The planar chip format that is widespread is microfluidics is ideally suited for a number of applications by virtue of the ability to create complex structures and functionalities all on the same substrate. Nonetheless, planar chips are typically limited to creating two-dimensional extruded features. Fibers, meanwhile, are drawn structures that today only used as passive fluid conduits (capillaries) to transfer liquids from one platform to another. Here we propose to utilize fibers to create active microfluidic devices: multimaterial microfluidic fibers (MMMF) that are fabricated in a thermal drawing process, allowing formation of complex cross-sectional geometries using a variety of materials (polymers, metals, semiconductors) with micron to nanometer resolution, along meters of fiber. MMMF provides a complementary route to creating microfluidic devices that leverages new dimensions of freedom. To illustrate the concept of an active MMMF, we specifically propose to develop fibers that perform dielectrophoretic (DEP) cell separations, leveraging the fiber format to attain 1 ml/min mammalian cell separation in physiological buffer, which is 100-1000 faster than comparable devices. The approach is to use DEP forces to alter the particle equilibrium points that exist in inertial microfluidic flows, using the cross- sectional geometry of the fiber to allow for the creation of complex electrode geometry. Critically, advances in additive manufacturing now make it feasible to interface to fibers to send particles from separated flow streams to distinct outlets. Over the course of two Aims, we propose to first develop a MMMF capable of using DEP-modulated inertial forces to separate mammalian cells in physiological buffer at rates of 1 mL/min. We will then apply these fibers to separate immune cells based on their electrical signatures, which are correlated to immune cell activation state, and holds promise as a method to monitor the immune system during sepsis.

Public Health Relevance

Analyzing and separating cells is routinely performed throughout clinical medicine. We are proposing to develop a method to much more quickly process cell samples to speed up clinical decision-making. The method uses a variant of the technology used to make optical fibers, here employed to separate cells.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21EB022729-01A1
Application #
9317128
Study Section
Instrumentation and Systems Development Study Section (ISD)
Program Officer
Lash, Tiffani Bailey
Project Start
2017-02-01
Project End
2019-01-31
Budget Start
2017-02-01
Budget End
2018-01-31
Support Year
1
Fiscal Year
2017
Total Cost
$206,954
Indirect Cost
$56,954
Name
Massachusetts Institute of Technology
Department
Type
Organized Research Units
DUNS #
001425594
City
Cambridge
State
MA
Country
United States
Zip Code
02142
Yuan, Rodger; Lee, Jaemyon; Su, Hao-Wei et al. (2018) Microfluidics in structured multimaterial fibers. Proc Natl Acad Sci U S A 115:E10830-E10838