Biodesign Institute's new facility arranged to encourage collaboration between disciplines as researchers work to solve tough problems
The mission of the Biodesign Institute at Arizona State University started with the desire to replicate a single blade of grass.
That’s what President Michael Crow told a crowd of about 450 researchers, faculty, staff, students, city and state education officials, and members of the public gathered Monday to celebrate the opening of Biodesign C, the third of four facilities planned to accommodate the institute’s cutting-edge research efforts.
Crow referred to the accomplished American inventor Thomas Edison’s notion that the answers to mankind’s ills lie in nature: “Until man duplicates a blade of grass, nature can laugh at his so-called scientific knowledge. Remedies from chemicals will never stand in favorable comparison with the products of nature, the living cell of the plant, the final result of the rays of the sun, the mother of all life.”
“The idea for the Biodesign Institute was basically, could you gather scientists, engineers, dreamers, thinkers, ambitious individuals … (and) find a way to … replicate the simplicity and the beauty and the elegance of the work of a single blade of grass,” Crow said, because the second you can understand how to replicate that blade — or the body’s immune system, for instance — you can create real, lasting solutions to health challenges, environmental challenges, energy challenges, national security challenges and more.
Video by Jordan Currier/ASU
The new five-story, 191,000-plus-square-foot building gives scientists even more space to realize those visions, with high-quality wet lab space for chemistry, engineering and the biological sciences arranged in a “neighborhood”-style open layout that encourages collaboration.
“It’s meant to cause scientists to collide with each other, and that’s important because it is in individuals colliding with each other that new ideas emerge,” said Joshua LaBaer, the Biodesign Institute's executive director.
The $120 million project was planned with nature in mind. Funding for construction came from “green bonds” that promote environmental sustainability. Copper screens on the exterior help regulate temperature to save energy, and wastewater will be collected to further research into the development of a university-wide reusable wastewater system.
“Stone-age thinkers think that digging things out of the ground, lighting them on fire, polluting the atmosphere and boiling water to produce movement of machines to produce electric signals is somehow an advanced form of human existence,” Crow said.
“It’s not an advanced form of human existence. It’s one step past a campfire. So now we live in a world with billions of these campfires burning, and burning, and burning … when all around us nature operates in a completely different realm.”
Biodesign C can house up to 80 lead researchers and 400 support staff, bringing the institute’s total workforce to 800 strong, and is already home to the ASU-Banner Neurodegenerative Disease Research Center (NDRC), the Biodesign Center for Applied Structural Discovery, the Biodesign Center for Mechanisms of Evolution and several labs from ASU’s School of Molecular Sciences.
Visitors at Monday’s grand opening were invited to tour the space, where they were able to view a roughly 7-foot-long 3D model of the world’s first compact X-ray free-electron laser (CXFEL) — a key drug discovery and bioenergy research tool — and step inside the vault where it will be located in the basement of Biodesign C.
The CXFEL is a highly sensitive piece of equipment that allows scientists to peer deep inside proteins to better understand the action of molecules critical to cancer and other devastating diseases, and also how plants convert sunlight into renewable energy. It requires a controlled environment to ensure accuracy.
Video by Knowledge Enterprise Development
The vault, a true feat of construction engineering, is complete with vibration-proof flooring, to minimize interference from passing light-rail trains, and a 4-foot-thick, 36,000-pound lead-shielded door to reduce magnetic fields in building materials and contain the energy from the laser beam.
Currently, there are only four XFEL facilities worldwide, resulting in a traffic jam of scientific demand that is slowing down potential research. ASU’s CXFEL will be about 100 times smaller and cheaper than a typical XFEL, and it is expected to relieve the gridlock and attract leading scientists from around the world.
Up on the fifth floor, visitors were able to observe a real human brain in the area that will belong to the ASU-Banner Neurodegenerative Disease Research Center, an interdisciplinary collaborative of researchers poised to become one of the world’s largest teams of translationalTranslational refers to research whose findings can be translated from basic science to enhance human health and well-being through medical practices. neuroscientists in the fight against Alzheimer’s, Parkinson’s and other neurodegenerative diseases.
The NDRC, established in 2017, is notable for its intentional leveraging of expertise from several areas — including brain imaging, genomics and data analyses — which has helped put Arizona on the map as a destination for leading neuroscience researchers.
The decision to locate the center on ASU’s Tempe campus was influenced largely by the plethora of resources available to researchers here, including the state-of-the-art physical space itself, as well as an abundance of students eager to contribute to impactful research.
“I could not be more grateful to President Crow and his ASU colleagues for their extraordinary commitment,” said Eric Reiman, a university professor of neuroscience at ASU and chief executive officer at Banner Research. He views the breadth of skill within the center as instrumental in the discovery of better treatment options.
“Ninety-nine-point-eight percent of Alzheimer’s treatments found in the last 12 years that have been discovered through traditional research mechanisms have failed to work,” he said. “We’re emphasizing a strategy that fosters close working relationships between researchers who study human beings with and without these disorders, along with experimental researchers who use cellular or small animal models.”
And they’re already making headway. For instance, Assistant Research Professor Ben Readhead and his colleagues used donated brain data to conduct the most rigorous study to date on the viral contribution to Alzheimer’s, and Associate Professor Salvatore Oddo and his colleagues conducted a groundbreaking study to implicate a mechanism to account for brain cell death in a genetically engineered mouse model of Alzheimer’s.