Share this article

 Email

 Print

 

Republish this article

The text of this article by Futurity is licensed under a Creative Commons Attribution-No Derivatives License.

More
Health & Medicine

Weekend delivery safe for high-risk babies

Fee hike makes kids’ insurance a challenge

100-year-old brains may help treat mentally ill

No consensus on mastectomy follow-up

Therapy for MS prods brain to re-cloak neurons

Girls ‘rewire’ brain to beat depression

Brand name drugs cost Medicare the most

Spoon-fed babies may become fatter kids

Prenatal thyroid drugs don’t boost kids’ IQ

In a study appearing online in the International Journal of Pharmaceutics, the University of California, Irvine researchers show that doxorubicin—commonly used to treat a number of cancers—can be directed almost entirely to a particular spot in the body with virtually no spread to other organs.

“Although doxorubicin is a potent anticancer agent, its usefulness is compromised by its serious side effects on normal tissue,” says Kenneth Longmuir, physiology and biophysics associate professor. “When administered in a chemotherapeutic regimen, the drug distributes widely in the body, including the heart, rather than just in tumor regions. This chance of heart damage restricts the amount of doxorubicin that a patient can receive.”

He notes that less than a quarter—and in many cases less than 10 percent—of the medicine typically reaches its target. The remainder is dispersed throughout normal organs, resulting in considerable toxicity.

To overcome this, the researchers focused on the fact that all tissue, even a tumor, is surrounded by a dense area of sugar-containing molecules called polysaccharides. The chemical composition of these polysaccharides differs for each type of tissue.

“We knew that if we could find a molecular guide to a specific polysaccharide coating, we could create a highly targeted drug delivery system,” says Richard Robertson, anatomy and neurobiology professor. “Fortunately, such a guide exists in the malaria microorganism Plasmodium.”

Plasmodium has the exceptional ability to only recognize the liver’s polysaccharide coating. So Robertson and Longmuir isolated the protein that allows Plasmodium to do this and built a doxorubicin delivery system around it.

They inserted the drug into fatty, tubelike structures called liposomes that are staples of nanomedicine. Then they bonded Plasmodium’s targeting protein to these liposome packages, in essence “addressing” them to the liver.

In tests on mice, the research team demonstrated that doxorubicin was conveyed to the liver, and away from the heart, with a specificity rate of more than 99 percent.

The next step is to try the drug transport system in several experimental cancer models, Longmuir says. He and Robertson are developing new liposome packages with targeting proteins that only recognize the unique polysaccharide features of tumors.

“By rapidly and accurately delivering chemotherapeutic agents to tumor regions, treatments can become safer and more effective,” Longmuir says. “This promising approach opens up a new avenue to helping people survive cancer.”

UC Irvine news: www.uci.edu