The ability to analyze the properties of individual cells is vital to broad areas of life science applications, from diagnosing diseases and developing better therapeutics to characterizing pathogenic bacteria and developing cells for bioproduction applications.
However, the accurate analysis of individual cells is a challenge, especially when it comes to a cell’s biophysical properties, due to large property variations among cells even in the same cell population as well as the presence of rare cell types within a larger population.
Addressing this need, Arum Han, Texas Instruments Professor II in the Department of Electrical and Computer Engineering at Texas A&M University, together with his graduate students and postdoctoral researchers, has developed a new technology that can accurately analyze cell properties through the use of a single-cell electrorotation microfluidic device, which utilizes an electric field to probe the cell’s properties.
The technology works by using an electric field to first capture a single cell in a microfluidic device, followed by applying a rotating electric field to rotate the trapped single cell and then measuring the speed of rotation. By knowing the input electric field parameters and analyzing the rotation speed, accurately analyzing the dielectric properties of a single cell becomes possible.
“By knowing how much force was applied and how fast the cell turns, you can extract many basic biophysical properties of cells,” Han said.
There have been previous efforts to accomplish this, but this technology is the most accurate in measuring these properties because of its capability to apply a high-frequency electric field (up to 100 megahertz) and its use of an eight-electrode-pair design to simultaneously trap a single cell and apply rotational force to the trapped cell.
The research team’s findings are featured on the cover of the June 2022 issue of the journal Biomedical Microdevices.
This technology has been fully developed and applied to several different cell analysis applications. Having successfully demonstrated that analysis can be accurately completed on one cell at a time, Yuwen Li, graduate student in Han’s lab and the lead author of the work, is now leading the effort to further develop the technology so that this can be executed at a much higher speed and against many cells simultaneously.
Other contributors to this research are postdoctoral researcher Can Huang and research scientist Songi Han from the electrical and computer engineering department.
This project was funded through a cooperative agreement with the U.S. Army Combat Capabilities Development Command Army Research Laboratory, facilitated through the Texas A&M Engineering Experiment Station.
This article by Rachel Rose originally appeared on the College of Engineering website.
Humans and robots are working closer than ever before. Texas A&M researchers are using brain imaging to investigate how these interactions can impact human trust in robots during manufacturing tasks.
Researchers are using photodynamic therapy to break the dangerous cycle of fighting increasingly resistant bacteria with increasingly stronger antibiotics.
Using NASA satellite images and large-scale models, they tracked the same dust plumes from Africa to Houston.
More than 60% of Puerto Ricans seeking FEMA aid after Hurricane Maria had their applications denied – will the agency approve more this time?
The funds will allow the center to continue research on climate change and health.
It’s unlikely that the brightly-colored pills will turn up among Halloween candy this year. But a Texas A&M clinical professor says fentanyl exposure is still a concern to be taken seriously.
Subscribe to the Texas A&M Today newsletter for the latest news and stories every week.