Johns Hopkins engineers and cardiology experts have teamed up to develop a fingernail-sized biosensor that could alert doctors when serious brain injury occurs during heart surgery. By doing so, the device could help doctors devise new ways to minimize brain damage or begin treatment more quickly.
In an issue of the journal Chemical Science, the team reported on lab tests demonstrating that the prototype sensor had successfully detected a protein associated with brain injuries.
“Ideally, the testing would happen while the surgery is going on, by placing just a drop of the patient’s blood on the sensor, which could activate a sound, light or numeric display if the protein is present,” said the study’s senior author, Howard Katz, a Whiting School of Engineering expert in organic thin film transistors, which form the basis of the biosensor.
The project originated about two years ago when Katz, who chairs the Department of Materials Science and Engineering, was contacted by Allen Everett, a Johns Hopkins Children’s Center pediatric cardiologist who studies biomarkers linked to pulmonary hypertension and brain injury. As brain injury can occur with heart surgery in both adults and children, the biosensor Everett proposed should work on patients of all ages. He is particularly concerned, however, about operating room injuries to children, whose brains are still developing.
“Many of our young patients need one or more heart surgeries to correct congenital heart defects, and the first of these procedures often occurs at birth,” Everett said. “We take care of these children through adulthood, and we have all have seen the neurodevelopment problems that occur as a consequence of their surgery and post-operative care. These are very sick children, and we have done a brilliant job of improving overall survival from congenital heart surgery, but we have far to go to improve the long-term outcomes of our patients. This is our biggest challenge for the 21st century.”
He said that recent studies found that after heart surgery, about 40 percent of infant patients will have brain abnormalities that show up in MRI scans. The damage is most often caused by strokes, which can be triggered and made worse by multiple events during surgery and recovery, when the brain is most susceptible to injury. These brain injuries can lead to deficiencies in the child’s mental development and motor skills, as well as hyperactivity and speech delay.
To address these problems, Everett sought an engineer to design a biosensor that responds to glial fibrillary acidic protein (GFAP), which is a biomarker linked to brain injuries. “If we can be alerted when the injury is occurring,” he said, “then we should be able to develop better therapies. We could improve our control of blood pressure or redesign our cardiopulmonary bypass machines. We could learn how to optimize cooling and rewarming procedures and have a benchmark for developing and testing new protective medications.”
At present, Everett said, doctors have to wait years for some brain injury-related symptoms to appear. That slows down the process of finding out whether new procedures or treatments to reduce brain injuries are effective. The new device may change that. “The sensor platform is very rapid,” Everett said. “It’s practically instantaneous.”
To create this sensor, materials scientist Katz turned to an organic thin film transistor design. In recent years sensors built on such platforms have shown that they can detect gases and chemicals associated with explosives. These transistors were an attractive choice for Everett’s request because of their potential low cost, low power consumption, biocompatibility and their ability to detect a variety of biomolecules in real time. Futhermore, the architecture of these transistors could accommodate a wide variety of other useful electronic materials.
The sensing area is a small square, 3/8ths-of-an-inch on each side. On the surface of the sensor is a layer of antibodies that attract GFAP, the target protein. When this occurs, it changes the physics of other material layers within the sensor, altering the amount of electrical current that is passing through the device. These electrical changes can be monitored, enabling the user to know when GFAP is present.
“This sensor proved to be extremely sensitive,” Katz said. “It recognized GFAP even when there were many other protein molecules nearby. As far as we’ve been able to determine, this is the most sensitive protein detector based on organic thin film transistors.”
Through the Johns Hopkins Technology Transfer Office, the team members have filed for full patent protection for the new biosensor. Katz said the team is looking for industry collaborators to conduct further research and development of the device, which has not yet been tested on human patients. But with the right level of effort and support, Katz believes the device could be put into clinical use within five years. “I’m getting tremendous personal satisfaction from working on a major medical project that could help patients,” he said.
Everett, the pediatric cardiologist, said the biosensor could eventually be used outside of the operating room to quickly detect brain injuries among athletes and accident victims. “It could evolve into a point-of-care or point-of-injury device,” he said. “It might also be very useful in hospital emergency departments to screen patients for brain injuries.”
The lead author of the Chemical Science paper was Weiguo Huang, a postdoctoral fellow in Katz’s lab. Along with Everett and Katz, the co-authors, all from the Whiting School of Engineering and the School of Medicine, were Kalpana Besar, Rachel LeCover, Pratima Dulloor, Jasmine Sinha, Josue Martinez Hardigree, Christian Pick, Julia Swavola, Joelle Frechette and Michael Bevan.
Funding for the sensing project was provided by the Cove Point Foundation and the Johns Hopkins Environment, Energy, Sustainability and Health Institute. Fundamental materials characterization was funded by the U.S. Department of Engery.
Source: Johns Hopkins University