Effective Insertion Of DNA Molecules Into Cells For Gene Therapies

For years, researchers have attempted to harness the full potential of gene therapy, a technique that inserts genes into a patient’s cells to treat aggressive diseases such as cancer. But getting engineered DNA molecules into cells is not an easy task.

J. Mark Meacham, assistant professor of mechanical engineering & materials science at Washington University in St. Louis, leads a team of researchers that has developed a method enabling effective insertion of large molecules — such as DNA, RNA and proteins into cells and propels them into the cell nucleus. By combining a technique known as Acoustic Shear Poration (ASP) with electrophoresis, the approach uses ultrasound waves and focused mechanical force to create nanoscale holes, or pores, in the cell membrane that are big enough for large macromolecules or nanoparticles to pass into the cell’s interior.

Operation of the acoustic shear poration (ASP) device in Meacham’s lab

The researchers wrote that so far, ASP has achieved greater than 75 percent delivery efficiency of macromolecules. DNA insertion, or transfection, which is of most interest in gene therapy, is significantly more challenging. Yet the combined application of mechanical and electrical forces pioneered by Meacham and colleagues yields roughly 100 percent improvement in transfection versus pure mechanoporation. Results of the research are published in Scientific Reports.

Source: https://engineering.wustl.edu/