| NSF Org: |
ECCS Division of Electrical, Communications and Cyber Systems |
| Recipient: |
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| Initial Amendment Date: | May 10, 2019 |
| Latest Amendment Date: | July 20, 2021 |
| Award Number: | 1917295 |
| Award Instrument: | Standard Grant |
| Program Manager: |
Svetlana Tatic-Lucic
ECCS Division of Electrical, Communications and Cyber Systems ENG Directorate for Engineering |
| Start Date: | July 1, 2019 |
| End Date: | June 30, 2023 (Estimated) |
| Total Intended Award Amount: | $277,733.00 |
| Total Awarded Amount to Date: | $293,733.00 |
| Funds Obligated to Date: |
FY 2021 = $16,000.00 |
| History of Investigator: |
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| Recipient Sponsored Research Office: |
809 S MARSHFIELD AVE M/C 551 CHICAGO IL US 60612-4305 (312)996-2862 |
| Sponsor Congressional District: |
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| Primary Place of Performance: |
842 W Taylor Street Chicago IL US 60607-7021 |
| Primary Place of
Performance Congressional District: |
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| Unique Entity Identifier (UEI): |
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| Parent UEI: |
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| NSF Program(s): | CCSS-Comms Circuits & Sens Sys |
| Primary Program Source: |
01002122DB NSF RESEARCH & RELATED ACTIVIT |
| Program Reference Code(s): |
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| Program Element Code(s): |
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| Award Agency Code: | 4900 |
| Fund Agency Code: | 4900 |
| Assistance Listing Number(s): | 47.041 |
ABSTRACT
Circulating tumor cells are increasingly recognized as predictive biomarkers in early cancer detection; therefore, detecting circulating tumor cells in the peripheral blood of patients has important implications for clinical applications, which include early cancer detection as well as diagnoses and prediction of cancer progression. If viable unmodified circulating tumor cells can be separated from whole blood, then subsequent clinical analysis of these cells can lead to personalized cancer treatment. However, due to the extreme rarity of circulating tumor cells, a successful separation technology must meet the performance metrics of high-throughput, high-sensitivity, high-purity, and high-viability simultaneously to be useful - a goal that has never been achieved. To tackle these performance metrics, this project utilizes a novel threefold method called Three-Dimensional Deterministic Dielectrophoresis. Currently, the combined effects of three-dimensional geometry, deterministic lateral displacement and dielectrophoresis in a cell separation process represent a gap in research. Through this research, comprehensive understanding of the interplay between fluid mechanics, cell deformation, dielectrophoretic forces, and deterministic lateral displacement structures will be gained, which will lead to much improved sensitivity, purity, and cell viability at high-throughput - all requirements to be met at the same time. Additionally, the project will have a significant impact on a large number of underrepresented students in technical fields at both University of Illinois at Chicago (a federally designated Minority Serving Institution) and Washington State University Vancouver (a Research in Undergraduate Institutions eligible institution and the only four-year research university in southwest Washington).
The Three-Dimensional Deterministic Dielectrophoresis method brings a transformative impact by creating meaningful and valuable links between previously unconnected ideas and domain knowledge - namely deterministic lateral displacement, dielectrophoresis, and three-dimensional printing - potentially disrupting and outperforming all existing alternatives. However, in order to make the method truly useful for medical practice, fundamental knowledge about the separation process must be gained. This breaks down into three research objectives: 1) Study cell transport, cell-obstacle collision dynamics, and cell dielectrophoresis in periodic obstacle arrays using predictive models with experimental validations; 2) Fabricate Three-Dimensional Deterministic Dielectrophoresis devices and characterize how different obstacle shapes, geometries, obstacle array patterns, dielectrophoresis field parameters, carrier fluids and flow rates influence the cell separation performance; 3) Characterize circulating tumor cell separation performance for lung tumor cells against the four performance metrics above. This proposed research is significant because the multiphysics numerical models will elucidate scientific mechanisms of the complex separation principles of this method, which will guide experimental realization of a microfluidic device for high-throughput label-free circulating tumor cell separation. The research is unique in that dielectrophoresis will be combined with deterministic lateral displacement in a three-dimensional micro-structure for the first time, which is enabled by state-of-the-art nano three-dimensional printing technology. The research outcomes here have important implications for clinical applications including early cancer detection as well as diagnosis and prediction of cancer progression, as circulating tumor cells are increasingly recognized as predictive biomarkers in early stage cancer.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
PUBLICATIONS PRODUCED AS A RESULT OF THIS RESEARCH
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PROJECT OUTCOMES REPORT
Disclaimer
This Project Outcomes Report for the General Public is displayed verbatim as submitted by the Principal Investigator (PI) for this award. Any opinions, findings, and conclusions or recommendations expressed in this Report are those of the PI and do not necessarily reflect the views of the National Science Foundation; NSF has not approved or endorsed its content.
Over the past four years, the research team worked collaboratively to revolutionize the tumor cell separation technology by focusing on the design and fabrication of dielectrophoretic microfluidic devices. The project aimed to address critical challenges in integration of three-dimensional dielectrophoresis on microfluidic devices. The core objective of the project was to develop advanced label-free tumor cells separation microfluidic strategies that could significantly enhance the efficiency and reliability of cancer diagnosis. The team tackled this goal through a multidisciplinary approach, combining engineering principles, materials science, and computational simulations.
The key outcomes in this project include 1) Innovative lab-on-foil microfluidic device: The research led to the creation of a novel manufacturing that reduces the fabrication time and cost on dielectrophoretic microfluidic devices in biomedical applications. By incorporating biomedical thin-film materials and conductive ink-printing, the team achieved a fast and low-cost devices fabrication method compared to conventional combinations of lithography and metal deposition. This innovation not only contributes to accelerate biomedical device development but also demonstrates the value of advanced micro-manufacturing. 2) Cell manipulation by nonuniform electric field (dielectrophoresis): Another pivotal aspect of this project involved exploring for three-dimensional tumor cell separation by dielectrophoresis. Through rigorous theoretical and experimental analysis and testing, the team came up with bottom-to-top design of microelectrode array, which improves the throughput of cancel cell separation and opens the potential for cancer cell manipulation in microfluidic devices. 3) Fluid manipulation by electroosmosis: The team developed fluid manipulation method through the control of adjustable electroosmotic flow in a microfluidic channel. This dynamic electroosmotic fluidic system ensures the biological samples homogeneity in the microfluidic devices.
Beyond the technical outcomes, this project prioritized educational outreach to culture an environment for students, scholar and the general public for understanding of microfluidics in biomedical applications. The team presented their work in workshops, webinars, and interactive demonstrations at university and community events. This engagement not only sparked interest in STEM fields but also raised awareness about the importance of interdisciplinary study between engineering and biomedicine. Indeed, throughout the life of the project, the engineers collaborated with biomedical research partners, fostering a collaborative environment that accelerated cancer disease research. Specifically, by contributing to the development of more efficient and reliable biomedical devices, the project addressed the urgent need for early-stage cancer diagnosis using microfluidic cell manipulation techniques.
Last Modified: 11/12/2023
Modified by: Jie Xu
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