George Mason University

07/07/2026 | News release | Distributed by Public on 07/08/2026 11:58

George Mason researcher is using CAREER award to build brain-inspired AI that is more adaptive

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Though artificial intelligence (AI) is making extraordinary advances, today's AI systems still have significant limitations. They often require enormous computing power and energy (not to mention well-documented water usage), struggle to adapt when conditions change, and can make decisions in ways that are difficult for humans to interpret, validate, or trust.

Maryam Parsa. Photo provided

Maryam Parsa, assistant professor in George Mason University's Department of Electrical and Computer Engineering, believes those shortcomings point toward a compelling source of inspiration: the human brain.

Parsa received a five-year, $655,000 National Science Foundation Early Career Development (CAREER) Award for developing a new framework for brain-inspired AI. The project seeks to make AI systems more efficient, adaptable, resilient, and transparent by borrowing principles from biological nervous systems.

"AI was originally inspired by the brain," Parsa said. "Concepts such as neurons, synapses, and neural networks drew inspiration from how brains process information. But over time, AI has moved farther away from those biological principles."

Parsa believes researchers now have an opportunity to reconnect AI and neuroscience. "Neuroscience advanced tremendously over the past few decades, with only a small fraction of those discoveries finding their way into AI systems."

As computing power grew, researchers found AI systems could make major gains by scaling neural networks and training them on massive datasets. The approach, fueled by increasingly powerful computers, is leading to significant breakthroughs, particularly with the rise of large language models (LLMs).

"They are producing remarkable devices," she said. "The progress we see in LLMs and modern AI grew out of relatively simple neural-network ideas. Over time, researchers added more layers, more data, more computational power, and more sophisticated training methods, leading to powerful systems."

The goal is not to replace today's successful AI systems with direct copies of the brain. Instead, her research focuses on areas where current AI falls short. "We know some of the key challenges AI still faces," she said. "It can be difficult to understand how these systems reach their decisions, and they do not always transfer well when conditions, data, or environments change. That is where biological intelligence can offer useful design principles."

When today's AI systems encounter unfamiliar environments or changing conditions, they often need to be retrained or fine-tuned. Biological intelligence, however, is remarkably adaptable and energy efficient, offering clues to how future AI systems could learn and respond more flexibly.

Her CAREER project builds a unified framework around three characteristics of biological intelligence. The first pillar, dimensionality, examines how the brain creates meaningful representations of the world rather than simply processing raw information. The second, heterogeneity, explores the brain's remarkable diversity. Rather than relying on identical neurons performing tasks, biological brains contain many neuron types with distinct behaviors. "The brain is not copy, paste, copy, paste, copy, paste," she said.

The third pillar, nonlinearity, draws inspiration from the retina, which performs extensive processing before visual information reaches the brain. "It's not like the raw pixels go directly to our central brain," Parsa said. "The retina digests and processes the information first."

Parsa said the broader idea is combining these principles into a more biologically inspired approach to AI. "If I know how to process my input, create a better representation of my environment, and leverage this massive heterogeneity, then I can move AI a little closer to the way biological intelligence works," she said.

Beyond advancing AI research, the project includes an educational effort to help students see how ideas from the brain can shape the future of computing and artificial intelligence. Parsa plans to bring these concepts into graduate courses, hands-on hackathons, and STEM outreach activities for K-12 students, creating new pathways for students to explore the intersection of neuroscience, engineering, and AI.

George Mason University published this content on July 07, 2026, and is solely responsible for the information contained herein. Distributed via Public Technologies (PUBT), unedited and unaltered, on July 08, 2026 at 17:58 UTC. If you believe the information included in the content is inaccurate or outdated and requires editing or removal, please contact us at [email protected]