Gregory A Cooksey

Dr. Cooksey’s laboratory at NIST focuses on creating microfluidic tools to improve measurements and enable discoveries in biomedical and clinical research. His group is developing new approaches to measure optical properties of cells and materials in flow, and applications related to cytometry.

The group recently published the first direct uncertainty measurements in flow cytometry, which required novel flow control and analysis techniques in microfluidic devices with integrated waveguides. Work with collaborators in the Information Technology Laboratory is using signals analysis to improve counting, classification, and understanding of physical properties (e.g. size and shape) of objects in flow.

The team continues to improve accurate measurements of volumetric flow rates, recently demonstrating dynamic measurements of 1 nL/min with 5 % uncertainty and limit of detection of about 10 pL/min. The technique involves linking fluorescent properties of materials to the dosage of light they receive while flowing through an optical interrogation region.

These projects are part of the NIST on a Chip program and are supported by a NIST Innovation in Measurement Science (IMS) award.

Greg Cooksey joined NIST in 2007 as a National Research Council postdoctoral fellow and is a biomedical engineer and Project Leader in the Microsystems and Nanotechnology Division. Prior to NIST he was a graduate student and postdoctoral researcher at the University of Washington, where he developed surfaces and devices to study migrating cells and neurons.

Member Of

SELECTED PROGRAMS/PROJECTS

Research Opportunities Available

Potential Research Topics include:

Optofluidic cytometry design and characterization
Flow metrology; picoliter per minute measurements and dynamics
Microdroplet packaging and measurement
Cell-based microfluidic assays/diagnostics
Physical modeling, e.g. of dynamic systems in flow
Design of novel microfluidic functionalities

We encourage interested post-doctoral and graduate research candidates to contact us to discuss project opportunities and fellowships.

Click here to go to our project listing with the National Research Council (NRC)

Click here to find out how to apply for an NRC Postdoctoral Fellowship

Summer research opportunities for undergraduates (SURF Program) and high school students (SHIP Program) may also be available.

Please contact me for more details or to discuss other ways to work together.

Selected Publications

Serial flow cytometry in an inertial focusing optofluidic microchip for direct assessment of measurement variations

July 20, 2022

Author(s)

Matthew DiSalvo, Paul Patrone, Anthony J. Kearsley, Gregory A. Cooksey

Flow cytometry is an invaluable technology in biomedical research, yet it has limited ability to separate inherent sample variability from measurement

Dynamic Measurement of Nanoflows: Realization of an Optofluidic Flow Meter to the Nanoliter-per- Minute Scale

August 8, 2019

Author(s)

Gregory A. Cooksey, Paul N. Patrone, James R. Hands, Stephen E. Meek, Anthony J. Kearsley

The ultimate performance of flow-based measurements in microfluidic systems is limited by their accuracy at the nanoliter-per-minute scale. But improving such

Dynamic Measurement of Nanoflows: Analysis and Theory of an Optofluidic Flowmeter

March 11, 2019

Author(s)

Paul N. Patrone, Gregory A. Cooksey, Anthony J. Kearsley

Optofluidic Temperature and Pressure Measurements with Fiber Bragg Gratings Embedded in Microfluidic Devices

May 21, 2016

Author(s)

Gregory A. Cooksey, Zeeshan Ahmed

The integration of photonic sensors into microfluidic devices provides opportunities for dynamic measurement of chemical and physical properties of fluids in

Pneumatic valves in folded 2-D and 3-D fluidic devices made from plastic sheets and tapes

April 1, 2014

Author(s)

Gregory A. Cooksey, Francisco J. Atencia

We present a rapid prototyping technique that expands elastomeric valving capabilities to devices made from thin materials such as plastic films and tapes. A

A robust diffusion-based gradient generator for dynamic cell assays.

January 1, 2012

Author(s)

Francisco J. Atencia, Gregory A. Cooksey, Laurie E. Locascio

This manuscript describes a new method to generate purely diffusive chemical gradients that can be modified in time. The device is simple in its design and easy

Publications

Microfluidic-Integrated Chip Resonators for Electron Spin Sensing in Submicromolar, Submicroliter Solutions

October 15, 2024

Author(s)

Nandita Abhyankar, Megan Catterton, Gregory A. Cooksey, Veronika Szalai

We use planar inverse anapole (PIA) microresonators to report the first experimental demonstration of continuous wave (CW) electron paramagnetic resonance (EPR)

Relaxation times and dynamic behavior of an optofluidic flow meter in the nanoliter per minute regime

February 29, 2024

Author(s)

Nicholas Drachman, Paul Patrone, Gregory A. Cooksey

Accuracy and temporal resolution of flow meters are often unacceptable below the microliter per minute scale, limiting their ability to evaluate the real-time

Reproducibility in Cytometry: Signals Analysis and its Connection to Uncertainty Quantification

December 22, 2023

Author(s)

Paul Patrone, Matthew DiSalvo, Anthony J. Kearsley, Geoffrey B. McFadden, Gregory A. Cooksey

Serial flow cytometry in an inertial focusing optofluidic microchip for direct assessment of measurement variations

July 20, 2022

Author(s)

Matthew DiSalvo, Paul Patrone, Anthony J. Kearsley, Gregory A. Cooksey

Flow cytometry is an invaluable technology in biomedical research, yet it has limited ability to separate inherent sample variability from measurement

Optofluidic Flow Meter for sub–nanoliter per minute flow measurements

January 31, 2022

Author(s)

Jalal Sadeghi, Paul Patrone, Anthony J. Kearsley, Gregory A. Cooksey

Performance improvements in microfluidic systems depend on accurate measurement and control of fluids on the micro- and nanoscale, and new applications are

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Patents (2018-Present)

Spatio-Temporal Prolifometer And Performing Time-Resolved Spatial Prolifometry For Producing A Uniform Light Profile

NIST Inventors

Paul Patrone , Gregory A Cooksey and Matthew DiSalvo

A spatio-temporal profilometer performs time-resolved spatial profilometry and includes a substrate, a tapered optical collimator waveguide, a fluid channel, and a light-fluid interaction volume. The tapered optical collimator waveguide receives diverging light, internally reflects it, and

Serial Cytometry

NIST Inventors

Gregory A Cooksey , Paul Patrone and Anthony J. Kearsley

Flow cytometers can make thousands of single-cell measurements per second, but the limited ability to quantify uncertainty in individual measurements reduces their effectiveness for characterizing biomarker distributions, discriminating cell populations, and detecting rare events. To facilitate

Multiplexed Amplitude Modulation Fluorometry

NIST Inventors

Anthony J. Kearsley , Gregory A Cooksey and Paul Patrone

Improving accuracy of cytometers is challenging because optical configuration, flow control methods, and calibration issues make it difficult to characterize geometric factors associated with signal collection. State-of-the-art tools only collect a small solid angle of emitted light, so that minor

Optical Flow Meter for Determining a Flow Rate of a Liquid

NIST Inventors

Anthony J. Kearsley , Paul Patrone and Gregory A Cooksey

Optofluidic Flow Meter

NIST Inventors

Zeeshan Ahmed and Gregory A Cooksey

An optofluidic flow meter to determine a rate of fluid flow in a flow member includes: the flow member; a primary fluid conduit disposed in the flow member and that receives a fluid; a secondary fluid conduit disposed in the flow member; and a fiber optic comprising a fiber Bragg grating interposed

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Gregory A Cooksey ()

Member Of

SELECTED PROGRAMS/PROJECTS

Research Opportunities Available

Selected Publications

Publications

Patents (2018-Present)