Abstract
The isolation of a patient's metastatic cancer cells is the first, enabling step toward treatment of that patient using modern personalized medicine techniques. Whereas traditional standard-of-care approaches select treatments for cancer patients based on the histological classification of cancerous tissue at the time of diagnosis, personalized medicine techniques leverage molecular and functional analysis of a patient's own cancer cells to select treatments with the highest likelihood of being effective. Unfortunately, the pure populations of cancer cells required for these analyses can be difficult to acquire, given that metastatic cancer cells typically reside in fluid containing many different cell populations. Detection and analyses of cancer cells therefore require separation from these contaminating cells. Conventional cell sorting approaches such as Fluorescence Activated Cell Sorting or Magnetic Activated Cell Sorting rely on the presence of distinct surface markers on cells of interest which may not be known nor exist for cancer applications. In this work, we present a microfluidic platform capable of label-free enrichment of tumor cells from the ascites fluid of ovarian cancer patients. This approach sorts cells based on differences in biomechanical properties, and therefore does not require any labeling or other pre-sort interference with the cells. The method is also useful in the cases when specific surface markers do not exist for cells of interest. In model ovarian cancer cell lines, the method was used to separate invasive subtypes from less invasive subtypes with an enrichment of ~ sixfold. In ascites specimens from ovarian cancer patients, we found the enrichment protocol resulted in an improved purity of P53 mutant cells indicative of the presence of ovarian cancer cells. We believe that this technology could enable the application of personalized medicine based on analysis of liquid biopsy patient specimens, such as ascites from ovarian cancer patients, for quick evaluation of metastatic disease progression and determination of patient-specific treatment.
Highlights
The isolation of a patient’s metastatic cancer cells is the first, enabling step toward treatment of that patient using modern personalized medicine techniques
Metastasis plays a large role in ovarian cancer related mortality, given that 75% of ovarian cancer patients already have metastatic disease at the time of diagnosis, resulting in a five year survival rate of only 48.6%1,2
Cells with different biomechanical properties are directed towards different outlets, of which there are 5 in total. Performance of this device for a given application depends on careful selection of device geometry and flow rate in order to find a productive balance between hydrodynamic and mechanical forces operating on the cell
Summary
The isolation of a patient’s metastatic cancer cells is the first, enabling step toward treatment of that patient using modern personalized medicine techniques. We present a microfluidic platform capable of label-free enrichment of tumor cells from the ascites fluid of ovarian cancer patients This approach sorts cells based on differences in biomechanical properties, and does not require any labeling or other pre-sort interference with the cells. In ascites specimens from ovarian cancer patients, we found the enrichment protocol resulted in an improved purity of P53 mutant cells indicative of the presence of ovarian cancer cells We believe that this technology could enable the application of personalized medicine based on analysis of liquid biopsy patient specimens, such as ascites from ovarian cancer patients, for quick evaluation of metastatic disease progression and determination of patient-specific treatment. One marker used to assess malignancy in ovarian cancer is TGM2, but the resulting protein TG2 is expressed in a wide variety of tissues and detectible in all o rgans[10]
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