Browsing by Subject "Cell Sorting"
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Item Open Access Acoustic and Magnetic Techniques for the Isolation and Analysis of Cells in Microfluidic Platforms(2016) Shields IV, Charles WyattCancer comprises a collection of diseases, all of which begin with abnormal tissue growth from various stimuli, including (but not limited to): heredity, genetic mutation, exposure to harmful substances, radiation as well as poor dieting and lack of exercise. The early detection of cancer is vital to providing life-saving, therapeutic intervention. However, current methods for detection (e.g., tissue biopsy, endoscopy and medical imaging) often suffer from low patient compliance and an elevated risk of complications in elderly patients. As such, many are looking to “liquid biopsies” for clues into presence and status of cancer due to its minimal invasiveness and ability to provide rich information about the native tumor. In such liquid biopsies, peripheral blood is drawn from patients and is screened for key biomarkers, chiefly circulating tumor cells (CTCs). Capturing, enumerating and analyzing the genetic and metabolomic characteristics of these CTCs may hold the key for guiding doctors to better understand the source of cancer at an earlier stage for more efficacious disease management.
The isolation of CTCs from whole blood, however, remains a significant challenge due to their (i) low abundance, (ii) lack of a universal surface marker and (iii) epithelial-mesenchymal transition that down-regulates common surface markers (e.g., EpCAM), reducing their likelihood of detection via positive selection assays. These factors potentiate the need for an improved cell isolation strategy that can collect CTCs via both positive and negative selection modalities as to avoid the reliance on a single marker, or set of markers, for more accurate enumeration and diagnosis.
The technologies proposed herein offer a unique set of strategies to focus, sort and template cells in three independent microfluidic modules. The first module exploits ultrasonic standing waves and a class of elastomeric particles for the rapid and discriminate sequestration of cells. This type of cell handling holds promise not only in sorting, but also in the isolation of soluble markers from biofluids. The second module contains components to focus (i.e., arrange) cells via forces from acoustic standing waves and separate cells in a high throughput fashion via free-flow magnetophoresis. The third module uses a printed array of micromagnets to capture magnetically labeled cells into well-defined compartments, enabling on-chip staining and single cell analysis. These technologies can operate in standalone formats, or can be adapted to operate with established analytical technologies, such as flow cytometry. A key advantage of these innovations is their ability to process erythrocyte-lysed blood in a rapid (and thus high throughput) fashion. They can process fluids at a variety of concentrations and flow rates, target cells with various immunophenotypes and sort cells via positive (and potentially negative) selection. These technologies are chip-based, fabricated using standard clean room equipment, towards a disposable clinical tool. With further optimization in design and performance, these technologies might aid in the early detection, and potentially treatment, of cancer and various other physical ailments.
Item Embargo Aptamers as Reversible Sorting Ligands in Dual FACS and MACS: Antisense and Nuclease-Mediated Approaches(2023) Requena, MartinFluorescence Activated Cell Sorting (FACS) and Magnetic Activated Cell Sorting (MACS) are two essential tools for cell separation in research and medicine. Antibodies, the gold standard in both of these methods, are effective ligands for cell-surface biomarkers, but their irreversible binding precludes a wide variety of downstream medical and experimental applications. Aptamers – nucleic acid ligands with a defined three-dimensional structure that enables them to bind a molecular target with a high degree of specificity – offer a viable alternative for this particular obstacle because their RNA- or DNA-based chemistry enables their removal from cellular targets. In these studies, we present examples of successful sorting of cells and removal of the targeting aptamers with MACS and FACS using both the previously-published antisense-based method of post-sorting aptamer removal and a more general approach using nuclease-based digestion of targeting aptamers on the cell surface after cell isolation. We believe this work can be used in a number of potential post-sorting applications where targeting ligands or attached magnetic or fluorescent moieties could interfere with experimental or clinical results.