The invention involves inducing 3-50 or more mutations (e.g., any whole number between 3 and 50 of mutations, with it noted that in some embodiments there can be up to 16 different RNA(s), e.g., sgRNAs each having its own a promoter, in a vector, such as AAV, and that when each sgRNA does not have its own promoter, there can be twice to thrice that amount of different RNA(s), e.g., sgRNAs, e.g., 32 or even 48 different guides delivered by one vector) in transgenic Cas9 eukaryotes to model genetic disease, e.g. cancer. The invention comprehends testing putative treatments with such models, e.g., testing putative chemical compounds that may be pharmaceutically relevant for treatment or gene therapy that may be relevant for treatment, or combinations thereof. The invention allows for the study of genetic diseases and putative treatments to better understand and alleviate a genetic disease or a condition, e.g., cancer.

Delivery devices, systems, and methods related thereto may be used in humans for spinal delivery of cells, drugs or vectors. Thus, the system enables subpial delivery, which leads to a near complete spinal parenchymal AAV9-mediated gene expression or ASO distribution in both white and grey matter.

The invention provides a platform and methods of using the platform for the regulation of the expression of a target gene using exposure to an aptamer ligand (for example, a small molecule). The platform features a polynucleotide gene regulation cassette that is placed in the target gene and includes a synthetic riboswitch positioned in the context of a 5′ intron-alternative exon-3′ intron. The riboswitch comprises an effector region and a sensor region (e.g., an aptamer that binds a small molecule ligand) such that the alternative exon is spliced into the target gene mRNA when the ligand is not present thereby preventing expression of the target gene. When the ligand is present, the alternative exon is not spliced into the target gene mRNA thereby providing expression of the target gene.

A lipidated secondary antibody is disclosed. Particles comprising same are also disclosed.

Provided herein are micellic assemblies comprising a plurality of copolymers. In certain instauces, micellic assemblies provided herein are pH sensitive particles.

This invention provides formulations for use in distributing RNAi molecules targeted to a human GST-π for treating a malignant tumor in a subject. The formulation can include nanoparticles composed of an ionizable lipid, a DSPE lipid, and additional lipids. A drug product can be made by lyophilization of the formulation. This invention further provides methods for ameliorating or treating a malignant tumor by administering a therapeutically effective amount of a formulation containing the RNAi agents.

Lipid particles containing a nucleic acid, devices and methods for making the lipid particles, and methods for using the lipid particles.

Aspects of the disclosure relate to complexes comprising a muscle-targeting agent covalently linked to a molecular payload. In some embodiments, the muscle-targeting agent specifically binds to an internalizing cell surface receptor on muscle cells. In some embodiments, the molecular payload promotes the expression or activity of a functional dystrophin protein. In some embodiments, the molecular payload is an oligonucleotide, such as an antisense oligonucleotide, e.g., an oligonucleotide that causes exon skipping in a mRNA expressed from a mutant DMD allele.

Biodegradable particles for delivering a nucleic acid encoding gene-editing factors or a nucleic acid associated with a therapeutic protein to a cell, and compositions, methods, systems, and kits for gene editing in vivo or ex vivo or gene therapy for treating retinal eye diseases are disclosed.

The present disclosure relates to extracellular vesicles, e.g., exosomes, comprising an antisense oligonucleotide (ASO), wherein the ASO comprises a contiguous nucleotide sequence of 10 to 30 nucleotides in length that is complementary to a nucleic acid sequence within a CEBP/transcript. Also provided herein are methods for producing the exosomes and methods for using the exosomes to treat and/or prevent diseases or disorders.