Ketal containing amphiphilic block copolymer micelles as pH-sensitive drug carriers.

pH-Responsive linkages have been widely exploited in the development of polymeric drug delivery systems, which trigger drug release selectively at tumor tissues or endosomes and lysosomes of cells. Herein we report new pH-sensitive amphiphilic poly(ketal adipate)-co-poly(ethylene glycol) block copolymers (PKA-PEG), which have acid-cleavable ketal linkages in their hydrophobic backbone. PKA-PEG copolymers self-assemble to form stable micelles with a mean diameter of ~175 nm, which can encapsulate a payload of anticancer drugs and rapidly dissociate to release drug payload at the acid environment. The micelles are biocompatible and exhibit abilities to disrupt endosomes to enhance the cytosol drug delivery. Taken together, we anticipate that the pH-sensitive PKA-PEG micelles have great potential as anticancer drug carriers.

Acid-degradable cationic poly(ketal amidoamine) for enhanced RNA interference in vitro and in vivo.

Efficient delivery of small interfering RNA (siRNA) is one of major challenges in the successful applications of siRNA in clinic. In the present study, we report a new acid-degradable poly(ketal amidoamine) (PKAA) as a siRNA carrier, which has high delivery efficiency and low cytotoxicity. PKAA was designed to have acid-cleavable ketal linkages in the backbone of cationic biodegradable poly(amidoamine). PKAA efficiently self-assembled with siRNA to form nanocomplexes with a diameter of ~200 nm and slightly positive charges, which are stable under physiological conditions, but rapidly release siRNA at acidic pH. PKAA exhibited sufficient buffering capability and endosomolytic activity due mainly to the presence of secondary amine groups in its backbone and rapid degradation in acidic endosomes, leading to the enhanced release of siRNA to cytoplasm. Cell culture studies demonstrated that PKAA is capable of delivering anti-TNF (tumor necrosis factor)-α siRNA to lipopolysaccharide (LPS)-stimulated macrophages and significantly inhibits the expression of TNF-α. A mouse model of acetaminophen (APAP)-induced acute liver failure was used to evaluate in vivo siRNA delivery efficacy of PKAA. PKAA/anti-TNF-α siRNA nanocomplexes significantly reduced the ALT (alanine transaminase) and the hepatic cellular damages in APAP-intoxicated mice. We anticipate that acid-degradable PKAA has great potential as siRNA carriers based on its excellent biocompatibility, pH sensitivity, potential endosomolytic activity, and high delivery efficiency.

Fully biodegradable and cationic poly(amino oxalate) particles for the treatment of acetaminophen-induced acute liver failure.

Acute inflammatory diseases are one of major causes of death in the world and there is great need for developing drug delivery systems that can target drugs to macrophages and enhance their therapeutic efficacy. Poly(amino oxalate) (PAOX) is a new family of fully biodegradable polymer that possesses tertiary amine groups in its backbone and has rapid hydrolytic degradation. In this study, we developed PAOX particles as drug delivery systems for treating acute liver failure (ALF) by taking the advantages of the natural propensity of particulate drug delivery systems to localize to the mononuclear phagocyte system, particularly to liver macrophages. PAOX particles showed a fast drug release kinetics and excellent biocompatibility in vitro and in vivo. A majority of PAOX particles were accumulated in liver, providing a rational strategy for effective treatment of ALF. A mouse model of acetaminophen (APAP)-induced ALF was used to evaluate the potential of PAOX particles using pentoxifylline (PTX) as a model drug. Treatment of PTX-loaded PAOX particles significantly reduced the activity of alanine transaminase (ALT) and inhibited hepatic cell damages in APAP-intoxicated mice. The high therapeutic efficacy of PTX-loaded PAOX particles for ALF treatment may be attributed to the unique properties of PAOX particles, which can target passively liver, stimulate cellular uptake and trigger a colloid osmotic disruption of the phagosome to release encapsulated PTX into the cytosol. Taken together, we believe that PAOX particles are a promising drug delivery candidate for the treatment of acute inflammatory diseases.