Posted: Mar 01, 2016
Researchers involved in a national effort to develop cancer treatments that harness nanotechnology are recommending pivotal changes in the field because experiments with laboratory animals and efforts based on current assumptions about drug delivery have largely failed to translate into successful clinical results.
The assessment was advanced in a perspective piece that (“Targeting the Tumor Microenvironment”; pdf) appeared in the National Cancer Institute’s Cancer Nanotechnology Plan 2015, a 10-year roadmap concerning the use of nanotechnology to attack cancer.
The complex microenvironment of tumors is presenting a challenge in developing effective anticancer treatments
The complex microenvironment of tumors is presenting a challenge in developing effective anticancer treatments that attempt to harness nanotechnology. Researchers are recommending pivotal changes in the field of cancer nanotechnology because experiments with laboratory animals and efforts based on current assumptions about drug delivery have largely failed to translate into successful clinical results. (Image: Bumsoo Han, Kinam Park, Murray Korc) (click on image to enlarge)
Researchers are trying to perfect “targeted delivery” methods using various agents, including an assortment of tiny nanometer-size structures, to selectively attack tumor tissue. However, the current direction of research has brought only limited progress, according to the authors of the article.
“The bottom line is that so far there are only a few successful nanoparticle formulations approved and clinically used, so we need to start thinking out of the box,” said Bumsoo Han, a Purdue University associate professor of mechanical and biomedical engineering.
One approach pursued by researchers has been to design nanoparticles small enough to pass through pores in blood vessels surrounding tumors but too large to pass though the pores of vessels in healthy tissue. The endothelial cells that make up healthy blood vessels are well organized with tight junctions between them. However, the endothelial cells in blood vessels around tumors are irregular and misshapen, with loose gaps between the cells.
“We should realize that having a specific nanosize or functionality alone is not enough to guarantee good drug delivery to target tumors,” said Kinam Park, a professor of pharmaceutics and Purdue’s Showalter Distinguished Professor of Biomedical Engineering. “The tumor microenvironment is just too complex to overcome using this strategy alone.”
The two authored the article with Murray Korc, the Myles Brand Professor of Cancer Research at the Indiana University School of Medicine.
The authors pointed out that research with laboratory mice has rarely translated into successful clinical results in humans, suggesting that a more effective approach might be to concentrate on research using in-vitro experiments that mimic human physiology. For example, one new system under development, called a tumor-microenvironment-on-chip (T-MOC) device, could allow researchers to study the complex environment surrounding tumors and the barriers that prevent the targeted delivery of therapeutic agents.
The approach could help drug makers solve a daunting obstacle: even if drugs are delivered to areas near the target tumor cells, the treatment still is hindered by the complex microenvironment of tumors.
“We used to think that if we just killed the tumor cell it would cure the cancer, but now we know it’s not just the cancer cells alone that we have to deal with,” Korc said. “There are a lot of different cells and blood vessel structure, making for a complex environment that supports the cancer cells.”
An “extracellular matrix” near tumors includes dense collagen bundles and a variety of enzymes, growth factors and cells. For example, surrounding pancreatic tumors is a “stromal compartment” containing a mixture of cells called stromal cells, activated cancer-associated fibroblasts and inflammatory immune cells.
“Particularly for pancreatic cancer, the stromal tissue is much bigger than the tumor itself,” Korc said.
In addition, a compound called hyaluronic acid in this stromal layer increases the toughness of tumor microenvironment tissue, making it difficult for nanoparticles and drugs to penetrate.
“It’s dense, like scar tissue, so it’s more difficult for drugs coming out of the blood vessel to diffuse through this tissue,” Han said.
Another challenge is to develop water-soluble drugs to effectively deliver medicines.
“The cancer drugs need to be aqueous because the body resorbs them better, but a lot of the current chemotherapy drugs have low solubility and usually need different types of solvents to increase their solubility,” Park said.
The T-MOC approach offers some hope of learning how to design more effective cancer treatments.
“Recent advances in tissue engineering and microfluidic technologies present an opportunity to realize in-vitro platforms as alternatives to animal testing,” Park said. “Tumor cells can be grown in 3D matrices with other relevant stromal cells to more closely mirror the complexity of solid tumors in patients. The current ability of forming 3D-perfused tumor tissue needs to be advanced further to create an accurate tumor microenvironment.”
Such a major shift in research focus could play a role in developing personalized medicine, or precision medicine, tailored to a particular type of cancer and specific patients. More effective treatment might require various “priming agents” in combination with several drugs to be administered simultaneously or sequentially.
“This kind of research currently involves a very large number of experiments, and it makes animal testing expensive and time consuming,” Park said. “Moreover, small animal data have not been good predictors of clinical outcome. Thus, it is essential to develop in-vitro test methods that can represent the microenvironment of human tumors.”
Source: By Emil Venere, Purdue University
Some drug regimens, such as those designed to eliminate tumors, are notorious for nasty side effects. Unwanted symptoms are often the result of medicine going where it’s not needed and harming healthy cells. To minimize this risk, researchers in Quebec have developed nanoparticles that only release a drug when exposed to near-infrared light, which doctors could beam onto a specific site. Their report appears in the Journal of the American Chemical Society.
For years, scientists have been striving to develop localized treatments to reduce side effects of therapeutic drugs. They have designed drug-delivery systems that respond to light, temperature, ultrasound and pH changes. One promising approach involved drug-carrying materials that are sensitive to ultraviolet (UV) light. Shining a beam in this part of the light spectrum causes the materials to release their therapeutic cargo at a designated location. But UV light has major limitations. It can’t penetrate body tissues, and it is carcinogenic. Near-infrared (NIR) light can go through 1 to 2 centimeters of tissue and would be a safer alternative, but photosensitive drug-carriers don’t react to it. McGill University engineering professor Marta Cerruti and colleagues sought a way to bring the two kinds of light together in one possible solution.
The researchers started with nanoparticles that convert NIR light into UV light and coated them in a UV-sensitive hydrogel shell infused with a fluorescent protein, a stand-in for drug molecules. When exposed to NIR light, the nanoparticles instantaneously converted it to UV, which induced the shell to release the protein payload. The researchers note that their on-demand delivery system could not only supply drug molecules but also agents for imaging and diagnostics.
- Ghulam Jalani, Rafik Naccache, Derek H. Rosenzweig, Lisbet Haglund, Fiorenzo Vetrone, Marta Cerruti.Photocleavable Hydrogel-Coated Upconverting Nanoparticles: A Multifunctional Theranostic Platform for NIR Imaging and On-Demand Macromolecular Delivery. Journal of the American Chemical Society, 2016; DOI: 10.1021/jacs.5b12357