Skip To Main Content
Graduate student working on Dell laptop

Explore degrees available through the No. 1 online graduate program in Texas. Study online to earn the same quality degree as on campus.

Two students working on equations on a white board with eligible text on it

Get information on the application process and funding opportunities for undergraduate, graduate and transfer students.

Ingenium blogger posing with fellow organization leaders with Aggie ring
Ingenium Our blog by students, for students

Get inspired by experiences and opportunities shared by fellow engineering students.

Students with thumbs up holding Future Aggie Engineers and Engineering Texas A&M University signs
PK-12 Outreach Spark!

Students and organizations can bring hands-on activities or design challenges to your location or just visit as guest speakers.

Dr. Vladislav Yakovlev headshot
A recent paper published by Dr. Vladislav Yakovlev and a multidisciplinary research team has been recognized with the Editor's Pick distinction. The research focuses on how electrical and optical pulses can impact cell absorption of materials, including vaccines like COVID-19. | Image: Texas A&M Engineering

Dr. Vladislav Yakovlev, professor in the Department of Biomedical Engineering at Texas A&M University, is part of a multiuniversity team researching how electrical and optical pulses can benefit cell absorption of materials, including vaccines.

The team investigated the optical and electrical breakdown of materials. Those effects, which describe material modification in the presence of extreme optical or electrical fields, have been studied since the 1950s. However, the simultaneous application of optical and electrical fields, especially to biologically relevant systems, hasn’t been explored before. Yakovlev said by investigating the synergistic action of electrical and optical pulses, they were able to promote highly localized breakdown while reducing the threshold for such breakdown. 

The newly discovered synergistic effect is particularly important if there is a need to selectively disrupt cellular membrane in a highly localized manner. Typically, electroporation, a technique that applies an electrical field to cells to increase the permeability of the cell membrane, is used. Alternatively, an optoporation, which uses ultrashort laser pulses to form a small hole in the cell membrane, can be employed. A powerful combination of electroporation and optoporation can provide the benefits of both approaches, leading to new ways drugs and vaccines can be delivered to cells and tissues.

“One of the impacts of paramount significance of this effect, which can be of great interest to a general audience, is improved accuracy of vaccine delivery for COVID-19,” the team said in an impact statement.

The team recently published a paper in the journal Photonics Research where it was selected as Editors' Pick. The research is funded by the Air Force Office of Scientific Research, with Dr. Sofi Bin-Salamon serving as project manager. Salamon facilitated the collaboration between the three different research teams involved in this project.

While this technology would be a new addition to a laboratory, the research team noted that creating the effect doesn’t require sophisticated equipment, allowing it to be used in a broad range of facilities.

“We believe that a unique combination of a new fundamental science and a broad range of high-impact applications. ranging from extreme light-matter interactions to nano- and biotechnology, would be of great interest for a broad audience,” Yakovlev said.