A mushroom-powered robot. Credit: Cornell University

Biohybrid Bots Are Mushrooming

Kim Bellard
5 min readSep 2, 2024

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I hadn’t expected to write about a biology-related topic anytime soon after doing so last week, but, gosh darn it, then I saw a press release from Cornell about biohybrid robots — powered by fungi! They had me at “biohybrid.”

The release talks about a new paper — Sensorimotor Control of Robots Mediated by Electrophysiological Measurements of Fungal Mycelia — from the Cornell’s Organic Robotics Lab, led by Professor Rob Shepherd. As the release describes the work:

By harnessing mycelia’s innate electrical signals, the researchers discovered a new way of controlling “biohybrid” robots that can potentially react to their environment better than their purely synthetic counterparts.

Or, in the researchers’ own words:

The paper highlights two key innovations: first, a vibration- and electromagnetic interference–shielded mycelium electrical interface that allows for stable, long-term electrophysiological bioelectric recordings during untethered, mobile operation; second, a control architecture for robots inspired by neural central pattern generators, incorporating rhythmic patterns of positive and negative spikes from the living mycelia.

Let’s simplify that: “This paper is the first of many that will use the fungal kingdom to provide environmental sensing and command signals to robots to improve their levels of autonomy,” Professor Shepherd said. “By growing mycelium into the electronics of a robot, we were able to allow the biohybrid machine to sense and respond to the environment.”

Lead author Anand Mishra, a research associate in the lab, explained: “If you think about a synthetic system — let’s say, any passive sensor — we just use it for one purpose. But living systems respond to touch, they respond to light, they respond to heat, they respond to even some unknowns, like signals. That’s why we think, OK, if you wanted to build future robots, how can they work in an unexpected environment? We can leverage these living systems, and any unknown input comes in, the robot will respond to that.”

The team build two robots: a soft one shaped like a spider, and a wheeled one. The researchers first used the natural spike in the mycelia to make them walk and roll, respectively, using the natural signals from the mycelia. Then researchers exposed them to ultraviolet light, which caused the mycelia to react and changed the robots’ gaits. Finally, the researchers were able to override the mycelia signals entirely.

“This kind of project is not just about controlling a robot,” Dr. Mishra said. “It is also about creating a true connection with the living system. Because once you hear the signal, you also understand what’s going on. Maybe that signal is coming from some kind of stresses. So you’re seeing the physical response, because those signals we can’t visualize, but the robot is making a visualization.”

Dr. Shepherd believes that instead of using light as the signal, they will use chemical signals. For example: “The potential for future robots could be to sense soil chemistry in row crops and decide when to add more fertilizer, for example, perhaps mitigating downstream effects of agriculture like harmful algal blooms.”

It turns out that biohybrid robots in general and fungal computing in particular are a thing. In last week’s article I quoted Professor Andrew Adamatzky, of the University of the West of England about his preference for fungal computing. He not only is the Professor in Unconventional Computing there, and is the founder and Editor-in-Chief of the International Journal for Unconventional Computing, but also literally wrote the book about fungal computing. He’s been working on fungal computing since 2018 (and before that on slime mold computing).

Professor Adamatzky notes that fungi have a wide array of sensory inputs: “They sense light, chemicals, gases, gravity, and electric fields,” which opens the door to a wide variety of inputs (and outputs). Accordingly, Ugnius Bajarunas, a member of Professor Adamatzy’s team, told an audience last year: “Our goal is real-time dialog between natural and artificial systems.”

With fungal computing, TechHQ predicts: “The future of computing could turn out to be one where we care for our devices in a way that’s closer to looking after a houseplant than it is to plugging in and switching on a laptop.”

But how would we reboot them?

There are some who feel that we’re making progress on biohybrid robotics faster than we’re thinking about the ethics of it. A paper earlier this summer — Ethics and responsibility in biohybrid robotics researchurged that we quickly develop and ethical framework, and potentially regulation.

The authors state: “While the ethical dilemmas associated with biohybrid robotics resonate with challenges seen in fields like biomedicine, conventional robotics, or artificial intelligence, the unique amalgamation of living and nonliving components in biohybrid robots, also called biorobots, breeds its own set of ethical complexities that warrant a tailored investigation.”

Co-lead author Dr. Rafael Mestre, from the University of Southampton, said: “But unlike purely mechanical or digital technologies, bio-hybrid robots blend biological and synthetic components in unprecedented ways. This presents unique possible benefits but also potential dangers.” His co-lead author Aníbal M. Astobiza, an ethicist from the University of the Basque Country, elaborated:

Bio-hybrid robots create unique ethical dilemmas. The living tissue used in their fabrication, potential for sentience, distinct environmental impact, unusual moral status, and capacity for biological evolution or adaptation create unique ethical dilemmas that extend beyond those of wholly artificial or biological technologies.

Dr. Matt Ryan, a political scientist from the University of Southampton and a co-author on the paper, added: “Compared to related technologies such as embryonic stem cells or artificial intelligence, bio-hybrid robotics has developed relatively unattended by the media, the public and policymakers, but it is no less significant.”

Big Think recently focused on the topic, asking: Revolutionary biohybrid robots are coming. Are we prepared? The article points out: “Now, scientific advances have increasingly shown that biological beings aren’t just born; they can be built.” It notes: “Biohybrid robots take advantage of living systems’ millions of years of evolution to grant robots benefits such as self-healing, greater adaptability, and superior sensor resolution. But are we ready for a brave new world where blending the artificial and the biological blurs the line between life and non-life?”

Probably not. As Dr. Mestre and his colleagues concluded: “If debates around embryonic stem cells, human cloning, or artificial intelligence have taught us something, it is that humans rarely agree on the correct resolution of the moral dilemmas of emergent technologies.”

Biohybrid robotics and fungal computing are emerging fast.

Think you know what robots are? You don’t. Think you understand how computing works? Maybe silicon-based, but probably not “unconventional.” Think you’re ready for artificial intelligence? Fungi-powered AI might still surprise you.

Exciting times indeed.

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Kim Bellard
Kim Bellard

Written by Kim Bellard

Curious about many things, some of which I write about — usually health care, innovation, technology, or public policy. Never stop asking “why” or “why not”!

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