Personalized in vitro model enables drug screening for kidney cancer

Personalized in vitro model enables drug screening for kidney cancer
Tumor and normal tissue are removed from the patient during surgery, the cells are isolated, and then injected into the lumen device created by the Beebe lab. There they grew into three-dimensional models of kidney cancer blood vessels. Credit: University of Wisconsin-Madison

One way to treat the most common type of kidney cancer is to use anti-angiogenic drugs to cut off the blood supply to the tumors, but patients respond differently to the drugs, and choosing the wrong one can make the cancer grow faster.

A new UW Carbone Cancer Center study, published online this week in EBioMedicine, has developed a model that mimics the tumor's blood supply on a three-dimensional platform designed in the laboratory of Dr. David Beebe, professor of biomedical engineering and pathology. The authors of the study, led by Drs. Jose "Tony" Jimenez-Torres and Maria Virumbrales-Munoz, used both normal and cancerous tissue from patients to grow the . They replicated many of the structures seen in the normal and -tissue blood supplies and used them to test targeted drugs used to treat renal cell carcinoma.

Renal cell carcinoma is the third most common genitourinary cancer in the United States, with about 64,000 new cases each year. This tends not to respond to standard chemotherapy, so anti-angiogenic targeted agents, which can cut off the to tumors by inhibiting vessel formation, are often used.

"In this type of cancer, clinicians report that giving the patients the wrong drug can be counterproductive,'' says Virumbrales-Munoz. "You can actually increase angiogenesis and feed the tumor more. This screening approach could help us make treatment decisions for each patient, knowing beforehand the outcome of their treatment."

Personalized in vitro model enables drug screening for kidney cancer
Photos of the in-vitro vasculature show vessels on the left before treatment. The vessel in the top photo was untreated and was sprouting after 48 hours. The vessel on the bottom received sunitinib, and 48 hours later shows few or no sprouts. The graph shows patient models that did respond to the drug (those below 0 on the graph) and those (above 0) that did not. Credit: University of Wisconsin-Madison

Jimenez-Torres says the lab was able to create an in vitro model of each patient's tumor blood vessels to test the effect of anti-angiogenic drugs. The normalization of tumor blood vessels in response to anti-angiogenic drugs would lead to decreases in tumor size.

"This is the first model for that enables personalized anti-angiogenic drug testing'' explains Jimenez-Torres.

The preliminary data of this study was so promising that the group was awarded a $1.5 million Cancer Moonshot grant from the National Cancer Institute to compare the results of the personalized model with patient response.

The "moonshot" clinical study will use (PET) imaging before and after the patients are treated for their cancer, to see whether it responded to a particular drug. Meanwhile, in the Beebe lab, the tumor tissue will be grown into three-dimensional blood vessel structures and treated with the drugs. The goal is to see whether the in vitro model predicts the patient response.

"Our future goal is not to test every single patient, but to develop a list of markers that will better predict which patient will respond to a treatment,'' says Virumbrales-Munoz.

Explore further

Tumor growth parameters predict response to anti-angiogenic therapy in mice

More information: José A. Jiménez-Torres et al. Patient-specific organotypic blood vessels as an in vitro model for anti-angiogenic drug response testing in renal cell carcinoma, EBioMedicine (2019). DOI: 10.1016/j.ebiom.2019.03.026
Journal information: EBioMedicine

Citation: Personalized in vitro model enables drug screening for kidney cancer (2019, March 27) retrieved 21 September 2019 from
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