In some aspects, fusosome compositions and methods are described herein that comprise membrane enclosed preparations, comprising a fusogen. In some embodiments, the fusosome can the target cell, thereby delivering complex biologic agents to the target cell cytoplasm.

Described herein are genetically modified cells derived from a human cell and which contain at least one exogenous transcription unit inserted into at least one of four open chromatin regions (OCRs) located on Chromosomes 2, 5, 8 and 12, as well as compositions, pharmaceutical preparations, and implantable devices comprising the genetically modified cells, and methods of using the same for preventing or treating a disease, disorder, or condition.

Methods of forming, dissolving, and functionalizing an extracellular matrix gel on demand based on cross-linking, modification, and dissolution of hydrogels using transpeptidase (e.g. sortase) are disclosed. Also provided are hydrogels comprising one or more macromers crosslinked to a mixture of peptides, wherein all or a portion of the peptides in the mixture comprise a recognition motif cleavable by a transpeptidase (e.g., sortase).

Described herein are oral delivery systems for use in delivering live mammalian cells to the intestinal tract of an individual.

Thin film devices, e.g., multilayer thin film devices, that encapsulate cells for transplantation into a subject are provided. Also provided are methods of using and methods of preparing the subject devices. The thin film devices include a first porous polymer layer and a second porous polymer layer that define a lumen therebetween and encapsulate a population of cells within the lumen. The thin film devices can promote vascularization into the lumen of the device via the pores in the first polymer layer and/or second polymer layer; limit foreign body response to the device; limit ingress of cells, immunoglobulins, and cytokines into the lumen via the first and the second polymer layers; and release from the first polymer layer and/or the second polymer layer molecules secreted by the population of cells.

Micro-Organospheres, including Patient-Derived Micro-Organospheres (PMOSs), apparatuses and methods of making them, and apparatuses and methods of using them. Also described herein are methods and systems for screening a patient using these Patient-Derived Micro-Organospheres, including personalized therapies.

This document relates to bioengineering and involves bioengineered thymus organoids and related humanized animal models. The thymus organoids and animal models have various commercial and clinical uses, including generating humanized antibodies, making antigen-specific human T cells, inducing transplantation tolerance, rejuvenating thymus functions, and modeling human diseases.

The application relates to the use of loaded red blood cells (e.g. “RBCs”, “red cells” or “erythrocytes”) or red blood cell precursors to produce red cell extracellular vesicles (RCEVs) containing cargos, including cargos comprising biologically active ingredients. Notable red cell precursors include hematopoietic stem cells (HSCs), induced pluripotent stem cells (iPSCs), and reticulocytes. The cargo may comprise nucleic acids, proteins, small molecules, or components of a gene editing system, including CRISPR/Cas9. The RCEVs may be used to treat of diseases and disorders including autoimmune disorders, cancers, cardiovascular diseases, gastrointestinal diseases, genetic disorders, or inflammatory diseases. The RCEVs may also be used to carry antigens and or immune modulator, for use in eliciting immune or immune tolerance responses. Also provided are methods for producing cargo loaded RCEVs (CLRCEVs) by first loading cargo into red cells and then by vesiculating the cargo loaded red cells to yield the CLRCEVs.

A method of encapsulating a solid sample in a droplet, the method including flowing a continuous phase through a first fluid channel at a first flow rate; flowing a dispersed phase through a second fluid channel at a second flow rate, the dispersed phase including a plurality of particles, cells or beads; trapping the plurality of particles, cells or beads in a mixing region that receives the dispersed phase and the continuous phase; and reducing the first flow rate to encapsulate the trapped particles, cells or beads in droplets of the dispersed phase generated when the dispersed phase and the continuous phase exit the mixing region through an orifice.

An oral dissolving film containing nano- or micro-encapsulated bioactive material and methods of forming the film. The film may be prepared by dispensing a mixture of a film-forming agent, a crosslinking agent, a solution of nano- or micro-encapsulated bioactive material, and a photoinitiator into a plurality of wells in a tray using a 3D printer. The dispensed material is exposed to radiation in order to crosslink the material and form a film.