Your search keyword '"Brandi E. Swain"' showing total 6 results

1. High throughput, label-free isolation of circulating tumor cell clusters in meshed microwells

Author

Mert Boya, Tevhide Ozkaya-Ahmadov, Brandi E. Swain, Chia-Heng Chu, Norh Asmare, Ozgun Civelekoglu, Ruxiu Liu, Dohwan Lee, Sherry Tobia, Shweta Biliya, L. DeEtte McDonald, Bassel Nazha, Omer Kucuk, Martin G. Sanda, Benedict B. Benigno, Carlos S. Moreno, Mehmet A. Bilen, John F. McDonald, and A. Fatih Sarioglu

Subjects

Science

Abstract

Metastatic CTC clusters remain relatively unexplored due to the lack of optimized and practical technologies for their detection. Here the authors report Cluster-Wells to isolate CTC clusters in whole blood; they show this allows viable cluster retrieval for further molecular and functional analysis.

Published

2022

2. Negative enrichment of circulating tumor cells from unmanipulated whole blood with a 3D printed device

Author

Chia-Heng Chu, Ruxiu Liu, Tevhide Ozkaya-Ahmadov, Brandi E. Swain, Mert Boya, Bassel El-Rayes, Mehmet Akce, Mehmet Asim Bilen, Omer Kucuk, and A. Fatih Sarioglu

Subjects

Medicine, Science

Abstract

Abstract Reliable and routine isolation of circulating tumor cells (CTCs) from peripheral blood would allow effective monitoring of the disease and guide the development of personalized treatments. Negative enrichment of CTCs by depleting normal blood cells ensures against a biased selection of a subpopulation and allows the assay to be applied on different tumor types. Here, we report an additively manufactured microfluidic device that can negatively enrich viable CTCs from clinically-relevant volumes of unmanipulated whole blood samples. Our device depletes nucleated blood cells based on their surface antigens and the smaller anucleated cells based on their size. Enriched CTCs are made available off the device in suspension making our technique compatible with standard immunocytochemical, molecular and functional assays. Our device could achieve a ~ 2.34-log depletion by capturing > 99.5% of white blood cells from 10 mL of whole blood while recovering > 90% of spiked tumor cells. Furthermore, we demonstrated the capability of the device to isolate CTCs from blood samples collected from patients (n = 15) with prostate and pancreatic cancers in a pilot study. A universal CTC assay that can differentiate tumor cells from normal blood cells with the specificity of clinically established membrane antigens yet require no label has the potential to enable routine blood-based tumor biopsies at the point-of-care.

Published

2021

3. Negative enrichment of circulating tumor cells from unmanipulated whole blood with a 3D printed device

Author

Mehmet Asim Bilen, Mert Boya, Bassel F. El-Rayes, A. Fatih Sarioglu, Mehmet Akce, Omer Kucuk, Chia-Heng Chu, Tevhide Ozkaya-Ahmadov, Ruxiu Liu, and Brandi E. Swain

Subjects

Adult, Male, 3d printed, Science, Tumor cells, Cell Count, Pilot Projects, Cell Separation, Article, Cancer screening, Circulating tumor cell, Antigen, Prostate, Cell Line, Tumor, Lab-On-A-Chip Devices, Leukocytes, Medicine, Humans, Whole blood, Cancer, Aged, Multidisciplinary, Lab-on-a-chip, business.industry, Microfluidic Analytical Techniques, Middle Aged, Neoplastic Cells, Circulating, Peripheral blood, medicine.anatomical_structure, Printing, Three-Dimensional, Cancer research, Normal blood, Female, business

Abstract

Reliable and routine isolation of circulating tumor cells (CTCs) from peripheral blood would allow effective monitoring of the disease and guide the development of personalized treatments. Negative enrichment of CTCs by depleting normal blood cells ensures against a biased selection of a subpopulation and allows the assay to be applied on different tumor types. Here, we report an additively manufactured microfluidic device that can negatively enrich viable CTCs from clinically-relevant volumes of unmanipulated whole blood samples. Our device depletes nucleated blood cells based on their surface antigens and the smaller anucleated cells based on their size. Enriched CTCs are made available off the device in suspension making our technique compatible with standard immunocytochemical, molecular and functional assays. Our device could achieve a ~ 2.34-log depletion by capturing > 99.5% of white blood cells from 10 mL of whole blood while recovering > 90% of spiked tumor cells. Furthermore, we demonstrated the capability of the device to isolate CTCs from blood samples collected from patients (n = 15) with prostate and pancreatic cancers in a pilot study. A universal CTC assay that can differentiate tumor cells from normal blood cells with the specificity of clinically established membrane antigens yet require no label has the potential to enable routine blood-based tumor biopsies at the point-of-care.

Published

2021

4. Hybrid negative enrichment of circulating tumor cells from whole blood in a 3D-printed monolithic device

Author

Tevhide Ozkaya-Ahmadov, John F. McDonald, Chia-Heng Chu, Brandi E. Swain, Mert Boya, Mehmet Asim Bilen, A. Fatih Sarioglu, Ruxiu Liu, Enerelt Burentugs, and Jacob M Owens

Subjects

Cell, Microfluidics, Biomedical Engineering, Bioengineering, Cell Separation, 02 engineering and technology, Immunofluorescence, 01 natural sciences, Biochemistry, Jurkat cells, Jurkat Cells, Prostate cancer, Circulating tumor cell, Lab-On-A-Chip Devices, Leukocytes, medicine, Humans, Whole blood, medicine.diagnostic_test, biology, Chemistry, 010401 analytical chemistry, General Chemistry, Neoplastic Cells, Circulating, 021001 nanoscience & nanotechnology, medicine.disease, 0104 chemical sciences, medicine.anatomical_structure, Printing, Three-Dimensional, biology.protein, Antibody, 0210 nano-technology, Antibodies, Immobilized, Biomedical engineering

Abstract

Isolation and analysis of circulating tumor cells (CTCs) from blood samples present exciting opportunities for basic cancer research and personalized treatment of the disease. While microchip-based negative CTC enrichment offers both sensitive microfluidic cell screening and unbiased selection, conventional microchips are inherently limited by their capacity to deplete a large number of normal blood cells. In this paper, we use 3D printing to create a monolithic device that combines immunoaffinity-based microfluidic cell capture and a commercial membrane filter for negative enrichment of CTCs directly from whole blood. In our device, stacked layers of chemically-functionalized microfluidic channels capture millions of white blood cells (WBCs) in parallel without getting saturated and the leuko-depleted blood is post-filtered with a 3 μm-pore size membrane filter to eliminate anucleated blood cells. This hybrid negative enrichment approach facilitated direct extraction of viable CTCs off the chip on a membrane filter for downstream analysis. Immunofluorescence imaging of enriched cells showed ∼90% tumor cell recovery rate from simulated samples spiked with prostate, breast or ovarian cancer cells. We also demonstrated the feasibility of our approach for processing clinical samples by isolating prostate cancer CTCs directly from a 10 mL whole blood sample.

Published

2019

5. High throughput, label-free isolation of circulating tumor cell clusters in meshed microwells

Author

Mert, Boya, Tevhide, Ozkaya-Ahmadov, Brandi E, Swain, Chia-Heng, Chu, Norh, Asmare, Ozgun, Civelekoglu, Ruxiu, Liu, Dohwan, Lee, Sherry, Tobia, Shweta, Biliya, L DeEtte, McDonald, Bassel, Nazha, Omer, Kucuk, Martin G, Sanda, Benedict B, Benigno, Carlos S, Moreno, Mehmet A, Bilen, John F, McDonald, and A Fatih, Sarioglu

Subjects

Male, Sequence Analysis, RNA, Humans, Neoplastic Cells, Circulating

Abstract

Extremely rare circulating tumor cell (CTC) clusters are both increasingly appreciated as highly metastatic precursors and virtually unexplored. Technologies are primarily designed to detect single CTCs and often fail to account for the fragility of clusters or to leverage cluster-specific markers for higher sensitivity. Meanwhile, the few technologies targeting CTC clusters lack scalability. Here, we introduce the Cluster-Wells, which combines the speed and practicality of membrane filtration with the sensitive and deterministic screening afforded by microfluidic chips. The100,000 microwells in the Cluster-Wells physically arrest CTC clusters in unprocessed whole blood, gently isolating virtually all clusters at a throughput of25 mL/h, and allow viable clusters to be retrieved from the device. Using the Cluster-Wells, we isolated CTC clusters ranging from 2 to 100+ cells from prostate and ovarian cancer patients and analyzed a subset using RNA sequencing. Routine isolation of CTC clusters will democratize research on their utility in managing cancer.

Published

2020

6. Solid-State Nanopore Analysis of Diverse DNA Base Modifications Using a Modular Enzymatic Labeling Process

Author

Derek Parsonage, Osama K. Zahid, Thomas Hollis, Rahul M. Kohli, Brandi E Swain, Ethan Will Taylor, Adam R. Hall, Fanny Wang, Scott Harvey, and Fred W. Perrino

Subjects

Models, Molecular, 0301 basic medicine, Guanine, DNA Repair, Base Pair Mismatch, Modularity (biology), Affinity label, Bioengineering, Biosensing Techniques, Computational biology, Article, Epigenesis, Genetic, Nanopores, 03 medical and health sciences, chemistry.chemical_compound, Neoplasms, Humans, Nanotechnology, General Materials Science, Epigenetics, Uracil, biology, Chemistry, Adenine, Mechanical Engineering, DNA, General Chemistry, Condensed Matter Physics, Base (topology), Molecular biology, Nanopore, genomic DNA, 030104 developmental biology, biology.protein, DNA Damage

Abstract

Many regulated epigenetic elements and base lesions found in genomic DNA can both directly impact gene expression and play a role in disease processes. However, due to their noncanonical nature, they are challenging to assess with conventional technologies. Here, we present a new approach for the targeted detection of diverse modified bases in DNA. We first use enzymatic components of the DNA base excision repair pathway to install an individual affinity label at each location of a selected modified base with high yield. We then probe the resulting material with a solid-state nanopore assay capable of discriminating labeled DNA from unlabeled DNA. The technique features exceptional modularity via selection of targeting enzymes, which we establish through the detection of four DNA base elements: uracil, 8-oxoguanine, T:G mismatch, and the methyladenine analog 1,N6-ethenoadenine. Our results demonstrate the potential for a quantitative nanopore assessment of a broad range of base modifications.

Published

2017