A medicinal chewing gum has an inner core containing a first gum base and a first cannabinoid in a lipophilic nanosized form and an outer layer containing a second gum base and a second cannabinoid in a hydrophilic nanosized form, thereby providing quick release of the second cannabinoid in the outer layer and sustained release of the first cannabinoid in the inner layer. At least one of the inner core and the outer layer contains a synergistic compound having a synergistic effect with at least one of the first and second cannabinoids in the treatment of a medical condition.

The present invention includes synthesis of polyethyleneimine800-EpoxyC8-22 (PEI800-C8-22) lipids, e.g., Polyethyleneimine800-EpoxyC16 (PEI800-C16), PEI12C16, PEI8C16, and PEI4C16 lipids, compositions and methods for transfecting primary leukocytes, myeloid cells, lymphoid cells, monocytes, macrophages and dendritic cells (DC) comprising a transfection complex comprising: one or more nanoparticles; and Polyethyleneimine800-EpoxyC16 (PEI800-C16), PEI12C16, PEI8C16, and PEI4C16 lipids complexed with one or more nucleic acids, such as, e.g., DNA, RNA, nucleic acid vectors, shRNA, miRNA, and RNAi on or about the nanoparticles.

This disclosure relates to systems, compounds and methods for stem cell delivery. More specifically, the disclosure relates a system for promoting tissue regeneration, the system comprising a plurality of stem cells coated with at least one or a plurality of dendrimer nanocarriers that specifically bind to an adhesion molecule. Additionally, the disclosure relates to methods for delivering stem cells to damaged or diseased tissue for stem cell regeneration of the tissue.

A construct, or a pharmaceutically acceptable salt thereof, comprising: (a) a polyethylene glycol-block-poly(L-lysine) polymer moiety, wherein the polyethylene glycol is thiol-functionalized; (b) a cholecystokinin-B (CCK-B) receptor ligand coupled to the polyethylene glycol of the polymer moiety; and (c) a siRNA complexed with the poly(L-lysine) of the polymer moiety, wherein the construct is neutralized.

A DNA plasmid useful for diagnostic and therapeutic gene therapy is disclosed. Improvements to gene therapy methods known in the art are provided to ensure cancer-targeting, high efficacy, and long durability of expression. The DNA plasmid is combined with compositions of polymeric nanoparticles for non-viral gene therapy to treat cancer, including hepatocellular carcinoma and prostate cancer.

Disclosed herein are compositions and methods for preparation and delivery of protein therapeutics, and more particularly reversible linkers and use thereof.

A self-assembled therapeutic dendron-micelle includes a first amphiphilic dendron-coil, a second amphiphilic dendron-coil, and optionally a third amphiphilic dendron-coil, and an encapsulated BRD4 ligand or BRD4 proteolysis targeting chimera. The first and optional third amphiphilic dendron-coils have a therapeutic peptide conjugated thereto. Also included are pharmaceutical compositions containing the dendron-micelles, methods of making the dendron-micelles, and therapeutic methods including administering the dendron-micelles to a subject in need thereof.

Disclosed are a composition for inducing immunity against an active ingredient and a method for preparing same, the composition comprising: a nucleic acid, a polypeptide, or a combination thereof as the active ingredient; a cationic compound; an amphiphilic block copolymer; and a polylactate, wherein the active ingredient is encapsulated in a nanoparticle structure formed by the amphiphilic block copolymer and the polylactate.

Polymer-encapsulated viral vector nanoparticles and methods of using them provide enhanced delivery of genetic material for use in gene therapy and other applications. The nanoparticles include an outer shell containing an oligopeptide-modified poly(beta-amino ester) polymer which encapsulates the vector and allows the vector to transduce cells without the need for pseudotyping or the inclusion of any viral fusion protein, such as VSV-G. The polymer-encapsulated vector nanoparticles have a natural tropism for peripheral blood cells, such as leucocytes, without the need for a targeting moiety, and have an improved safety profile compared to pseudotyped viral vectors.

The present disclosure provides EBNA1 and LMP1 dual-targeting peptides and upconversion nanoparticles conjugates comprising the same useful as therapeutic and theranostic agents capable of targeting EBNA1 and LMP1 proteins present in Epstein-Barr virus infected cells, such as cancer.