Nanoparticle Formulation Derived from Carboxymethyl Cellulose, Polyethylene Glycol, and Cabazitaxel for Chemotherapy Delivery to the Brain.

Nanoparticles provide a unique opportunity to explore the benefits of selective distribution and release of cancer therapeutics at sites of disease through varying particle sizes and compositions that exploit the enhanced permeability of tumor-associated blood vessels. Though delivery of larger as opposed to smaller and/or actively transported molecules to the brain is prima facie a challenging endeavor, we wondered whether nanoparticles could improve the therapeutic index of existing drugs for use in treating brain tumors via these vascular effects. We therefore selected a family of nanoparticles composed of cabazitaxel-carboxymethyl cellulose amphiphilic polymers to investigate the potential for delivering a brain-penetrant taxane to intracranial brain tumors in mice.

Using Flash Nanoprecipitation To Produce Highly Potent and Stable Cellax Nanoparticles from Amphiphilic Polymers Derived from Carboxymethyl Cellulose, Polyethylene Glycol, and Cabazitaxel.

We report the use of flash nanoprecipitation (FNP) as an efficient and scalable means of producing Cellax nanoparticles. Cellax polymeric conjugates consisting of carboxymethyl cellulose functionalized with PEG and hydrophobic anticancer drugs, such as cabazitaxel (coined Cellax-CBZ), have been shown to have high potency against several oncology targets, including prostate cancer. FNP, a robust method used to create nanoparticles through rapid mixing, has been used to encapsulate several hydrophobic drugs with block copolymer stabilizers, but has never been used to form nanoparticles from random copolymers, such as Cellax-CBZ.

Site-specific UBITh amyloid-beta vaccine for immunotherapy of Alzheimer's disease.

The UBITh AD immunotherapeutic vaccine for Alzheimer's disease uses an amyloid-beta (Abeta) immunogen having two designer peptides that have been engineered to elicit anti-N terminal Abeta(1-14) antibodies while minimizing potential for the generation of adverse anti-Abeta immune responses. The vaccine has been further designed for minimization of inflammatory reactivities through the use of a proprietary vaccine delivery system that biases Th2 type regulatory T cell responses in preference to Th1 pro-inflammatory T cell responses. In vitro studies and in vivo studies in small animals, baboons and macaques show that anti-Abeta antibodies are generated with the expected N-terminus site-specificity, and that these antibodies have functional immunogenicities to neutralize the toxic activity of Abeta and promote clearance of plaque deposition.