The present invention provides novel bisphosphonates vinylic monomers, polymers and particles that have utility as biologically active molecule (such as drugs) carriers, medical device coatings and for imaging/radiology applications, especially in bone and dental applications. The invention also provides methods of synthesizing the monomers, polymerizing the polymers, and assembling the particles of the invention.

The invention in the various aspects provides nanogel compositions that are safe for topical, local, and/or systemic delivery, and which can be targeted to select tissues or cells, including pathogens. In some embodiments, conjugation of antibiotics to the nanogel surface, and in particular antibiotics that disrupt outer membranes of Gram negative bacteria or antibiotics that inhibit cell wall synthesis, provide for highly effective targeting and killing of bacterial pathogens, including drug-resistant bacteria.

The invention relates to polymer nanoparticle and DNA nanostructure delivery compositions for non-viral delivery, and methods therefor. More particularly, the invention relates to polymer nanoparticle delivery compositions, such as reversible addition-fragmentation chain transfer (RAFT) polymer compositions, and DNA nanostructure delivery compositions, such as DNA origami compositions, for the delivery of more than one payload, or for the delivery of a nucleic acid construct payload of 3 kB or more, and methods therefor.

The present invention provides a novel therapeutic agent for treating inflammatory diseases which reduces the pro-inflammatory response and increases M2 macrophages according to the repolarization of macrophages, thereby exhibiting fewer side effects and excellent anti-inflammatory effects even at low doses compared to conventional steroid anti-inflammatory agent.

The present invention provides compositions and methods for targeting cells for therapeutic and/or diagnostic purposes, e.g., delivery of therapeutic and/or diagnostic agents to a cell. Nanoparticles and polymers functionalized with capture molecules, reporter molecules, and/or therapeutic agents are provided for the treatment or prevention of disease, including neurological diseases associated with neuroinflammation, and cancer.

The present disclosure provides a drug carrier, a brain-targeting nanodrug based on CRISPR gene editing technology and a preparation method and use thereof. The nanodrug contains nanoparticles prepared by coupling Cas9/sgRNA and drug carriers. The drug carrier includes a polymer mPEG-P (GPMA, FPMA) and a polymer Ang-PEG-PGPMA, wherein a structural formula of the mPEG-P (GPMA, FPMA) is: ##STR00001##
a structural formula of the polymer Ang-PEG-PGPMA is: ##STR00002##
where n is 35-45, x1 is 15-20, y is 2-4, m is 75-85, and x2=x1. The guanidino group of the drug carrier can be combined with the ribonucleoprotein complex by electrostatic action, salt bridge formation, or hydrogen bonding action. Also provided are methods of suppressing and treating tumors at a gene level using the drug carrier to transport the therapeutic drug to the lesion site.

The present invention generally relates to yeast cell wall microparticles loaded with nanoparticles for receptor-targeted nanoparticle delivery. In particular, the present invention relates to trapping nanoparticles either on the surface or inside a yeast glucan particles, for example, yeast glucal particles. The present invention further relates to methods of making the yeast cell wall particles loaded with nanoparticles. The present invention also relates to methods of using the yeast cell wall particles particles loaded with nanoparticles for receptor-targeted delivery of the nanoparticles, e.g., drug containing nanoparticles.

A particulate, modified release barrier coated drug-cation exchange resin complex comprising a core composed of a drug complexed with a pharmaceutically acceptable ion-exchange resin is provided. Methods of making and products containing this coated complex are described.

A core-shell particle formulation for delivering multiple therapeutic agents is disclosed. More particularly, core-shell particle formulation configured to independently release therapeutic agents from the core and the shell. Moreover, the core-shell particle bearing therapeutic agents enables treatment against the diseases such as cancer, inflammatory and auto-immune diseases.

The invention is directed to a stable complex with controlled particle size, increased apparent solubility and increased dissolution rate comprising as active compound Sirolimus or derivatives thereof, which is useful in the prophylaxis of organ rejection in patients receiving renal transplants, in the treatment of psoriasis, facial angiofibromas associated with tuberous sclerosis, fibrofolliculomas found in Birt-Hogg-Dub Syndrome, chronic erosive oral lichen planus, Early Stage Cutaneous T-cell Lymphoma, Treatment of Autoimmune Active Anterior Uveitis, dry eye syndrome, age-related macular degeneration, diabetic macular edema, noninfectious uveitis, telangiectasia, inflammatory skin diseases (dermatitis, including psoriasis and lichen ruber planus), Pachyonychia Congenita and in the suppression of angiogenesis pathways. More specifically, the complex of the present invention possesses increased apparent solubility, permeability and enhanced biological performance including significantly improved exposure, earlier tmax, higher Cmax and higher trough concentrations at 24 hours which will allow the reduction of the dose.