Delivering a drug to a targeted site in the body requires a ‘carrier’ — a compound that encases the drug. However, optimizing the drug-to-carrier ratio can be a major challenge. “This ratio is a stumbling block in carrier design because the carrier itself provides no therapeutic effect,” explains Jackie Ying. “Furthermore, high quantities of the carrier may lead to problems associated with drug toxicity and metabolism.”
To overcome this problem, Ying, along with Joo Eun Chung, Motoichi Kurisawa and other co-workers, have designed a drug carrier that possesses therapeutic effects.
The scientists identified a catechin derivative in green tea known as epigallocatechin gallate (EGCG), which has documented anticancer effects, as the most promising carrier candidate. They used EGCG as the basis for 90-nanometer-diameter micellar nanocomplexes to deliver the anticancer protein drug Herceptin directly to tumors. The researchers did this by oligomerizing EGCG and then binding it to Herceptin, which formed the core of the micellar nanocomplexes. Finally, they formed the outer shells of the micellar nanocomplexes by binding polyethylene glycol–EGCG to the cores.
Cancer is not the only potential target for this drug delivery system. “EGCG binds to many biological molecules, such as proteins, peptides and genes, and this is responsible for its many beneficial activities,” notes Kurisawa. In particular, EGCG is known to be beneficial for cardiovascular and metabolic health; it also exhibits anti-HIV effects as well as neuro- and DNA-protective effects. “Our green-tea-based nanocarrier has the potential to deliver a variety of proteins, genes or drugs to improve the treatment of other diseases besides cancer,” remarks Chung.
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