Pitt researchers receive $550,000 NSF CAREER award to develop new brain-computer therapy method for people with autism

Bioengineering, Electrical & Computer

PITTSBURGH (March 21, 2019) … Autism was first described by U.S. researchers more than 70 years ago, and today the Centers for Disease Control and Prevention (CDC) estimates that 1 in 59 children are identified with autism spectrum disorder (ASD), affecting more than 3.5 million Americans. Although clinical techniques are used to help patients with ASD respond to stress and other factors, none are known to couple with technology that could monitor brain response in real time and provide the patient with feedback. However, thanks to a $550,000 award from the National Science Foundation, engineers at the University of Pittsburgh and clinicians at the UPMC Western Psychiatric Hospital, a new intervention using electroencephalography (EEG)-guided, non-invasive brain-computer interface (BCI) technology could complement clinical treatments and improve emotion regulation in people with ASD. The multidisciplinary team includes Murat Akcakaya, PhD, assistant professor of electrical and computer engineering at Pitt’s Swanson School of Engineering, and Carla A. Mazefsky, PhD, associate professor of psychiatry and psychology in Pitt’s Department of Psychiatry. The proposal is funded through an NSF CAREER award, which supports early-career faculty who have the potential to serve as academic role models in research and education and to lead advances in the mission of their department or organization.“People on the autism spectrum today have access to effective clinical strategies or technologies, but none are coupled effectively to provide real-time feedback in real-life activities. This limits reinforcement techniques that the patient can utilize on his or her own, without the need for a clinical appointment,” Dr. Akcakaya explained. “However, by utilizing EEG to couple clinical techniques with BCI technologies, we can develop a closed-loop system that will help patients better learn how to recognize emotional triggers and respond with appropriate techniques generalizing the effects of clinical treatment strategies to real-life activities.” Akcakaya and Mazefsky will develop social interaction scenarios in virtual environments while recording EEG responses simultaneously in order to detect patterns that represent changes in distress levels. The virtual scenario will then present audio or visual cues to help remind them how to handle stress. The project will also develop new machine learning algorithms and neuroscience methods to identify EEG features associated with emotion regulation to classify between distress and non-distress conditions, and to distinguish among different distress levels.The two will also investigate the promise of these EEG and virtual reality approaches within the context of Mazefsky’s randomized controlled clinical trial funded by the US Department of Defense. The clinical trial is testing the efficacy of an intervention Mazefsky and colleagues developed, called the Emotion Awareness and Skills Enhancement (EASE) program, in 12- to 21-year-old verbal youth with ASD. “EASE emphasizes awareness of one’s own emotional responses as a foundational skill that promotes the ability to manage intense negative emotions, which is taught through mindful awareness,” Mazefsky explained. “By coupling the clinical strategies we teach in EASE with technological interventions, we believe we can enhance patients’ ability to distinguish different distress levels and therefore potentially reap even greater (and more generalized) benefit.”The CAREER award will also enable Akcakaya to develop courses related to the research and outreach activities to promote STEM and ASD research to K-12 populations and the broader public. Outreach will focus especially on individuals with ASD, their families, and caretakers.  “Early diagnosis and intervention can help patients with ASD and their families improve quality of life, and so providing clinicians with a new tool that both enhances and reinforces what patients learn is critical to closing the loop between triggers and responses,” Akcakaya said. “Additionally machine learning based on biological responses could also be integrated in to the existing technologically driven intervention techniques targeting patients across the autism spectrum.  Eventually, the technology could be incorporated in an accessory like a smart watch or glasses, enhancing patient privacy and building confidence.” ###

Pennsylvania's Climate Moment

Electrical & Computer, MEMS, Nuclear

Forty-two percent of Pennsylvania’s electricity is generated by nuclear plants, but that percentage may decline as a result of the announced closure of two of Pennsylvania’s five nuclear plants in 2019 and 2021, respectively. To explore what impact those closures will have on the Commonwealth's energy portfolio, as well as on decarbonization plans, the University of Pittsburgh's Center for Energy will host a special forum, "Pennsylvania's Climate Moment," on Friday, March 8 from 11:00am - 12:30 pm in Posvar 3911. Heng Ban, PhDR.K. Mellon Professor in Energy, Professor of Mechanical Engineering and Materials Science, and Director of the Stephen R. Tritch Nuclear Engineering ProgramUniversity of Pittsburgh Swanson School of Engineering Hillary BrightDirector, State Policies Blue Green Alliance Sam RessinFormer PresidentUniversity of Pittsburgh Climate Stewardship Society Kathleen RobertsonSenior Manager of Environmental Policy and Wholesale Market DevelopmentExelon John WalliserSenior Vice-President, Legal AffairsPennsylvania Environmental Council For more information, contact the Center for Energy at 412-624-7476 or centerforenergy@engr.pitt.edu.

Lights, Camera, Action: Pitt iGEM team captures silver medal for their “Molecular Movie Camera”

Bioengineering, Electrical & Computer, Student Profiles

PITTSBURGH (January 29, 2019) … The ability to measure and record molecular signals in a cell can help researchers better understand its behavior, but current systems are limited and provide only a “snapshot” of the environment rather than a more informative timeline of cellular events. In an effort to give researchers a complete understanding of event order, a team of University of Pittsburgh undergraduate students prototyped a frame-by-frame “video” recording device using bacteria. The group created this project for the 2018 International Genetically Engineered Machine (iGEM) competition, an annual synthetic biology research competition in which over 300 teams from around the world design and carry out projects to solve an open research or societal problem. The Pitt undergraduate group received a silver medal for their device titled “CUTSCENE.” The iGEM team included two Swanson School of Engineering students: Evan Becker, a junior electrical engineering student, and Vivian Hu, a junior bioengineering student. Other team members included Matthew Greenwald, a senior microbiology student; Tucker Pavelek, a junior molecular biology and physics student; Libby Pinto, a sophomore microbiology and political science student; and Zemeng Wei, a senior chemistry student. CUTSCENE aims to show a “video” of cellular activity by recording events in the cell using modified CRISPR/Cas9 technology. Hu said, “By knowing what time molecular events are happening inside of a cell, we are able to better understand a cell's history and how it responds to external stimuli.” Their system improved upon older methods that could only record the levels of stimuli at a single point in time. They used a movie analogy to illustrate their objective. “Try guessing the plot of a movie by looking at the poster; you can get an idea of what is going on, but to really understand the story, you need to watch the film,” said Becker. “Unless researchers are taking many snapshots of the cellular activity over time, the image doesn’t give any sense of causality. You can see that the molecule is there, but you don't know where it has been or where it is going.” For their project, the iGEM team used modified CRISPR/Cas9 technology called a base editor. The CRISPR/Cas9 system contains two key components: a guideRNA (gRNA) that matches a specific sequence of DNA and a Cas9 protein that makes a cut at the specific sequence, ultimately leading to the insertion or deletion of base pairs - the building blocks of DNA. In addition to these components, a CRISPR/Cas9 base editor contains an enzyme called cytidine deaminase that is able to make a known single nucleotide mutation at a desired location of DNA. “We achieved a method of true chronological event recording by introducing recording plasmids with repeating units of DNA and multiple gRNA to direct our base editor construct,” said Hu. “This technique will provide an understanding of the order in which molecules and proteins appear in systems.” “A recording plasmid can be thought of as a roll of unexposed film, with each frame being an identical sequence of DNA,” explained Wei. “A single-guideRNA (sgRNA) directs the CRISPR/Cas9 base editor to move along the recording plasmid, making mutations at a timed rate and constantly shifting which frame is in front of our base editor. Activated by the presence of a stimulus, another sgRNA can mark the current frame.” The iGEM team’s approach to this technology will allow them to figure out which molecules are abundant at specific times and perhaps reveal hidden, causal relationships. The information gathered from the device has many potential applications and may allow researchers to develop medicines and therapies based on the timing of the cellular malfunction. “The team did a tremendous amount of lab work over the summer, implementing the cellular event recording methodology,” said Alex Deiters, a professor of chemistry at Pitt who helped advise the iGEM team. “Most importantly, the students developed this clever idea on their own by first identifying a current technology gap and then applying modern gene editing machinery to it. The silver medal is well-deserved!” In addition to Dr. Deiters, the 2018 Pitt iGEM team was advised by Dr. Jason Lohmueller, American Cancer Society Postdoctoral Fellow in the Department of Immunology; Dr. Natasa Miskov-Zivanov, Assistant Professor of Electrical and Computer Engineering, Bioengineering, and Computational and Systems Biology; Dr. Sanjeev Shroff, Distinguished Professor and Gerald E. McGinnis Chair of Bioengineering; and Dr. Cheryl Telmer, a Research Biologist at Carnegie Mellon University. Funding for the 2018 Pitt iGEM effort was provided by the University of Pittsburgh (Office of the Senior Vice Chancellor for Research, Honors College, Kenneth P. Dietrich School of Arts and Sciences, Department of Biological Sciences, Department of Chemistry, Swanson School of Engineering, Department of Bioengineering, and Department of Electrical & Computer Engineering), New England Biolabs (NEB), and Integrated DNA Technologies (IDT). ###