A complex is provided comprising a conjugate in which a polymer having a boronic acid group and a compound having a diol structure are bonded, and a substance that is complexed with the conjugate.

The present invention pertains to extracellular vesicle (EV) therapeutics, wherein the EVs are coated with proteins containing Fc domains (such as antibodies) for i.a. targeting and therapeutic applications. The coating of EVs is achieved through inventive protein engineering of EV polypeptides. The present invention thus relates to methods for coating of EVs, EVs per se, as well as pharmaceutical compositions and medical applications of such EVs coated with Fc containing proteins.

Described herein are hydrogel compositions comprising cross-linked bacteriophages. The hydrogels are typically bioactive, degradable, for example biodegradable, self-healing, fluorescent, for example autofluorescent, and/or birefringent. The hydrogels described herein may be used as therapeutics or diagnostics, as scaffolds for material synthesis, as catalysts, as membranes or filters, or as biosensor substrates, for example.

Photodynamic virus particles including a plant virus particle associated with a photosensitizing agent are described. Methods of treating cancer in a subject by administering to the subject a therapeutically effective amount of the photodynamic virus particles and illuminating a cancer-bearing region of the subject to activate the photodynamic virus particles are also described.

The present invention is, in general, directed to nanoparticles for the delivery of agents to glioblastoma tumors. More particularly, the present invention relates to nanoparticle conjugates that deliver and release agents to a glioblastoma tumor. The invention is also directed to methods of delivering agents to glioblastoma tumors.

Methods and compositions for using N-hydroxysuccinimide and N-hydroxysulfosuccinimide to covalently couple protein(s) to the surface of red blood cells universally, rapidly and conveniently are provided. In one embodiment, the compositions promote immune tolerance in a subject. One embodiment provides autologous or allogenic red blood cells having whole protein(s) of interests conjugated to proteins on or within the plasma membrane of the red blood cells, wherein the conjugated proteins display at least one antigen to which immune tolerance is desired. The proteins are conjugated to the RBCs using carbodiimide chemistry. In a preferred embodiment, the whole proteins are conjugated using EDC in combination with NHS or sulfo-NHS.

Residence structures, systems, and related methods are generally provided. Certain embodiments comprise administering (e.g., orally) a residence structure to a subject (e.g., a patient) such that the residence structure is retained at a location internal to the subject for a particular amount of time (e.g., at least about 24 hours) before being released. The residence structure may be, in some cases, a gastric residence structure. In some embodiments, the structures and systems described herein comprise one or more materials configured for high levels of active substances (e.g., a therapeutic agent) loading, high active substance and/or structure stability in acidic environments, mechanical flexibility and strength in an internal orifice (e.g., gastric cavity), easy passage through the GI tract until delivery to at a desired internal orifice (e.g., gastric cavity), and/or rapid dissolution/degradation in a physiological environment (e.g., intestinal environment) and/or in response to a chemical stimulant (e.g., ingestion of a solution that induces rapid dissolution/degradation). In certain embodiments, the structure has a modular design, combining a material configured for controlled release of therapeutic, diagnostic, and/or enhancement agents with a structural material necessary for gastric residence but configured for controlled and/or tunable degradation/dissolution to determine the time at which retention shape integrity is lost and the structure passes out of the gastric cavity. For example, in certain embodiments, the residence structure comprises a first elastic component, a second component configured to release an active substance (e.g., a therapeutic agent), and, optionally, a linker. In some such embodiments, the linker may be configured to degrade such that the residence structure breaks apart and is released from the location internally of the subject after a predetermined amount of time.

Uniform, functional polymer patches can be attached to a fraction of the surface area of living individual cells. These surface-modified cells can cross the blood-brain barrier while remaining viable after attachment of the functional patch. Functional payloads carried by the patch can include a drug. The patch can include one or more polyelectrolyte multilayers (PEMs).

The present invention pertains to extracellular vesicle (EV) therapeutics, wherein the EVs comprise nucleic acid (NA)-based therapeutics such as mRNAs, circular RNAs, miRNAs, shRNAs, and/or DNA molecules. The NA therapeutics are loaded into EVs using inventive protein and NA engineering strategies which stabilize the cargo NAs and enhance loading into EVs, thereby enhancing therapeutic activity of the cargo NA molecules half-life.

In some aspects, the present invention provides cell-reactive compstatin analogs and compositions comprising cell-reactive compstatin analogs. In some aspects, the invention further provides methods of using cell-reactive compstatin analogs, e.g., treat a complement-mediated disorder, e.g., to inhibit complement-mediated damage to a cell, tissue, or organ. In some aspects, the invention provides long-acting compstatin analogs and compositions comprising long-acting compstatin analogs. In some aspects, the invention further provides methods of using long-acting compstatin analogs, e.g., to treat a complement-mediated disorder, e.g., to inhibit complement-mediated damage to a cell, tissue, or organ. In some aspects, the invention provides targeted compstatin analogs and compositions comprising targeted compstatin analogs. In some aspects, the invention further provides methods of using targeted compstatin analogs, e.g., to treat a complement-mediated disorder, e.g., to inhibit complement-mediated damage to a cell, tissue, or organ.