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July 28, 2014
Isolated Cancer Cells May Lead to Personalized Treatments
At a Glance
- Scientists used a novel microchip-based method to isolate and grow tumor cells circulating in blood.
- The technique provides an opportunity to test treatments on tumor cells, an important step toward personalizing cancer therapy.
Cells shed from tumors enter the bloodstream in very low numbers and circulate through the body. These circulating tumor cells (CTCs) can take root elsewhere, causing the spread of the cancer to other organs, a process called metastasis. As cancers grow and spread, they can undergo genetic mutations that enable them to become resistant to treatment and survive and grow at metastatic sites. The isolation and analysis of CTCs may thus be a useful method for tracking how cancers evolve during therapy.
Isolating these rare CTCs from the blood of cancer patients, however, has been a technical challenge. Recently, researchers developed a way to isolate CTCs using microfluidic technology. The microchip device, called the CTC-iChip, enriches CTCs by removing blood cells. As the method doesn鈥檛 rely on any cell-surface proteins expressed by tumor cells, it can be applied to virtually all cancers.
In their new study, the research team鈥攍ed by Drs. Shyamala Maheswaran and Daniel A. Haber of Massachusetts General Hospital and Harvard Medical School鈥攗sed the CTC-iChip to establish cell cultures from breast cancer patients. The work was funded in part by NIH鈥檚 National Cancer Institute (NCI) and National Institute of Biomedical Imaging and Bioengineering (NIBIB). The study was published on July 11, 2014, in Science.
The scientists collected blood samples from 36 patients with metastatic, estrogen-receptor-positive breast cancers. Using the CTC-iChip, the researchers isolated CTCs from these samples and were able to establish cell lines from 6 of the patients. They found that 3 of 5 tested cell lines formed tumors when injected into mice.
The CTC lines proved to be genetically different than the original tumors. Newly acquired mutations were found in several cancer-associated genes: fibroblast growth factor receptor (FGFR2), PIK3CA, TP53, KRAS, and estrogen receptor (ESR1).
The researchers tested a number of drugs on the cells to find better therapies to treat the cancers. They found that different combinations of drugs were effective against tumors carrying these acquired mutations.
鈥淭his approach of culturing circulating cancer cells in the blood, analyzing them for new mutations that have developed during therapy, and testing the utility of drugs targeting those mutations could become the essence of individually adjusted cancer therapy in the future,鈥 Haber says.
One major challenge before this strategy could be used in the clinic will be to make it easier to establish CTC lines from patients. 鈥淲e need to improve culture techniques before this is ready for clinical use, and we are working on doing that right now,鈥 Maheswaran says.
鈥攂y Shu Hui Chen, Ph.D.
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References: Yu M, Bardia A, Aceto N, Bersani F, Madden MW, Donaldson MC, Desai R, Zhu H, Comaills V, Zheng Z, Wittner BS, Stojanov P, Brachtel E, Sgroi D, Kapur R, Shioda T, Ting DT, Ramaswamy S, Getz G, Iafrate AJ, Benes C, Toner M, Maheswaran S, Haber DA. Science. 2014 Jul 11;345(6193):216-20. doi: 10.1126/science.1253533. PMID: 25013076.
Funding: NIH鈥檚 National Cancer Institute (NCI) and National Institute of Biomedical Imaging and Bioengineering (NIBIB); Breast Cancer Research Foundation, Stand Up to Cancer, the Wellcome Trust, National Foundation for Cancer Research, Susan G. Komen for the Cure, and the Howard Hughes Medical Institute.