Formulated and/or co-formulated nanocarriers (e.g., LNPs and/or SLNPs) comprising PD-1 Prodrugs and methods of making the nanocarriers are disclosed herein. The PD-1 Prodrug compositions comprise a drug moiety, a lipid moiety, and linkage unit that inhibit PD-1-L1/L2. The PD-1 Prodrugs can be formulated and/or co-formulated into a nanocarrier to provide a method of treating cancer, immunological disorders, and other disease by utilizing a targeted drug delivery vehicle.

Described herein are processable compositions comprising at least one moiety that is processable in its free form. Also described herein are compositions and methods for the treatment of ocular diseases or disorders including glaucoma, blepharitis, ocular inflammation, diabetic macular edema, posterior inflammation, anterior inflammation, macular degeneration (e.g., wet macular degeneration (AMD) or dry AMD), post-cataract surgery, and retinal vein occlusion. Said compositions and methods comprise steroids and prostaglandins which demonstrate anti-inflammatory activity, intraocular pressure (IOP) lowering, and/or other desirable activities. Injection of said compositions in the eye provides therapeutic benefit to patients suffering from ocular disorders.

Covalently modified polypeptide antigens having improved immunogenicity and/or stability, as well as compositions, cells, and methods relating thereto, are described herein. Polypeptide antigens are covalently conjugated to a one or more of steroid acid moieties to improve their stability and/or to trigger improved cellular immunity, or improved cellular and humoral immunity, against the antigen upon administration to a subject. The steroid acids include bile acids and bile acid analogs that enhance endocytosis and/or endosomal escape of endosomally trapped cargoes by potentiating enzymatic cleavage of sphingomyelin to ceramide within endosomal membranes. The steroid acid moieties may be pre-conjugated to a peptide, and the steroid acid-peptide moiety subsequently conjugated to the polypeptide antigen. The peptide may comprise one or more domains that impart an additional functionality to the modified polypeptide antigen.

Formulated and/or co-formulated nanocarriers (e.g., LNPs and/or SLNPs) comprising PD-1 Prodrugs and methods of making the nanocarriers are disclosed herein. The PD-1 Prodrug compositions comprise a drug moiety, a lipid moiety, and linkage unit that inhibit PD-1-L1/L2. The PD-1 Prodrugs can be formulated and/or co-formulated into a nanocarrier to provide a method of treating cancer, immunological disorders, and other disease by utilizing a targeted drug delivery vehicle.

The present invention relates to nanoparticles complexed with biomacromolecule agents configured for treating, preventing or ameliorating various types of disorders, and methods of synthesizing the same. In particular, the present invention is directed to compositions comprising nanoparticles (e.g., synthetic high density lipoprotein (sHDL)) carrying biomacromolecule agents (e.g., nucleic acid, peptides, glycolipids, etc.), methods for synthesizing such nanoparticles, as well as systems and methods utilizing such nanoparticles (e.g., in diagnostic and/or therapeutic settings).

Methods and compositions are provided for extending the half-life of a therapeutic agent. A modified therapeutic agent (mTA) comprises a therapeutic agent, a staple, and a half-life extending molecule. The mTAs disclosed herein may be used to treat a disease or a condition in a subject in need thereof.

This disclosure provides cell surface anchoring conjugates that can bind with an exogenous antibody, compositions and formulations comprising said cell surface anchoring conjugates, TLR agonist and methods of using the same for boosting immunity in a subject and treating tumor cell and cancer.

The invention relates to a molecular scaffold suitable for covalently binding at least one biologically active molecule to a carrier molecule, the scaffold comprising a polymeric structure and the biologically active molecules covalently bound to said polymeric structure, and wherein the scaffold further comprises a chemical group for covalently coupling of the scaffold to the carrier molecule. The biologically active molecule has a molecular weight of 3.000 Dalton or less, such as 1.700 Dalton-1.950 Dalton. The biologically active molecule is an amphiphilic molecule in some embodiments. The biologically active molecule is a single specific molecule or is a mixture of different types of molecules, when more than one biologically active molecules are covalently bound to the polymeric (or oligomeric) structure. In particular, the invention relates to monoclonal antibody-based antibody-drug conjugates with improved therapeutic window of the drug due to covalent linkage of (a cluster of) potentiator molecules, e.g. a payload such as a protein toxin or oligonucleotide to the ADC, or alternatively, due to co-administration of an ADC and a cell-targeting conjugate comprising (a cluster of) potentiator molecules to a patient in need thereof. The invention also relates to a method for producing a scaffold suitable for covalently binding a biologically active molecule to a carrier molecule, providing a cluster of potentiator molecules. Furthermore, the invention relates to a method for producing a scaffold covalently bound to a carrier molecule, the scaffold comprising a covalently bound biologically active molecule, the carrier molecule comprising an antibody and a payload.

The present invention discloses preparation and use of a nanoparticle-doped RNA hydrogel targeting to a triple negative breast cancer (TNBC). The RNA hydrogel is a pure RNA system formed in a rolling circle transcription manner. The transcription process generates a large number of GC bonds, which provides a large number of sites for the introduction of DOX. The large number of RNA copy structures generated by rolling circle replication is a polyanionic aggregate. Due to the strong electronegativity of the polyanionic aggregate, electropositive MnO.sub.2@Ce6 nanoparticles are introduced, such that the colloid cationic MnO.sub.2@Ce6 particles can be stabilized by the polyanionic hydrogel, and thus target into a breast cancer cell for synergistic treatment. It can be used for a drug slow release system, has good biocompatibility, and has broad prospects in the fields of growth inhibition effects on targeted MDA-MB-231 tumor cells, inhibition of cancer metastasis and recurrence, and the like.

Provided herein are methods, compounds, and compositions for modulation of transcript processing.