Image courtesy of the Laboratory for Noninvasive Neuroengineering/Rice University
News • Ultrasound-guided gene therapy
New approach for targeted seizure control without surgery
Rice University bioengineers have demonstrated a nonsurgical way to quiet a seizure-relevant brain circuit in an animal model.
The team used low-intensity focused ultrasound to briefly open the blood-brain barrier (BBB) in the hippocampus, delivered an engineered gene therapy only to that region and later flipped an on-demand “dimmer switch” with an oral drug. The research shows that a one-time, targeted procedure can modulate a specific brain region without impacting off-target areas of the brain.
The researchers published their findings in the journal ACS Chemical Neuroscience.
Image source: Rice University; photo by Jeff Fitlow
“Many neurological diseases are driven by hyperactive cells at a particular location in the brain,” said study lead Jerzy Szablowski, assistant professor of bioengineering and a member of the Rice Neuroengineering Initiative. “Our approach aims the therapy where it is needed and lets you control it when you need it, without surgery and without a permanent implant.”
The work builds on nearly a decade of innovation by Szablowski and his team. The group’s acoustically targeted chemogenetics (ATAC) method merges ultrasound, gene therapy and chemogenetics ⎯ a technique that equips selected neurons with engineered receptors so they can be activated or silenced by a specific drug ⎯ into a single tool that makes possible precise control over brain circuits without surgery.
In the ATAC procedure, researchers first injected microscopic gas-filled bubbles into the bloodstream. When low-intensity ultrasound waves were directed at the hippocampus, the microbubbles oscillated gently against blood vessel walls, creating temporary, nanometer-scale openings in the BBB. These pores were hundreds of times smaller than blood cells ⎯ thus impeding their passage ⎯ but large enough to allow engineered gene delivery vectors developed by the Szablowski lab to enter the targeted brain tissue. The pores closed naturally within hours, leaving the BBB intact.
The engineered vectors carried instructions for building an inhibitory chemogenetic receptor ⎯ a kind of molecular “dimmer switch” that makes neurons responsive to a drug administered later to “quiet” seizure-inducing activity. “By precisely targeting the hippocampus, we can dampen overactivity where it matters and leave the rest of the brain untouched,” said Honghao Li, a bioengineering doctoral student at Rice who is a first author on the study.
The results confirm that ATAC can achieve precise control over target brain circuits using a minimally invasive procedure and a simple systemic drug. Because both focused ultrasound BBB opening and viral vector-based gene delivery are already advancing in clinical studies, the method could accelerate the development of targeted treatments for epilepsy and other neurological disorders.
Images courtesy of the Laboratory for Noninvasive Neuroengineering/Rice University
The hippocampus experiment marks a milestone for Szablowski’s group, which has previously shown how to deliver gene therapies across large brain volumes, small targeted brain regions and even individual neuronal connections. Focused ultrasound can also be used to recover molecular signals from specific brain regions: A related technique of the Szablowski lab known as recovery of markers through insonation, or REMIS, can release engineered or natural proteins from only the insonated region into the bloodstream, allowing researchers to monitor gene activity without invasive investigations. The technique gave rise to a recently funded clinical trial with Texas Medical Center partners, including researchers at Baylor College of Medicine and the University of Texas MD Anderson Cancer Center.
“These technologies complement each other,” Szablowski said. “Ultrasound lets us deliver therapy, control the neurons we want and then measure the effects in the exact circuit we targeted. Our goal is to build a platform that can reach any brain region safely, deliver any genetic payload precisely and let clinicians control it on demand. This kind of versatility could change how we think about developing brain therapies.”
The work highlights a deepening focus at Rice on understanding the brain and improving neurological health ⎯ momentum that now converges in the university’s new Rice Brain Institute, which brings together researchers from across disciplines to address the most complex challenges in brain health.
The research was supported by the G. Harold & Leila Y. Mathers Foundation (MF-2012-01228), Michael J. Fox Foundation for Parkinson’s Disease Research (MJFF-020154), the National Institutes of Health (F30EY037188) and the National Science Foundation (1842494).
Source: Rice University
12.11.2025
