Provided herein are dendrimers comprising a core unit, five generations of building units being a lysine residue or analogue thereof, a plurality of first terminal groups each comprising a residue of a nucleoside analogue, and a plurality of second terminal groups each comprising a hydrophilic polymeric group. Also provided herein are pharmaceutical compositions comprising the dendrimer, and methods and uses of the dendrimers in therapy of disorders such as cancers.

Provided in the present invention is a bispecific antibody which comprises an anti-MUC1 VHH antibody fragment and an anti-CD16 VHH antibody fragment. The antibody fragment used in the present invention is a variable region sequence derived from a heavy chain camelid antibody and has a high binding affinity to the antigen. Antibody fragments recognizing MUC1 and CD16 are constructed in the same antibody molecule by the invention, so that the antibody molecule can specifically bind to MUC1 and CD16 molecules to promote the killing effect of NK cells on MUC1-positive expression cells and has an inhibiting effect on the growth of MUC1-positive tumors. Also provided is a conjugate of the bispecific antibodies, a related pharmaceutical composition and use.

Methods for synthesizing and purifying oligopeptide-modified poly-beta-amino-esters (OM-PBAEs) and related polymers without using DMSO as a solvent yield OM-PBAEs with improved storage stability in biocompatible buffers. The polymers can be stored for extended periods and used to encapsulate nucleic acids and viral vectors losing transfection or transduction efficiency.

The present invention relates to a technique for effective intranasal delivery to the brain. More specifically, the present invention is used for diagnosing, preventing or treating central nervous system encephalopathy, neurodegenerative diseases or brain tumor by effectively delivering to the brain a pH-responsive and bioreducible PPA polymer, which can be used as a drug carrier, by means of nasal administration.

Free-standing non-fouling polymers and polymeric compositions, monomers and macromonomers for making the polymers and polymeric compositions, objects made from the polymers and polymeric compositions, and methods for making and using the polymers and polymeric compositions.

Free-standing non-fouling polymers and polymeric compositions, monomers and macromonomers for making the polymers and polymeric compositions, objects made from the polymers and polymeric compositions, and methods for making and using the polymers and polymeric compositions.

The present disclosure provides, in some aspects, macromonomers of Formula (I), and salts thereof; methods of preparing the macromonomers, and salts thereof; Brush prodrugs (polymers); methods of preparing the Brush prodrugs; compounds of Formula (II); conjugates of Formula (III), and salts thereof; pharmaceutical compositions comprising a Brush prodrug, or a conjugate or a salt thereof; kits comprising: a macromonomer or a salt thereof, a Brush prodrug, a compound, a conjugate or a salt thereof, or a pharmaceutical composition; methods of using the Brush prodrugs, or conjugates or salts thereof; and uses of the Brush prodrugs, and conjugates or salts thereof. These chemical entities may be useful in delivering pharmaceutical agents to a subject or cell.

The present disclosure provides, in some aspects, macromonomers of Formula (I), and salts thereof; methods of preparing the macromonomers, and salts thereof; Brush prodrugs (polymers); methods of preparing the Brush prodrugs; compounds of Formula (II); conjugates of Formula (III), and salts thereof; pharmaceutical compositions comprising a Brush prodrug, or a conjugate or a salt thereof; kits comprising: a macromonomer or a salt thereof, a Brush prodrug, a compound, a conjugate or a salt thereof, or a pharmaceutical composition; methods of using the Brush prodrugs, or conjugates or salts thereof; and uses of the Brush prodrugs, and conjugates or salts thereof. These chemical entities may be useful in delivering pharmaceutical agents to a subject or cell.

In one aspect, methods of targeted nanoparticles and cell delivery are described herein. In some embodiments methods described herein comprise coupling nanoparticles and cells to a carrier cell to form a nanoparticle-cell conjugate or cell-cell conjugate, disposing the nanoparticle-cell or cell-cell conjugate in a biological environment, and delivering the nanoparticles and cells to target cells or tissues located within the biological environment. The nanoparticles comprise a biodegradable photoluminescent polymer, and the nanoparticle-cell conjugate is formed using one or more click chemistry reaction products.

The present invention concerns novel and improved antibody-conjugates for targeting CD30. The inventors found that when antibody-conjugates were prepared using a specific mode of conjugation, they exhibit an improved therapeutic index. The mode of conjugation comprises a first step (i) of contacting a glycoprotein comprising 1-4 core N-acetylglucosamine moieties with a compound of the formula S(F.sup.1).sub.x-P in the presence of a catalyst, wherein S(F.sup.1).sub.x is a sugar derivative comprising x functional groups F.sup.1 capable of reacting with a functional group Q.sup.1, x is 1 or 2 and P is a nucleoside mono- or diphosphate, and wherein the catalyst is capable of transferring the S(F.sup.1).sub.x moiety to the core-GlcNAc moiety, to obtain a modified antibody; and a second step (ii) of reacting the modified antibody with a linker-conjugate comprising a functional group Q.sup.1 capable of reacting with functional group F.sup.1 and a target molecule D connected to Q.sup.1 via a linker L.sup.2 to obtain the antibody-conjugate wherein linker L comprises S—Z.sup.3-L.sup.2 and wherein Z.sup.3 is a connecting group resulting from the reaction between Q.sup.1 and F.sup.1. The invention also relates to a use for improving the therapeutic index of an antibody-conjugate and to a method for targeting CD30-expressing cells.