The power of collaboration

Vital Signs » Winter 2015
NEC Building
NEC Building
NEC Building

Wright State University’s dazzling new Neuroscience Engineering Collaboration Building a research powerhouse

Wright State University’s spectacular new Neuroscience Engineering Collaboration (NEC) Building promises to spawn pioneering research and medical breakthroughs by housing the collective brainpower of almost 30 top neuroscientists, engineers, and clinicians, and their teams.

The four-story, L-shaped structure features two wings—one for neuroscience and one for engineering—that flank a central atrium. The building is honeycombed with laboratories and includes offices, conference rooms, and a 105-seat auditorium for research symposiums.

“It is one impressive building,” said Robert Fyffe, Ph.D., vice president for research and dean of the Graduate School. “It represents a transformational moment for the university’s research enterprise, the community, and its partners.”

The building is the first of its kind to be intentionally designed to drive research interaction across disciplines, bringing 30 researchers from six disciplines under one roof to understand brain, spinal cord, and nerve disorders and develop treatments and devices.

Architectural features include chilled ceiling beams that provide a natural, energy-efficient convection air current, an anti-vibration floor that preserves the clarity of sensitive lasers and microscopes, and a dust-free sensors lab that is free of the tiniest speck.

NEC Building glass fins

The Neuroscience Engineering Collaboration Building’s facade is clad with hundreds of glass “fins” that provide shading and reduce heat buildup on sunny days.

About 70 percent of the facade is glass, enabling natural light to stream into the building and create an airy work environment. In the building’s atrium is a dazzling art installation with 3-D asterisks that mimic the firing of the brain’s neurons.

The building is designed to foster research projects that break new ground in treating brain, spinal cord, and nerve disorders by putting neuroscientists, engineers, and clinicians under the same roof and creating an environment that enables them to collaborate and feed off of each other’s ideas and skills.

It houses basic researchers working to understand biological processes, clinical researchers who use that knowledge to develop treatments and cures, and engineers who create medical devices and imaging technologies.

The NEC Building has already become the new home for pioneering research.

For example, Wright State neuroengineer Sherif M. Elbasiouny, Ph.D., has a three-year, $433,000 research grant from the Defense Advanced Research Projects Agency to try to make upper limb prostheses feel and function like natural limbs.

“Our lab being one of neuroscience and engineering is exactly the multidisciplinary nature of what the NEC Building is all about,” said Elbasiouny. “The space we’re receiving will allow us to do more work. The impact is going to be huge on the research.”

The building also houses sophisticated technologies such as an $800,000 PET/CT scanner, which marries positron emission tomography with computed tomography.

Wright State is one of only a few universities that have this body-scanning technology, which is at the forefront of medical diagnosing. It holds out the promise of helping find causes and treatments for cancer and neurological diseases such as epilepsy.

“It just opens up a whole world of opportunities we didn’t have before,” said assistant engineering professor Nasser Kashou, Ph.D.

Kashou said the scanner will be instrumental in training engineering students, strengthening research proposals and increasing their chances of being funded, and creating opportunities for Wright State researchers to collaborate with those at other universities.

The NEC Building also features a special bullpen for graduate and undergraduate student researchers, such as Adam Deardorff and Emily Diller.

Deardorff is an M.D./Ph.D. student studying the nervous system to learn how people develop coordinated, purposeful movement and make small movement corrections. Diller is a biomedical engineering graduate student studying how tiny vibrations can improve a person’s fine-motor skills.

“The work that goes on in this building will truly be cutting edge,” said Fyffe, “maybe even science fiction in its nature.”


Last edited on 02/16/2016.