Scientists Create Engineered Organ Model for Breast Cancer Research

Researchers have replicated portions of the female breast in a tiny slide-sized model called "breast on-a-chip” that will be used to evaluate nanomedical applications for the detection and treatment of breast cancer. The model mimics the branching mammary duct system, where most breast cancers begin, and will serve as an "engineered organ” to study the use of nanoparticles to detect and target tumor cells within the ducts.

Dr. Sophie Lelièvre, associate professor of basic medical sciences in the School of Veterinary Medicine (SVM), and Dr. James Leary, professor of nanomedicine and professor of basic medical sciences in the School of Veterinary Medicine and professor of biomedical engineering in the Weldon School of Biomedical Engineering at Purdue University (West Lafayette, IN, USA), led the team.

"Breast cancer is the most common cancer in women in most countries, and in the US alone nearly 40,000 women lost their lives to it this past year,” said Dr. Lelièvre, who is associate director of discovery groups in the Purdue Center for Cancer Research and a leader of the international breast cancer and nutrition project in the Oncological Sciences Center. "We've known that the best way to detect this cancer early and treat it effectively would be to get inside the mammary ducts to evaluate and treat the cells directly, and this is the first step in that direction.”

Dr. Lelièvre and Dr. Leary plan ultimately to be able to introduce magnetic nanoparticles through openings in the nipple, employ a magnetic field to guide them through the ducts where they would attach to cancer cells and then reverse the magnetic field to retract any excess nanoparticles.

The nanoparticles could carry contrast agents to improve mammography, fluorescent markers to guide surgeons or anticancer agents to treat the cancer, according to Dr. Leary. "Nanoparticles can be designed to latch on to cancer cells and illuminate them, decreasing the size of a tumor that can be detected through mammography from 5 mm to 2 mm, which translates into finding the cancer 10 times earlier in its evolution,” Dr. Leary said. "There also is great potential for nanoparticles to deliver anticancer agents directly to the cancer cells, eliminating the need for standard chemotherapy that circulates through the entire body causing harmful side effects."

Physicians have tried to access the mammary ducts through the nipple in the past, injecting fluid solutions to try to wash out cells that could be studied and used for a diagnosis of cancer. However, this approach could only reach the first third of the breast due to fluid pressure from the ducts, which branch and become smaller and smaller as they near the glands that produce milk, according to Dr. Leary. "The idea is that nanoparticles with a magnetic core can float through the naturally occurring fluid in the ducts and be pulled by a magnet as opposed to being pushed with pressure. We think they could reach all the way to the back of the ducts, where it is believed most breast cancers originate. Of course, we are only at the earliest stages and many tests need to be done.”

This sort of research could not be conducted using conventional models that grow cells across a flat surface in a plastic dish, so the investigators created the artificial organ-like model in which living cells line a three-dimensional model of the smallest portions of the mammary ducts.

Dr. Lelièvre, whose group is one of the few in the world able to grow the complicated cells that line the mammary ducts effectively, coaxed the cells to grow within the mold and behave as they would within a real human breast. "The cells within the breast ductal system have a very specific organization that has proven difficult to obtain in a laboratory,” Dr. Lelièvre said. "The cells have different sides, and one side must face the wall of the duct and the other must face the inner channel. Reproducing this behavior is very challenging, and it had never been achieved on an artificial structure before.”

The scientists coated the mold in a protein-based compound called laminin 111 as a foundation for the cells that allows them to attach to the mold and behave as they would inside the body, Dr. Lelièvre reported.

Because injecting the delicate cells into the finished channels of the mold caused too much damage, the researchers devised a removable top for the channels. "The design of the U-shaped channels and top was necessary for us to be able to successfully apply the cells, but it also allows us to make changes quickly and easily for different tests,” Dr. Lelièvre stated. "We can easily introduce changes among the cells or insert a few tumor cells to test the abilities of the nanoparticles to recognize them. The design also makes it very easy to evaluate the results as the entire model fits under a microscope.”

An article detailing the team's research was published January 2011 in the journal Integrative Biology. The team has demonstrated that nanoparticles can be moved within the bare channels of the mold filled with fluid, but has not yet moved nanoparticles through the finished model lined with living cells, Dr. Lelièvre reported. The investigators next plan to create and evaluated nanoparticles with a slippery surface that will prevent them from adhering to the cells as they move through the channels and coatings that contain antibodies to target and attach to specific types of cancerous and precancerous cells, she stated.

"Although we are at the very beginning stages of this work, we are hopeful that this nanomedical approach will one day save lives and provide patients with an easier road to recovery,” Dr. Lelièvre concluded. "The successful creation of this model is an important milestone in this work and it is a testament to what can be accomplished through multidisciplinary research.”

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