The proposed instrumentation for rapid sorting and staining of cellular samples will provide a convenient tool in a number of cellular analyses and manipulations including diagnoses (e.g., for isolation of circulating tumor cells or circulating feal cells) and therapies (e.g., hematopoietic stem cells transplantation, stem cell based regenerative medicine) based on rare cell isolation from blood or other tissues. While this proposal focuses on simple cell sorting and staining protocols and analysis of cells by multicolor flow cytometry, this versatile, modular system will allow the efficient collection and efficient preparation of cellular samples for a wide variety of clinically relevant analyses such as genotyping/phenotyping assays (e.g., tumor genotyping), drug or chemosensitivity assays, drug reactivity profiles, mutational analyses and high-throughput gene sequencing. The proposed instrumentation will thus have potential impact across a wide cross section of medical applications and general relevance to the improvement of public health.

Public Health Relevance

This project aims to develop a next generation instrument for cell sorting and cell sample preparation (e.g., multimarker staining) to address the rapidly increasing need for methods to isolate and analyze rare cells in complex mixtures for a variety of clinical and biomedical research applications. This instrument will be a standalone, automated, 'front end' processor for complex samples containing low concentrations of target cells that will be rapidly isolated and stained prior to downstream analysis, for example by flow cytometry. This instrumentation will be distinguished from all other cell manipulation systems through its innovative use of biospecific negative acoustic contrast particles (NACPs, which have been developed in the PI's laboratory) for capture and manipulation of specific cells in the mixture. The cell-sample processing system will use interchangeable, chip-based modules containing fluidic channels that support acoustic (ultrasonic) standing waves for discriminative manipulation of NACP labeled cells and unlabeled cells within laminar streamlines. NACP-bound target cells will rapidly migrate via acoustophoresis to the antinodes of the acoustic standing wave (where the acoustic pressure changes most), whereas unlabeled cells (which exhibit positive acoustic contrast) will quickly transport to the node in the acoustic standing wave (where the pressure acoustic pressure changes least). The central hypothesis of this work is that exploitation of the discriminating and opposite forces on labeled and unlabeled cells, which is a unique feature of the proposed approach, will allow greater efficiency and versatility in continuous cell isolation and sorting thn existing methods, such as magnetically activated cell sorting. The final prototype integrated system developed will incorporate three interchangeable, chip-based modules: one that allows rare cell isolation using acoustophoresis (positive selection) and multimarker staining, one that allows both rare cell isolation and debulking by acoustophoresis (negative selection) in continuous flows, and one that allows both debulking and rare cell isolation by a serial combination of acoustophoresis and acoustically-enhanced magnetophoresis in continuous flows in a single chip. The outcome of this exploratory research will be a prototype of a revolutionary yet affordable instrumentation system for comprehensive rapid cell isolation and multimarker staining for downstream quantitative fluorimetric analysis to determine cellular phenotype. While this instrument will be validated using flow cytometry as a convenient, widely available, downstream quantitative cellular analysis tool to determine cell phenotype, the new instrument will be useful for the processing of a wide range of cell types in a wide range of clinically relevant analyses including genotyping, drug and chemosensitivity assays, drug reactivity profiles, mutational analyses and high throughput gene sequencing, as well as the isolation of rare cells (e.g., stem cells) for therapeutic applications.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Exploratory/Developmental Grants (R21)
Project #
5R21GM111584-03
Application #
9096844
Study Section
Special Emphasis Panel (ZGM1)
Program Officer
Smith, Ward
Project Start
2014-09-20
Project End
2017-06-30
Budget Start
2016-07-01
Budget End
2017-06-30
Support Year
3
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Duke University
Department
Biomedical Engineering
Type
Biomed Engr/Col Engr/Engr Sta
DUNS #
044387793
City
Durham
State
NC
Country
United States
Zip Code
27705
Li, Linying; Li, Nan K; Tu, Qing et al. (2018) Functional Modification of Silica through Enhanced Adsorption of Elastin-Like Polypeptide Block Copolymers. Biomacromolecules 19:298-306
Ohiri, Korine A; Kelly, Sean T; Motschman, Jeffrey D et al. (2018) An acoustofluidic trap and transfer approach for organizing a high density single cell array. Lab Chip 18:2124-2133
Shields 4th, C Wyatt; Ohiri, Korine A; Szott, Luisa M et al. (2017) Translating microfluidics: Cell separation technologies and their barriers to commercialization. Cytometry B Clin Cytom 92:115-125
Shields 4th, C Wyatt; Cruz, Daniela F; Ohiri, Korine A et al. (2016) Fabrication and Operation of Acoustofluidic Devices Supporting Bulk Acoustic Standing Waves for Sheathless Focusing of Particles. J Vis Exp :
Li, Linying; Mo, Chia-Kuei; Chilkoti, Ashutosh et al. (2016) Creating cellular patterns using genetically engineered, gold- and cell-binding polypeptides. Biointerphases 11:021009
Shields 4th, C Wyatt; Reyes, Catherine D; López, Gabriel P (2015) Microfluidic cell sorting: a review of the advances in the separation of cells from debulking to rare cell isolation. Lab Chip 15:1230-49