A composition for the controlled release of a nucleic acid such as short interfering RNA or messenger RNA,comprising silicon nanoparticles, at least one amino acid,and at least one lipid, wherein the silicon nanoparticles comprise at least 50% by weight silicon. Also related compositions and methods.

This invention relates generally to anellosomes and compositions and uses thereof.

The present invention provides, among other things, effective methods and compositions for delivering messenger RNA (mRNA) via rectal delivery. The present invention is, in part, based on unexpected observation that mRNA may be effectively delivered to the circulation, liver, kidney, colon and/or rectum via rectal delivery despite the barriers such as RNase and mucus layer.

Disclosed herein are compositions (e.g., sprays, paints, etc.) that comprise antimicrobial zeolite nanoparticles. Also provided are hemostatic compositions comprising zeolite nanoparticles, dryer sheets comprising zeolite nanoparticles, and textiles comprising zeolite nanoparticles. Also disclosed are compositions (e.g., sprays) that include a binder polymer to improve coating adherence. In some cases, the zeolite nanoparticles can further comprise an optical tracer (e.g., a fluorophore) associated with the zeolite nanoparticles. The optical tracer can be interrogated to confirm presence of the zeolite nanoparticles (or a coating comprising the zeolite nanoparticles) on a surface. Also provided are methods of forming viricidal coatings using compositions that comprise zeolite nanoparticles dispersed in a carrier.

Provided are antibodies, and fragments and derivatives thereof, particularly humanized derivatives thereof, which bind to tumor antigens. Also provided are nucleic acid molecules encoding chimeric antigen receptors (CARs) that bind to tumor antigens, polypeptides and CARs encoded by the nucleic acid molecules, vectors and host cells that include the nucleic acid molecules, methods of making the same, and methods for using the same to generate a persisting population of genetically engineered T cells in a subject, expanding a population of genetically engineered T cells in a subject, modulating the amount of cytokine secreted by a T cell, reducing the amount of activation-induced calcium influx into a T cell, providing an anti-tumor immunity to a subject, treating a mammal having a MUC1-associated disease or disorder, stimulating a T cell-mediated immune response to a target cell population or tissue in a subject, and imaging a MUC1-associated tumor. Also provided are nanoparticle conjugates of the antibodies and fragments and derivatives thereof, particularly humanized derivatives thereof, compositions and delivery agents that include the same, host cells that produce the same; methods for producing the same; methods of using the same for detecting, targeting, and/or treating tumors and/or metastatic cells derived therefrom and/or tumor stem cells; and methods for predicting the recurrence of cancer in a subject.

Provided herein are methods and compositions for sensitizing a cancer cell to a cancer treatment, for example to an anticancer drug by the inhibition of at least two cancer biomarkers. Further provided are methods of treating and/or preventing a cancer including reducing the size of a tumor. Also provided are compositions comprising nanopartides associated with inhibitory molecules, such as siRNA, and/or anti-cancer drugs.

The present invention relates to a kit for preparing a nanoparticle composition for drug delivery and, more specifically, to a kit for preparing a nanoparticle composition for drug delivery, which is designed to easily form a nanoparticle in which a drug is encapsulated by simply mixing an amphiphilic block copolymer, a cationic compound, a polylactic acid salt, and the drug that are the components of the kit.

The preparation method of a starch-based double-loaded functional nanoparticle includes: performing restrictive hydrolysis treatment on egg high-density lipoprotein using proteases to obtain the polypeptide; performing self-assembling on a mixed system containing the polypeptide and quercetin under the alkaline condition to form a micelle nanoparticle; performing covalent grafting reaction on a mixed system containing the micelle nanoparticle and anthocyanin under the alkaline condition to form a graft; and electrostatically compounding carboxymethyl dextrin with the graft to obtain the starch-based double-loaded functional nanoparticle. In the preparation method, raw materials derived from natural sources are used, and the self-assembled colloid nanoparticle with good properties can be obtained by adjusting the pH without any organic reagents. The obtained product has a nanoparticle size, has high antioxidant activity and stability against environmental stress, and can be widely applied to the fields of delivery of nutrients, stabilization of biologically active substances and the like.

The present disclosure relates to a multi-functional nanoparticle targeted to breast cancer, a preparation method and use thereof. The multi-functional nanoparticle includes a targeting carrier and a medicament loaded on the targeting carrier; and the targeting carrier is made from recombinant ferritin. Cell experiments verify that the multi-functional nanoparticle has better efficacy and drug release capacity for cancer cells than those of conventional ferritin as a vector. Moreover, the drug delivery system can further achieve optical imaging of tumor cells by loading quantum dots, thus playing a role in cancer diagnosis and treatment.

The invention provides solid lipid nanoparticles (SLNs) which comprise gold, and are useful as vectors for the transfection of different types of nucleic acids. Different methods for obtaining such SLNs are also disclosed.