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Cancer treatment - Imaging yields insights into nanomedicine

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Researchers at Purdue University have discovered a possible new pathway for anti-tumor drugs to kill cancer cells and proposed how to improve the design of tiny drug-delivery particles for use in "nanomedicine."


The synthetic "polymer micelles" are drug-delivery spheres 60-100 nanometers in diameter, or roughly 100 times smaller than a red blood cell. The spheres harbor drugs in their inner core and contain an outer shell made of a material called polyethylene glycol.

Purdue researchers showed for the first time how this shell of polyethylene glycol latches onto the membranes of cancer cells, allowing fluorescent probes mimicking cancer drugs to enter the cancer cells, said Ji-Xin Cheng, an assistant professor in the Weldon School of Biomedical Engineering and Department of Chemistry.

"This is an interesting new step in developing nanomedicine techniques in drug delivery," he said.

The research is being led by Cheng and Kinam Park, Showalter Distinguished Professor of Biomedical Engineering and a professor of pharmaceutics.

New findings are detailed in two research papers. One paper appears this week in Proceedings of the National Academy of Sciences, and another paper also will appear in May in the journal Langmuir.

The researchers used an imaging technique called Förster resonance energy transfer imaging, or FRET, to make two key discoveries: how fluorescent molecules mimicking the cancer drug paclitaxel enter tumor cells and how the micelles break down in the blood before they have a chance to deliver the drug to cancer cells.

A critical feature of micelles is that they combine two types of polymers, one being hydrophobic and the other hydrophilic, meaning they are either unable or able to mix with water. The hydrophobic core was loaded with a green dye and the hydrophilic portion labeled with a red dye.

Experiments showed that "core-loaded" fluorescent molecules mimicking the drug entered cancer cells within 15 minutes, suggesting a new drug-delivery pathway to kill tumor cells, Cheng said.

The fluorescent probes produced a green color on the membranes and a yellowish color inside the cells.

"So this technique provides a system to monitor in real time how well anti-cancer drug delivery is working," Cheng said.

Additional findings appearing in Langmuir, in research using mice, show specifically how the drug is released prematurely in the blood.

"We first proved that micelles are unstable in the blood, and then we answered why they don't remain intact," Cheng said.

The researchers also propose a possible way to fix the problem by "crosslinking," or reinforcing polymer strands in the micelles with chemical bonds made of two sulfur atoms. This reinforced structure might remain intact in the blood long enough to deliver the micelles to tumor sites, where they would biodegrade, Cheng said.

The researchers are the first to use FRET to study drug release from polymer micelles into a tumor cell.

Because micelles remain intact in water, researchers had thought the particles were stable in blood, but Canadian scientists in 2003 showed that the micelles are quickly broken down, releasing the drug into the blood.

"The reason is very simple," Cheng said. "Unlike water, blood has many components like surfactants and lipids and proteins that interact with the whole micelle structure. As a result, the micelles are unstable in blood and the drug is released too soon."

The Purdue researchers tested how stable micelles are in different blood components. Findings indicated that the micelles remained intact in red blood cells and components of blood plasma except for a class of plasma proteins called alpha and beta globulins, which caused the drug to be released.

"There could also be other blood components that cause the drug to be released, but our proposal of using crosslinking could prevent this from happening," Cheng said.

Future research may concentrate on creating micelles that remain intact longer in the blood by using the crosslinking.

The research has been funded by the Oncological Sciences Center in Purdue's Discovery Park, the National Science Foundation and the National Institutes of Health.

The research paper appearing this week in Proceedings of the National Academy of Sciences was written by graduate students Hongtao Chen and Li Li, and visiting scholar Shuyi Wang, post-doctoral research assistant Sungwon Kim, Park and Cheng. The paper appearing in May in Langmuir was written by Chen, Kim, and doctoral students Wei He and Haifeng Wang, Philip S. Low, the Ralph C. Corley Distinguished Professor of Chemistry and a researcher in Purdue's Oncological Sciences Center, Park and Cheng.
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