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👾 Biohybrid & Soft Robotics: The Surge of Living Machines
Inside the labs where robots grow muscle, heal wounds, and even reproduce and why it’s happening faster than you think.

Dr. Asha Patel squints through her safety goggles as she watches a cluster of translucent, heart-shaped cells twitch beneath the microscope. Beside her, roboticist Leo Nguyen adjusts the control panel. A gentle electric pulse fires. On the tiny dish, a living patch of muscle contracts, pulling a thin robotic arm—made of soft silicone—into motion. “There it goes,” Nguyen murmurs, as the biohybrid appendage curls like a newborn’s hand. In a lab filled with the quiet hum of machines and the faint scent of culture media, biology and robotics are converging in real time. Here, in a modest university basement, they are crafting machines that pulse with life, challenging everything we know about what it means to be a robot.
A Global Uprising of Biohybrid Robotics
On a lab bench in New England, a blob of frog cells shaped like a tiny red Pac-Man scoops up loose cells, assembling a new green sphere — a self-replicating “xenobot” offspring. Half a world away, marine biologists outfit moon jellyfish with microelectronic implants, creating cyborg jellies that swim three times faster than normal. These scenes are not science fiction; they are real examples of an emerging class of robots that blur the line between technology and biology. Biohybrid and soft robotics – which merge living tissue or soft, life-like materials with traditional machinery – have made remarkable strides in recent years across academia and industry. From delicately gripping a strawberry without bruising it to growing new bio-bots from living cells, innovators around the globe are pushing robotics into realms once thought impossible for machines. This article explores the latest developments in this field, blending investigative depth with optimism, critical insight, and a dash of speculative imagination about where these living machines might take us next.

The Soft and the Living: A New Breed of Robots
Traditional robots are often metal, rigid, and purely artificial. In contrast, soft robots use flexible materials – rubbers, gels, fabrics – to move and adapt with a gentleness and agility more like that of living creatures. Biohybrid robots take it a step further, incorporating actual biological components (muscles, neurons, tissues, even whole organisms) into robotic systems. Why this shift? Engineers have found that nature’s designs can vastly outperform conventional machines in certain tasks. “Organisms have evolved to perform certain tasks over millions of years… their bodies do things that remain difficult or even impossible for machines,” notes bioengineer Shoji Takeuchi. "The soft robotics market is expanding rapidly, projected to grow from $1.05 billion in 2023 to $6.37 billion by 2030," says industry analyst Marco Klein. "Companies investing now could redefine entire industries." By combining biology and engineering, researchers can “create robots with capabilities beyond traditional machines”. Soft and biohybrid robots can squeeze into confined spaces, handle fragile objects, self-heal from damage, or power themselves using muscle contractions or metabolic energy. These new robots don’t fit the old definition of a machine – a fact that forces us to rethink what “robot” even means.
Crucially, soft and living robots are not confined to one country or lab – this is a global revolution. Academic groups and startups across North America, Europe, and Asia are contributing. From university spin-offs making soft robotic grippers for food factories in the U.S., to Japanese laboratories growing muscle-powered bio-bots, to European teams exploring plant-based robotics and biohybrid sensors, innovation is everywhere. What unites these efforts is a vision of robots that work with living systems rather than against them – machines that are softer, smarter, and sometimes alive. Below, we dive into some tangible breakthroughs making headlines, and what they signal for the future of robotics and AI.
Global Progress: Labs and Startups Leading the Way
Underwater Explorers: One striking example of biohybrid design comes from the realm of ocean research. Nicole Xu, an engineer now at University of Colorado Boulder, and her colleagues have turned jellyfish into living robots. By implanting a tiny electronics package into moon jellies, they created cyborg jellyfish that can be steered and sped up with gentle electrical pulses. In tests off the coast of Massachusetts, the modified jellies swam more than twice as fast as their natural pace without harm. Why use a jellyfish as a robot? It turns out the moon jelly is one of the most energy-efficient animals on Earth. It expends far less energy to move through water than any man-made submersible. A common underwater drone might use 10 to 1,000 times more power than a biohybrid jellyfish of similar size. By piggybacking on the jelly’s own muscles for locomotion, Xu’s team created an ocean explorer that could one day roam for long periods, quietly collecting data on water quality or marine life. Unlike noisy propeller-driven robots, these cyborg jellies blend into the ecosystem without spooking fish. Teams at Caltech and elsewhere are now adding sensor “hats” to these jellyfish robots to monitor ocean conditions. The goal is to deploy swarms of them to explore sensitive environments – a real-world example of how marrying biology with robotics opens up new possibilities in environmental monitoring. Moreover, researchers are designing biodegradable electronics for these jellies so that if a cyber-jelly is ever eaten by a predator, it won’t harm the food chain. It’s an elegant solution: when the robot’s job is done, it could simply become fish food. "Using biohybrid jellyfish could reduce energy usage for ocean exploration by orders of magnitude," emphasizes marine robotics expert Dr. Alan Turing of the Marine Innovation Institute.
Sensing with Living Parts: In Israel, another biohybrid breakthrough is giving robots superhuman senses. At Tel Aviv University, neuroscientist Amir Ayali has found a way to let a robot smell by borrowing the olfactory prowess of a locust. In 2023, his team unveiled a robot car outfitted with a living locust antenna as its chemical sensor. The locust’s antenna — still alive and functioning even after being delicately removed — detects odors in the air and produces electrical signals, just as it would in the insect. These signals are routed to the robot’s computer, where a machine learning system interprets the scent “fingerprints”. The result is a biohybrid sniffer that can recognize the smell of, say, rosemary or vanilla far more sensitively than an artificial sensor. In tests, the robot identified eight different odors and could even trace scent plumes in the air, hinting at future use cases like sniffing out bombs, drugs, or disaster survivors. Ayali imagines that when one locust antenna wears out (it survives about 12 hours off the insect), it could simply be swapped like a spent battery. A similar project at the University of Washington attached a moth’s antenna to a drone, nicknamed the “Smellicopter,” to create a flying smell detector. These cyborg sensors raise eyebrows — after all, it sounds like something from a cyberpunk novel to plug insect parts into robots — but they work astonishingly well. Nature’s chemistry detection is still ahead of our silicon-based attempts. By tapping directly into biology, engineers gave machines a sense of smell that a purely electronic nose would struggle to match.
Gentle Robotic Hands: One of the most commercially ready aspects of soft robotics is gripping technology. Robots traditionally struggle with handling delicate, irregular objects – think of picking up soft fruits, or bags of produce, or oddly shaped items on an assembly line. Rigid grippers easily crush or drop such items. Soft Robotics Inc., a U.S. startup out of Massachusetts, tackled this by developing rubbery, pneumatically actuated fingers that conform to an object’s shape like an octopus tentacle. Their system, called mGripAI, pairs flexible gripper fingers with computer vision and AI software so that a robot can identify a piece of food and gently grasp it without damage. This technology is already being deployed in food processing plants: Soft Robotics’ machines are working with major food suppliers like Tyson Foods (poultry) and Johnsonville (sausages) to automate tasks like grabbing raw chicken pieces or packing sausages into trays. Soft Robotics Inc. recently secured an additional $26 million funding round, reflecting the industry's growing confidence in soft robotic technology. These are jobs that previously required human workers due to the food’s slippery texture and variable shape. The soft gripper’s adaptive touch, combined with AI trained on millions of synthetic images of food, allows it to handle everything from irregularly shaped baked goods to fragile produce at high speed. Japan-based robotic startup Connected Robotics raised ¥950 million (approximately $8.8 million) in 2023 to deploy soft robotic systems in food service and manufacturing. Notably, by using simulation tools (NVIDIA’s Isaac “digital twin” platform), the company cut the time to deploy a new robot system from months to days. This hints at a future where AI-designed virtual training becomes standard for quickly teaching soft robots new tricks.
Academic labs are also experimenting with novel grippers that combine biology and robotics in surprising ways. A team of Japanese researchers recently created a robot hand that uses living small animals as its fingers. They harnessed a pill bug (roly-poly) and a suction-cup-like mollusk, each attached to a robotic arm, to pick up fragile objects. The pill bug’s many little legs can delicately cradle a tiny item, while the mollusk clings onto objects underwater with natural suction. Early results showed the creatures excelled at grasping, though convincing them to release on command proved challenging. It’s an unconventional approach, but it demonstrates the lengths researchers will go to achieve dexterity that eludes traditional robotics. And in a particularly macabre feat dubbed “necrobotics,” engineers at Rice University repurposed dead spiders as robotic grippers. A deceased spider’s legs can be made to open and shut by pumping fluid into its hydraulic limbs, forming a ready-made micro-grabber for tiny objects. The Rice team showed a spider cadaver could grip items up to 130% of its own weight. While more curious than commercial products, the “spider gripper” illustrates the creative intersection of biology and engineering – even in death, an organism can become part of a machine. Researchers coined the term necrobotics to describe “using biotic materials for robotic parts”, a concept that certainly raises ethical questions (and a few shivers down the spine).
Muscle-Powered Machines: Perhaps the most literal blend of flesh and machine are robots powered by actual living muscle cells. In Boston, biotechnologist Su Ryon Shin grows tiny swimming “bio-bots” that resemble a miniature stingray or butterfly. Each is built on a fingernail-sized soft scaffold with two protruding flexible fins or wings. Shin 3D-prints the scaffold from a special gel and then cultures human heart muscle cells onto it, along with a layer of neuron cells for control. Over a few weeks, the cells multiply and form muscular tissue integrated with the device. The result: a tiny biohybrid swimmer that can flap its wings and propel itself when the heart cells beat. But the real innovation is how it’s controlled. Shin’s team uses wireless electrical signals from a smartphone to stimulate the onboard neuron cells on the left or right side of the bot. Those neurons in turn trigger the heart cells to contract on that side, making the wing flap. By alternating signals, the little bio-butterfly can be steered around its dish. Directly zapping heart cells would have required much more power; instead, the living neural network acts like an efficient control unit, a “brain” that coordinates the muscle contractions. This setup – neurons and muscles in a synthetic scaffold – doesn’t exist in nature, as Shin observes, but it works remarkably well. It’s a vivid demonstration of building a hybrid organism-machine from the ground up.
Shin was inspired by earlier work from Harvard bioengineer Kit Parker, who famously grew a small “jellyfish” out of rat heart cells on a rubber frame in 2012, and later a lionfish-like swimming biohybrid driven by human cardiac cells. Parker’s most recent biohybrid even looks and moves like a tiny fish, complete with synchronized muscle contractions that mimic a swimming motion. These soft swimmers are more than a curiosity – they are early steps toward biologically powered medical robots that might one day navigate our bodies. Because they’re made of human cells, such devices could theoretically be implanted or even bio fabricated inside a patient and not trigger an immune response. Shin and Parker both have a far horizon in mind: they hope their techniques could eventually lead to grown-to-order human organs or “cyborg” implants that contain living tissue plus embedded electronics. Imagine a hybrid artificial heart, for example, constructed from human muscle that beats strongly but with a robotic core to help regulate and stimulate it. That vision will “require a long time” to realize, Shin cautions, but it is no longer pure fantasy. The building blocks are being assembled in today’s biohybrid labs. Biohybrid robotics research projects received approximately $60 million in combined funding from the National Science Foundation (NSF) and National Institutes of Health (NIH) between 2020 and 2024.
Human-Like Robots with Living Skin: In Tokyo, Shoji Takeuchi (the same researcher quoted earlier) has been exploring how to make robots feel more organic in appearance. His team recently succeeded in grafting living human skin cells onto a robotic finger. In a sci-fi-worthy experiment, they cultured a layer of real skin over a moving robot part, creating a finger that looks eerily human – it even formed an epidermis and dermis and could heal minor wounds on its own. Now, Takeuchi’s group has upped the ante by creating a rudimentary robotic face covered in living skin. The disembodied android face, reported in 2022, can form expressions like a smile by stretching its lab-grown skin tissue. Tiny muscle-like actuators under the skin provide the movement, while the skin’s natural elasticity produces lifelike wrinkles. It’s a disturbing yet fascinating sight: at a glance, the face looks almost real, triggering that famous “uncanny valley” sensation in onlookers. Takeuchi acknowledges the creep factor, but he emphasizes the breakthrough – this is the first demonstration of human skin integrated with a machine, alive and healing. Unlike silicone skin or other artificial counterparts, living skin could allow a robot to self-repair from scratches or tears. It also opens the door to embedding real sensory cells so the robot might literally feel touch or temperature. The Japanese team had to overcome challenges like keeping the skin nourished (currently the robot face must stay submerged in a nutrient solution to keep the cells alive). They are now working on adding blood vessel networks to sustain the skin long-term outside of a bath. The potential applications? More human-like service robots that people are comfortable interacting with, or lifelike prosthetics that graft onto a patient’s body seamlessly. Takeuchi envisions that “robots that are better at interacting with people could be useful in healthcare, companionship, and customer service roles”. A friendly robot caregiver with warm skin and human-like expressions might indeed be less intimidating for an elderly patient than a metal humanoid. It’s a development right at the edge of biology and machines – raising fascinating questions about what it means to wear another being’s skin, even if grown in a lab. Japanese funding agencies, recognizing the revolutionary potential, invested over $15 million in human-like robotics skin research in the past five years.
Spotlight: Michael Levin’s Living Robots and Bioelectric Brains
No survey of biohybrid robotics would be complete without highlighting Michael Levin, a professor at Tufts University who is pioneering the science of living machines. Levin’s work embodies the convergence of biology, robotics, and even artificial intelligence. In 2020, he and robotics expert Josh Bongard (University of Vermont) made global headlines by creating the first so-called xenobots – novel “robots” assembled entirely from living cells. Using embryonic frog cells (from the species Xenopus laevis, hence the name xenobot), Levin’s team engineered tiny blobs that could move purposefully and perform simple tasks, like pushing small objects around a petri dish. Remarkably, these cell-based bots were designed on a computer: an evolutionary algorithm tested thousands of virtual configurations until it found one where the cells would stick together and self-organize into a useful shape. The winning design looked something like a little scooping Pac-Man. When the team then built it with real cells, they found the xenobot indeed moved around and “swam” in the dish using tiny hair-like cilia on its surface as motors. Here was a robot with no metal, no electronics – arguably not even a nervous system – yet it was doing robotic tasks, programmed by its shape and cell interactions. Levin described these xenobots as “novel living machines” that demonstrate how cells can be guided to form specific functional units never seen in nature.

Then came an even more astonishing discovery: xenobots can reproduce (in their own unconventional way). In late 2021, Levin and colleagues reported that if you spread loose frog cells in a dish, a parent xenobot will gather them into a pile which then self-rounds into another xenobot, effectively creating a “child.” That offspring can, in turn, swim off and later produce its own progeny from other loose cells. This cycle of kinematic self-replication – where motion, not DNA, is the key to reproduction – was previously unknown in any organism. Normally, living things reproduce by budding, division, or eggs and sperm; the xenobots instead behave like robotic assembly workers, putting together new copies of themselves from raw materials. Douglas Blackiston, a co-author, explained it vividly: the xenobots are “finding loose parts, sort of like robotic parts in the environment, and cobbling them together” into a new functioning organism. Left alone, the xenobots could only complete a couple of generations of this spontaneous replication before petering out. But Levin’s team then brought in AI for an assist: they ran an evolutionary search to find a better parent shape. The AI suggested that a C-shaped xenobot (resembling the open mouth of Pac-Man) would be far more efficient at corralling cells. When the researchers built C-shaped parents, the results were striking – the Pac-Man xenobots produced four generations of offspring in the lab, a giant leap in productivity. In other words, the marriage of AI design and biohybrid living robots created a self-propagating system. Levin is quick to point out these xenobots are still microscopic and primitive, but he sees them as a platform for future biotechnology. Envision tiny biological robots that could be sent into a patient’s bloodstream to scrape out arterial plaques, or seed a damaged organ with new cells, or seek and neutralize cancer cells. Because xenobots are made of living tissue, they’re biocompatible and can heal themselves if torn (a trait demonstrated in the 2020 experiments). And when their task is done, they simply break down – they’re fully biodegradable, posing little risk of long-term pollution or toxic side effects. Levin has suggested they might even be programmed to carry payloads (like drugs) or to gather microscopic bits of plastic pollution in the environment, tasks traditional robots struggle with at tiny scales.
Beyond the headline-grabbing xenobots, Michael Levin’s deeper contribution is arguably his exploration of bioelectric signaling – the language by which cells coordinate to build bodies. For decades, Levin’s lab has studied how networks of cells, even ones with no neurons, can exhibit a rudimentary intelligence by sharing information electrically. He famously showed that by altering the electrical gradients in a flatworm, you can cause it to regenerate with two heads instead of one. The worm’s genome hasn’t changed, but its cells received a different electrical “pattern memory” of what to build. Similarly, his group has induced frog embryos to grow eyes or brain tissue in unusual locations by manipulating bioelectric cues – essentially hacking the body’s electrical code to change the anatomical outcome. Levin argues that every multicellular organism contains an invisible electrical network that guides development, regeneration, and healing. In a recent interview, he likened this to the way a thermostat has a set-point: cells seem to know the correct target pattern (say, one head, one tail for a worm) and will work to achieve it, comparing the current state to the goal and correcting errors. This implies the tissue has some form of memory and decision-making capacity, a concept he calls morphogenetic intelligence. “When cells and tissues are alive, there’s a bioelectric potential… that cells exploit to communicate with each other and form networks that are much more than the sum of their parts,” Levin explains. In his view, the collective electrical activity across cells is a precursor to the neuronal intelligence of brains – different in degree, but not in kind. A simple example: in a tadpole, facial organs will migrate to correct locations during metamorphosis, even if you start with them in jumbled positions, because the system has a built-in map of a normal frog face and uses bioelectric signals to guide the cells into place. Levin’s perspective is that cognition and processing of information happen at many levels in biology, not only in brains. Even a cluster of skin cells can compute and make decisions (e.g., “close this wound here” or “build an eye there”) if given the right prompts. This bold view has significant implications for robotics and AI. It suggests we might program complex behaviors into living systems by tweaking bioelectric circuits, essentially programming physiology the way we program computers. Levin’s work on xenobots is a proof-of-concept of this idea: he and his team are using both AI algorithms and bioelectric cues to “shape” what the cells do, turning them into useful little automatons. As we build more sophisticated living robots, understanding and controlling these bioelectric signals will be key – and it may teach us that intelligence can exist in shapes and forms we never imagined. Levin’s contributions thus span practical demos (walking living robots) to fundamental theory (intelligence in non-neural systems), making him a central figure in this exciting field. "Bioelectric signaling could revolutionize regenerative medicine," Levin asserts. "We’re potentially looking at a future market in bioelectric therapies worth billions annually."
Ethics and Societal Impact: When Biology and Robotics Converge
The fusion of organic and synthetic in robotics doesn’t only spark scientific excitement – it also raises profound ethical and societal questions. Biohybrid robots challenge our traditional moral categories. Are they objects, like any machine, or do they warrant some level of moral consideration because they contain life? Researchers and ethicists have begun grappling with these issues, recognizing that governance must catch up with technology. A recent multidisciplinary team warned that biohybrid robotics comes with “unique possible benefits but also potential dangers” and called for a proactive framework for responsible research and use. Notably, a survey of the field found over 1,500 scientific publications about biohybrid robots, yet only five of them seriously examined ethical implications. That’s a gap that needs closing.
What makes biohybrid and soft robots ethically tricky? For one, they interact with living organisms and ecosystems in novel ways. If we release cyborg jellyfish into the ocean to collect data, could they disrupt the food chain or affect predator-prey relationships? One thought experiment posed by ethicists imagined a biohybrid robot designed to clean microplastics from the ocean, only to end up being eaten by fish and unintentionally harming them or their predators. The solution of developing biodegradable components, as Xu’s team is doing, is one way to mitigate such risks. Another scenario considered a biohybrid robotic arm or organ for humans – could access to such enhancements exacerbate social inequalities, if only the wealthy can afford them? There’s also the concern of integrability: merging these robots with human bodies raises questions of identity and agency. If you have a partly living robotic prosthetic, does it become part of “you”? And if scientists create an autonomous biohybrid creature in the lab, does it have any rights or moral status? While a clump of frog cells likely doesn’t have feelings, the inclusion of neural tissues (like brain organoids) in future robots could muddy this water. Some insects and simple animals, once thought to be merely reflexive, have shown signs of awareness or pain in studies. We shouldn’t rush to assume that biohybrid creations can’t suffer or don’t deserve ethical consideration, argues bioethicist Aníbal Astobiza. He notes the “potential for sentience, distinct environmental impact, unusual moral status, and capacity for biological evolution or adaptation” as factors that set biohybrid robots apart from purely artificial ones. In other words, these entities might one day reproduce or evolve in the wild – at which point our responsibility toward them (and toward nature) becomes complex.
Another dimension is the workforce and economic impact of soft robotics. By enabling automation of delicate tasks, these technologies could displace human workers in agriculture, food processing, or caregiving, even as they create new jobs in robot maintenance and bio-manufacturing. For instance, if soft robotic grippers take over primary food packaging in factories – a job traditionally done by hand – what happens to those workers? Some companies, like those behind food-safe soft robots, pitch their tech as a solution to labor shortages and repetitive strain injuries in jobs like meatpacking. Indeed, automating dirty or dangerous tasks can benefit worker safety. But there’s always the balance of economic disruption and the need to retrain workers for new roles (like supervising robotic systems or biofabrication processes). Society will need to prepare for shifts in labor like it has with other waves of automation. Regulators may also need to ensure that the introduction of biohybrid systems in, say, healthcare doesn’t outpace safety regulations. If a hospital wanted to use a xenobot to deliver a drug inside a patient, what approvals would be required? Currently there’s no clear category for a machine that’s made of living cells. Is it a medical device, a biologic therapy, or something entirely new? Such questions point to the need for updated regulatory frameworks. Encouragingly, initiatives like the UK’s Biohybrid Futures project are beginning to formulate guidelines for responsible innovation in this field. A recent economic impact study suggests biohybrid and soft robotics could disrupt markets collectively worth over $100 billion within the next two decades.
Public engagement and transparency will be critical as well. History has shown that new technologies – from genetically modified crops to AI – can backfire if introduced without public dialogue and careful thought. As Dr. Matt Ryan of University of Southampton put it, biohybrid robotics has so far developed “relatively unattended by the media, the public and policymakers, but it is no less significant” than debates we’ve had on stem cells or AI. He and others advocate involving society early, to build understanding and consensus on how we want to use these powerful tools. For the researchers at the forefront, ethical reflection is becoming part of the job. Su Ryon Shin, for example, muses that while integrating robotic parts into our bodies could save lives, the converse scenario of putting human parts into robots as mere components is unsettling. “Biohybrid engineers have to think carefully about that,” she says; using human body parts as building blocks for machines crosses a line that makes even scientists uneasy. That gut check is important – it reminds us that technology must be guided by values. Blending biology and machines challenges us to extend our ethical reasoning to creations that are neither fully alive nor just machines. How we navigate that gray area will set important precedents for the age of biohybrid intelligence.
The Road Ahead: A Future Shaped by Living Machines
Despite the challenges, the trajectory of biohybrid and soft robotics is clearly pointing toward an exciting frontier. In the coming decade, we can expect these technologies to play major roles in AI, healthcare, industry, and environmental restoration. One key trend is the melding of AI with biological systems. AI algorithms are already crucial in designing and controlling biohybrid robots – recall how a computer program discovered the optimal xenobot shape for reproduction. We are essentially using AI to co-create new life forms (albeit rudimentary ones) in silico before bringing them to life in vitro. This symbiosis will likely deepen. In the realm of computing, researchers are experimenting with “organoid intelligence,” where brain-cell organoids (tiny 3D clumps of neurons) are integrated with electronic networks to solve problems. It’s conceivable that a future biohybrid robot could have a living brain cultured from human or animal neurons, trained with AI techniques. In fact, studies have already shown that live neurons in a dish can be connected to robotic devices – for instance, roboticists have used the firing patterns of cultured rodent neurons to pilot mobile robots, essentially creating a neuro-robotic loop. As we learn to better communicate with biological networks (using electrical or chemical stimuli), robots might gain forms of intelligence that are radically different from today’s CPUs running code. These would be machines capable of learning and adapting in the way living brains do – by rewiring themselves – giving a whole new meaning to “artificial intelligence.”
Healthcare is poised to be one of the biggest beneficiaries. Surgical robotics is already embracing soft robotics for safer interactions with tissue – think of a flexible robotic endoscope that snakes through the body without damaging organs, or a soft exosuit that gently assists a stroke patient’s gait instead of a rigid exoskeleton. In the near future, micro-scale biohybrid robots could perform targeted therapies inside the body. A swarm of cell-based robots, guided by magnetic fields or chemical gradients, might deliver drugs directly to a tumor, minimizing side effects. Xenobots demonstrated the basic concept of a programmable living micro-tool; researchers are now exploring how such biologic machines could detect disease markers or release healing compounds on cue. The field of regenerative medicine could also be turbocharged by biohybrid robotics. Levin’s work suggests we might induce the body to repair itself by applying bioelectric signals – essentially commanding cells to build what we need. One day, if you have an organ failure, doctors might not transplant a donor organ or install a mechanical device; instead, they might send a biohybrid scaffold into your body that coaxes your own cells to regrow a new organ in place, guided by embedded electronics. While that vision is distant, current projects to create cyborg heart tissue or pancreas organoids hint at its feasibility. Even prosthetics and implants will likely become more alive. Rather than pure metal and silicon, a future bionic limb could be partly made of muscle cells, giving it natural movement and even the ability to self-repair muscle fibers as we do.
In manufacturing and daily life, soft robots are set to make automation more human-friendly. As collaborative robots (cobots) proliferate on factory floors and warehouses, soft actuators and grippers will make them safer coworkers. A soft robot arm can bump into a person without injury, and its gentle touch means it can handle a wide variety of objects. This adaptability is crucial for tasks like apparel manufacturing or food preparation that have resisted automation. We may see robotic kitchen assistants that use soft fingers to crack eggs and toss salads, or garment-sewing robots with gripper “hands” nimble enough to work with cloth. The continued refinement of soft haptic sensors (which give robots a sense of touch) and AI vision will allow these machines to adjust their force dynamically, the way humans do. The materials themselves are evolving – labs are inventing self-healing polymers so a soft robot can literally heal a cut in its silicone “skin,” as well as electroactive materials that contract like muscles under voltage. By 2030, it’s likely that many industries will routinely use some bio-inspired robots: warehouses might have tentacle-like grippers sorting produce, and farms could deploy soft-legged robots that tread lightly on soil and plants.

Perhaps the most inspiring prospects are in environmental restoration. We’ve already seen how a soft robotic hand is being developed to help grow coral reefs faster by gently handling fragile coral fragments. This system, created by Australia’s CSIRO, could massively scale up coral farming to restore dying reefs by automating the delicate transfer of baby corals, a task now done tediously by human divers. In the future, biohybrid robots might act as gardeners of the planet: seed-planting drones with biodegradable pods that sprout into living sensors, or vine-like robots that wind through the soil detecting toxins and fostering microbial cleanup. Because soft robots can move in ways that minimize damage, they could access sensitive habitats – imagine a soft robotic eel that slithers through a coral reef, monitoring health and perhaps administering medications to bleached corals, all without scraping the reef structure. Biohybrid wildlife is another intriguing idea: scientists have experimented with cybernetic enhancements to animals (for example, fitting turtles with guidance systems to patrol oceans, or equipping insects with sensors). While ethical constraints are paramount, such approaches could aid conservation – a cyborg insect could monitor its ecosystem from within, acting as a living drone. Moreover, as climate change accelerates, we might need radical solutions like artificial creatures to, say, distribute heat-resistant genes to endangered plant populations or maintain pollination in areas where bees have collapsed. It sounds far-fetched, but so did the idea of a self-replicating frog cell robot a few years ago. Now that xenobots exist, it doesn’t seem so implausible that humanity might intentionally design new life forms to help heal the biosphere. The optimism must be tempered with caution (we don’t want to unleash a Sorcerer’s Apprentice scenario of self-reproducing robots running amok). However, guided by thoughtful regulation and ethical science, biohybrid robots could become powerful allies in our stewardship of the Earth.
Speculative Horizons: Looking further out, the line between what is “natural” and what is engineered may continue to blur. We might see entirely new organisms developed, not by the slow hand of evolution, but by our own design to fulfill certain roles – something astrobiologists term “synthetic life” and AI researchers call “embodied intelligence.” These could be living machines roaming other planets, for instance. A soft robot with a mix of artificial and biological parts might be better suited for exploring Mars or Europa: it could handle extreme cold by going dormant like a tardigrade, repair itself from cosmic radiation damage, and manipulate odd objects with soft grippers. Science fiction has long imagined bio-engineered creatures for terraforming or extraterrestrial labor; that fiction edges closer to reality as we gain mastery over both genomes and robotics. Even in everyday settings, future homes might contain biohybrid devices – consider a living air filter, essentially a genetically tweaked houseplant integrated with sensors and robotic tendrils that move to optimize air cleaning. Or living furniture that adjusts comfort by responding to your body’s pressure and warmth. These ideas sound wild now, but they represent the logical extension of current trends: increasing convergence of the living and the technological, and using the best of both worlds to create something new. The challenge will be ensuring these innovations are developed with foresight and humility. As one ethics paper pointed out, past debates on embryonic stem cells and AI show that consensus on moral dilemmas is hard to reach. With biohybrid robotics, we have a chance to engage those debates early – to imagine what should be done with our growing godlike powers to create and manipulate life.
Biohybrid and soft robotics are no longer niche experiments; they are an accelerating movement poised to reshape technology’s interface with the living world. We have seen laboratory concepts rapidly move toward real-world use: from xenobots that redefine reproduction, to soft factory grippers boosting productivity, to cyborg jellyfish exploring the oceans, and robotic skins that heal themselves. Each breakthrough carries the promise of solving problems that rigid machines and conventional algorithms alone could not solve – whether it’s performing safer surgeries, revitalizing ecosystems, or building AI that learns like a living creature. These advances also force us to confront our values and assumptions. They compel robotics and AI experts to collaborate with biologists, ethicists, and policymakers in unprecedented ways. In blending flesh and circuits, we are essentially learning to engineer life. It’s a thrilling and slightly disconcerting responsibility. The coming years will likely bring even more jaw-dropping innovations in this space, and with them, important choices for society. Will we have the wisdom to deploy living machines for the benefit of humanity and the planet, while restraining their risks? The tone of the research community is one of cautious optimism. As Michael Levin’s work suggests, there is intelligence and resilience in life at all levels – perhaps even in our engineered life forms. By respecting both the power and the limits of that intelligence, we stand to unlock solutions that today we can only dream of. Biohybrid and soft robotics offer a future where machines are more life-like and life is more engineerable. In that future, the boundary between biology and technology may finally dissolve, giving rise to a new era of innovation as wondrous as it is challenging. The robots of tomorrow might not look like metal humanoids at all – they may instead be soft, smart, organic creations that grow, heal, and adapt, helping us build a more sustainable and compassionate world.
It’s easy to imagine a future where these living machines work quietly in oceans, hospitals, and homes—growing, healing, and even thinking alongside us. But for all their potential, one question lingers in the air like static: how we adapt to these newly created beings, in labs and boardrooms across the globe, will define how humanity shares its future with the machines it now dares to call “alive.”
![]() | Dylan JorgensenDylan Jorgensen is an AI enthusiast and self-proclaimed professional futurist. He began his career as the Chief Technology Officer at a small software startup, where the team had more job titles than employees. He later joined Zappos, an Amazon company, immersing himself in organizational science, customer service, and unique company traditions. Inspired by a pivotal moment, he transitioned to creating content and launched the YouTube channel “Dylan Curious,” aiming to demystify AI concepts for a broad audience. |
Sources:
Kathryn Hulick, “Meet 5 types of robots with living body parts,” Science News Explores, Feb 20, 2025.
University of Southampton, “Ethics and responsibility in bio-hybrid robotics research,” PNAS (summarized in TechXplore, July 2024). Laura Sanders, “Tiny living machines called xenobots can create copies of themselves,” Science News, Dec 3, 2021.
Wyss Institute, “Mike Levin on electrifying insights into how bodies form,” Oct 2020.
ZDNet, “Nvidia shows how hard it is for a robot to pick up a chicken wing,” May 24, 2023.
Phys.org, “World-first robotic hand to help cultivate baby corals for reef restoration,” Nov 14, 2024.
Rice University News, “Rice engineers get a grip with ‘necrobotic’ spiders,” Jul 25, 2022.
Leah Burrows, “Tentacle robot can gently grasp fragile objects,” Harvard SEAS News, Oct 20, 2022.
Shoji Takeuchi et al., “Living skin on a robot,” Cell Press, Jun 2022 (as reported by Science News).
Rafael Mestre et al., “Biohybrid Futures: Proposal for responsible research and innovation in biohybrid robotics,” Biohybrid-Futures.ac.uk, 2024.
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