibers.

Abstract: A 3D printed tubular construct, such as a nephron, with or without embedded vasculature as well as methods of printing tubular tissue constructs are described.

Abstract: Described are methods of enhancing development of renal organoids, methods of using the same, and kits.

Abstract: A 3D printed tubular construct, such as a nephron, with or without embedded vasculature as well as methods of printing tubular tissue constructs are described.

Abstract: Described are methods for producing multi-layered tubular tissue structures, tissue structures produced by the methods, and their use.

Abstract: Aspects of the present invention provide improved methods and apparatus for use in in vitro modeling of the interaction of cells with cellular constructs/parts/axons, including axon mimetics and use of three-dimensional fibers.

Abstract: Described are devices and methods for use in connection with organ replacement or organ assist therapy in a patient.

Abstract: A printed tissue construct comprises one or more tissue patterns, where each tissue pattern comprises a plurality of viable cells of one or more predetermined cell types. A network of vascular channels interpenetrates the one or more tissue patterns. An extracellular matrix composition at least partially surrounds the one or more tissue patterns and the network of vascular channels. A method of printing a tissue construct with embedded vasculature comprises depositing one or more cell-laden filaments, each comprising a plurality of viable cells, on a substrate to form one or more tissue patterns. Each of the one or more tissue patterns comprises one or more predetermined cell types. One or more sacrificial filaments, each comprising a fugitive ink, are deposited on the substrate to form a vascular pattern interpenetrating the one or more tissue patterns. The vascular pattern and the one or more tissue patterns are at least partially surrounded with an extracellular matrix composition.

Abstract: A printed tissue construct comprises one or more tissue patterns, where each tissue pattern comprises a plurality of viable cells of one or more predetermined cell types. A network of vascular channels interpenetrates the one or more tissue patterns. An extracellular matrix composition at least partially surrounds the one or more tissue patterns and the network of vascular channels. A method of printing a tissue construct with embedded vasculature comprises depositing one or more cell-laden filaments, each comprising a plurality of viable cells, on a substrate to form one or more tissue patterns. Each of the one or more tissue patterns comprises one or more predetermined cell types. One or more sacrificial filaments, each comprising a fugitive ink, are deposited on the substrate to form a vascular pattern interpenetrating the one or more tissue patterns. The vascular pattern and the one or more tissue patterns are at least partially surrounded with an extracellular matrix composition.

Abstract: A 3D printed tubular construct, such as a nephron, with or without embedded vasculature as well as methods of printing tubular tissue constructs are described.

Abstract: Methods of tissue engineering, and more particularly methods and compositions for generating various vascularized 3D tissues, such as 3D vascularized embryoid bodies and organoids are described. Certain embodiments relate to a method of generating functional human tissue, the method comprising embedding an embryoid body or organoid in a tissue construct comprising a first vascular network and a second vascular network, each vascular network comprising one or more interconnected vascular channels; exposing the embryoid body or organoid to one or more biological agents, a biological agent gradient, a pressure, and/or an oxygen tension gradient, thereby inducing angiogenesis of capillary vessels to and/or from the embryoid body or organoid; and vascularizing the embryoid body or organoid, the capillary vessels connecting the first vascular network to the second vascular network, thereby creating a single vascular network and a perfusable tissue structure.

Abstract: Aspects of the present invention provide improved methods and apparatus for use in in vitro modeling of the interaction of cells with cellular constructs/parts/axons, including axon mimetics and use of three-dimensional fibers.

Abstract: A printed tissue construct comprises one or more tissue patterns, where each tissue pattern comprises a plurality of viable cells of one or more predetermined cell types. A network of vascular channels interpenetrates the one or more tissue patterns. An extracellular matrix composition at least partially surrounds the one or more tissue patterns and the network of vascular channels. A method of printing a tissue construct with embedded vasculature comprises depositing one or more cell-laden filaments, each comprising a plurality of viable cells, on a substrate to form one or more tissue patterns. Each of the one or more tissue patterns comprises one or more predetermined cell types. One or more sacrificial filaments, each comprising a fugitive ink, are deposited on the substrate to form a vascular pattern interpenetrating the one or more tissue patterns. The vascular pattern and the one or more tissue patterns are at least partially surrounded with an extracellular matrix composition.

Abstract: Nanocarriers and methods of preparation and use of nanocarriers are presented. In some embodiments, a nanocarrier composition comprises an organic liquid comprising a plurality of nanoparticles dispersed therein; and a coating material disposed around the exterior surface of the organic liquid. Biological tissue may be imaged or treated by coming into contact with a nanocarrier composition, and, at least in some embodiments, irradiated.

Abstract: Methods of combined ultrasound and photoacoustic imaging are provided. In some embodiments, the methods may be used to determine the location or positioning of a metal object in a sample. In other embodiments, the methods may be used to determine the composition of a sample surrounding a metal object. Other methods are also provided.

Abstract: Nanocarriers and methods of preparation and use of nanocarriers are presented. In some embodiments, a nanocarrier composition comprises an organic liquid comprising a plurality of nanoparticles dispersed therein; and a coating material disposed around the exterior surface of the organic liquid. Biological tissue may be imaged or treated by coming into contact with a nanocarrier composition, and, at least in some embodiments, irradiated.