How Living Neural Chips Could Power AI
For decades, AI has run on silicon鈥揳 given that few have questioned or tried to challenge. However, one startup believes the future of computing might be grown in a dish…
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For decades, AI has run on silicon鈥揳 given that few have questioned or tried to challenge. However, one startup believes the might be grown in a dish and not manufactured in a lab. And if they鈥檙e correct, their technology may hold the answer to how we scale AI technology sustainably鈥搘ithout constantly running the risk of decimating the global power grid.
Last month, , a Baltimore-born startup, emerged from stealth with a bold announcement: its Bionode platform鈥攁 computing system that integrates lab-grown neurons with traditional processors鈥攊s already powering AI tasks like computer vision and large language model (LLM) acceleration. The company aims to remove our long-standing, global dependence on silicon by offering a more adaptive, energy-efficient alternative to the GPU-dominated status quo.
鈥淭丑别 biological has evolved over hundreds of millions of years into the most efficient computing system ever created,鈥 said Alex Ksendzovsky, BBB鈥檚 co-founder and CEO. 鈥淣ow we can start to use it for 颈苍迟别濒濒颈驳别苍肠别.鈥
A Living Co-Processor for AI
BBB鈥檚 platform uses neurons grown from human and rat-derived tissue, cultivated in a lab and placed atop a microelectrode array with 4,096 contact points. 鈥淲e have multiple models that we use,鈥 said Ksendzovsky. 鈥淥ne of those models is from rat cells. One of those models is from actual human stem cells converted into neurons.鈥
Each array contains 鈥渉undreds of thousands of them,鈥 he said鈥攏eurons that can rewire themselves in response to inputs. BBB believes this self-organizing behavior could radically improve AI training and inference.
鈥淲e鈥檝e built a closed-loop system that allows neurons to rewire themselves, increasing efficiency and accuracy for AI tasks,鈥 Ksendzovsky said.
And for those wary of the idea of using live cells, BBB鈥檚 current chip model doesn鈥檛 require a full-scale brain. 鈥淲e don鈥檛 need millions of neurons to process the entire environment like a brain does,鈥 Ksendzovsky said. 鈥淲e use only what鈥檚 necessary for specific tasks, keeping ethical considerations in mind.鈥
Applications in Vision and Language
The company isn鈥檛 just theorizing. Its Bionode chips have already been deployed in two foundational AI domains: vision and language.
鈥淲e鈥檙e already applying biological computing to computer vision,鈥 said Ksendzovsky. 鈥淲e can encode images into a biological network, let neurons process them, and then decode the neural response to improve classification accuracy.鈥
In addition to computer vision, BBB is also using its system to accelerate large language model (LLM) training鈥攁n area notorious for its high computing and energy demands. 鈥淥ne of our biggest breakthroughs is using biological networks to train LLMs more efficiently, reducing the massive energy consumption required today,鈥 he said.
Strategizing Sustainability with Nvidia
While BBB鈥檚 ambitions may seem completely disruptive at first glance, the company is positioning itself as a complement鈥攏ot a competitor鈥攖o current AI hardware leaders. It is currently a member of Nvidia鈥檚 Inception incubator, which adds credibility and nuance to the company鈥檚 strategic vision.
鈥淲e don鈥檛 see ourselves as direct competitors to Nvidia, at least not in the near future,鈥 Ksendzovsky noted. 鈥淏iological computing and silicon computing will coexist. We still need GPUs and CPUs to process the data coming from neurons.鈥
He added, 鈥淲e can use our biological networks to augment and improve silicon-based AI models, making them more accurate and more energy-efficient.鈥
Moving Toward a Modular AI Future
Ksendzovsky believes that as AI workloads diversify, the hardware will need to become more modular鈥攁nd biology will be part of that toolkit.
鈥淭丑别 silicon, biological computing, and quantum computing each play a role based on their strengths,鈥 he said.
BBB is focused on carving out a unique niche in the AI hardware landscape. Although its systems aren鈥檛 intended to replace GPUs entirely today, they offer a new class of computing that addresses some of the most urgent bottlenecks in AI: energy usage, retraining costs, and efficient, real-time learning.
To build a future where AI can harmoniously exist alongside the natural planet, it may not come down to how we build chips but how we grow them.
Featured Image Credit: Photo by Athena Sandrini;
The post appeared first on .
For decades, AI has run on silicon鈥揳 given that few have questioned or tried to challenge. However, one startup believes the might be grown in a dish and not manufactured in a lab. And if they鈥檙e correct, their technology may hold the answer to how we scale AI technology sustainably鈥搘ithout constantly running the risk of decimating the global power grid.
Last month, , a Baltimore-born startup, emerged from stealth with a bold announcement: its Bionode platform鈥攁 computing system that integrates lab-grown neurons with traditional processors鈥攊s already powering AI tasks like computer vision and large language model (LLM) acceleration. The company aims to remove our long-standing, global dependence on silicon by offering a more adaptive, energy-efficient alternative to the GPU-dominated status quo.
鈥淭丑别 biological has evolved over hundreds of millions of years into the most efficient computing system ever created,鈥 said Alex Ksendzovsky, BBB鈥檚 co-founder and CEO. 鈥淣ow we can start to use it for 颈苍迟别濒濒颈驳别苍肠别.鈥
