Nanotechnology Now - Press Release: Nanoparticles combine photodynamic and molecular therapies against pancreatic cancer: Novel drug-delivery system cuts off common treatment escape pathways in animal models

Home > Press > Nanoparticles combine photodynamic and molecular therapies against pancreatic cancer: Novel drug-delivery system cuts off common treatment escape pathways in animal models

Abstract:
A nanoparticle drug-delivery system that combines two complementary types of anticancer treatment could improve outcomes for patients with pancreatic cancer and other highly treatment-resistant tumors while decreasing toxicity. In their report that has received advance online publication in Nature Nanotechnology, a research team based at the Wellman Center for Photomedicine at Massachusetts General Hospital (MGH) describes how a nanomedicine that combines photodynamic therapy - the use of light to trigger a chemical reaction - with a molecular therapy drug targeted against common treatment resistance pathways reduced a thousand-fold the dosage of the molecular therapy drug required to suppress tumor progression and metastatic outgrowth in an animal model.

Nanoparticles combine photodynamic and molecular therapies against pancreatic cancer: Novel drug-delivery system cuts off common treatment escape pathways in animal models

Boston, MA | Posted on January 21st, 2016

"A broad challenge in cancer treatment is that tumor cells use a network of cellular signaling pathways to resist and evade treatment," says Bryan Spring, PhD, of the Wellman Center, co-lead author of the report. "The new optically active nanoparticle we have developed is able both to achieve tumor photodamage and to suppress multiple escape pathways, opening new possibilities for synchronized multidrug combination therapies and tumor-focused drug release."

Photodynamic therapy (PDT), involves the use of chemicals called photosensitizers that are activated by exposure to specific wavelengths of light to release reactive molecules that can damage nearby cells. In cancer treatment, PDT damages both tumor cells and their blood supply, directly killing some tumor cells and starving those that remain of nutrients. But as with many other types of treatments, treating tumors with PDT can stimulate molecular signaling pathways that support tumor survival.

The nanomedicine developed by the Wellman-based team is made up of nanoliposomes - spherical lipid membrane structures - enclosing a polymer nanoparticle that has been loaded with a targeted molecular therapy drug. The lipid membrane of these photoactivable multi-inhibitor nanoliposomes (PMILs) contains a FDA-approved photosensitizer called BPD (benzoporphyrin derivative), and the nanoparticles are loaded with a molecular therapy drug called XL184 or cabozantinib. XL184 inhibits two important treatment escape pathways, VEGF and MET, but while it has FDA approval to treat thyroid cancer and is being tested against pancreatic cancer and several other tumors, it is quite toxic requiring dose restrictions or treatment interruption. Since XL184 is delivered to every part of the body and not just to the tumor when administered orally, enclosing it in the PMIL could reduce toxicity by confining its action to the area of the tumor.

Led by Tayyaba Hasan, PhD, of the Wellman Center, the investigators first confirmed in laboratory experiments that exposing PMILs to near-infrared light both activated the antitumor action of BPD and, by disrupting the lipid membrane envelope, released the XL184-containing nanoparticles. In two mouse models of pancreatic cancer, a single treatment consisting of intravenous delivery of the PMILs followed by localized delivery of near-infrared light to the tumor site via optical fibers resulted in significantly greater reduction in tumor size than did either treatment with XL184 or PDT with BPD alone. PMIL treatment also was significantly more effective than treatment with both XL184 and BPD-PDT given as separate agents. Along with prolonged tumor reduction, PMIL treatment also almost completely suppressed metastasis in the mouse models.

While the VEGF treatment escape pathway is known to be induced and sensitized by PDT, the research team found that PDT also induces signaling via the MET pathway. The ability to deliver XL184 and PDT almost simultaneously allowed the two therapeutics to be "at the right place at the right time" to cut off the rapid initiation of escape signaling that usually follows PDT. This was reflected in how much more efficient PMIL-delivered treatment was in the animal models compared to either treatment alone, since PDT simultaneously sensitized the tumor to the second therapy. Delivery of XL184 directly to the tumor site produced these promising results at a dosage level less than one thousandth of what is used in oral therapy, with little or no toxicity.

"Right now we can say this approach has tremendous potential for patients with locally advanced pancreatic cancer, for whom surgery is not possible," says Hasan. "In our Phase I/II clinical studies with PDT alone, tumor destruction was achieved in all cases, and we've seen at least one case where PDT alone induced enough tumor shrinkage to enable follow-up surgery. The more robust tumor reduction and suppression of escape pathways possible with PMILs might enable curative surgery or improve the outcome of chemotherapy to enhance patient survival. But while we are encouraged by these results, this combination in a new nanoconstruct needs more validation before becoming a clinical treatment option"

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Previously a research fellow in Dermatology at the Wellman Center, Spring is now an assistant professor of Physics at Northeastern University. Hasan is a professor of Dermatology and of Health Sciences and Technology at Harvard Medical School. Bryan Sears and Lei Zak Zheng of the Wellman Center are also first co-authors of the Nature Nanotechnology paper. Additional co-authors are Zhiming Mai, PhD, and Margaret Sherwood, Wellman Center; Reika Watanab and Elizabeth Villa, PhD, University of California San Diego; David Schoenfeld, PhD, MGH Biostatistics; Brian Pogue, PhD, Dartmouth College; and Stephen Pereira, PhD, University College London. This study was supported by National Institutes of Health grants RC1-CA146337, R01-CA160998, P01-CA084203, and F32-CA144210.

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About Massachusetts General Hospital
Massachusetts General Hospital, founded in 1811, is the original and largest teaching hospital of Harvard Medical School. The MGH conducts the largest hospital-based research program in the United States, with an annual research budget of more than $800 million and major research centers in AIDS, cardiovascular research, cancer, computational and integrative biology, cutaneous biology, human genetics, medical imaging, neurodegenerative disorders, regenerative medicine, reproductive biology, systems biology, transplantation biology and photomedicine. In July 2015, MGH returned into the number one spot on the 2015-16 U.S. News & World Report list of "America's Best Hospitals."

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