While it has not yet controlled neurons in living animals, ICOPS could open new paths for studying the gut's nerve networks -- and one day inform therapies for digestive disorders.
NEW YORK -- Researchers at New York University have built a wireless capsule the size of a large vitamin that rats can swallow, giving scientists a unique way to shine light into their digestive systems without surgery. The device opens new doors for studying the enteric nervous system, a network of neurons in the gut often nicknamed the "second brain" in popular science. In the study itself, the researchers describe it as the body's second-largest collection of neurons after the brain.
Scientists have long struggled to study gut neurons because traditional methods require cutting animals open, which damages tissue and disrupts normal gut function. The new capsule, called ICOPS (Ingestible Capsule for Optical Stimulation), travels naturally through the digestive tract while delivering light to specially engineered neurons.
Not only is it the first swallowable optical stimulation device designed for rodents, but it's manufactured entirely through 3D printing without needing expensive chip-making facilities.
Wireless Power Makes the Magic Happen
The capsule is designed for use with optogenetics, a method that engineers neurons to act like light switches. When equipped with special proteins, neurons can be turned on or off with flashes of light. ICOPS uses a micro-LED that operates at about 470 nanometers, emitting predominantly at 460 nanometers, a wavelength known to trigger common optogenetic proteins.
Traditional electrical stimulation can't match this precision because it activates all nearby nerve cells at once, like flipping every switch in a house instead of just one.
At 2.7 millimeters wide and 18 millimeters long, the capsule weighs just 0.22 grams and passes through rat digestive systems naturally within 20 hours. The device doesn't need batteries, which would make it too large and potentially dangerous. Instead, it receives energy through magnetic fields generated by external coils.
Scientists place test animals inside a specially designed cage equipped with four spiral coils. These coils create magnetic fields that power the device as rats move freely around their cage. The system works at distances up to 14 centimeters (about the length of a dollar bill) and even when the capsule rotates 75 degrees. The coils operate at low frequencies of 45-63 kHz to minimize tissue heating and stay within international safety limits.
Engineering Challenges Solved with Tiny Components
Building sufficient power into such a tiny device required some serious engineering creativity. The research team at the NYU Tandon School of Engineering packed a receiver coil with 460 turns of copper wire around a ferrite core, paired with a micro-LED and capacitor to optimize power transfer. Picture wrapping thread around a toothpick 460 times, but much more precisely, and you get the idea of the coil complexity.
The transparent plastic housing allows about 80% of blue light to pass through while protecting the guts of the device. Lab tests confirmed durability by soaking three devices in simulated gastric fluid for two days. All kept working perfectly, showing the capsule can handle the harsh conditions inside a digestive system.
When researchers checked how hot the device gets during operation, they found only a 2-degree Celsius increase during extended use, well within safe limits for living tissue. The modest heating happens because the blue LED generates some heat, but the capsule's surface area lets it cool efficiently.
Safety analysis confirmed the magnetic fields stay within occupational exposure limits set by international radiation protection guidelines. The team measured specific absorption rates, which track how much electromagnetic energy tissues absorb, and found levels well below established safety thresholds.
From Idea to Working Gadget
Scientists built their device entirely through high-precision 3D printing that builds objects layer by layer using light. This approach avoids expensive semiconductor fabrication facilities typically needed for such precision electronics, making the technology accessible to research institutions worldwide and allowing rapid tweaking of design variations.
Researchers successfully printed hundreds of device housings at once, supporting high-volume production at relatively low cost. The simple circuit design contains only three main parts (receiver coil, capacitor, and LED), keeping complexity and expenses manageable.
In live rat studies, scientists successfully tracked the capsule's journey using micro-CT imaging, which easily spots the metal coil components against surrounding tissue. The device maintained consistent power delivery regardless of where animals positioned themselves or how active they got, proving it functions during normal digestive transit.
Testing revealed the capsule works effectively up to 14 centimeters lengthwise and 9 centimeters sideways from the power source. The device even keeps functioning when rotated 75 degrees relative to the magnetic field, ensuring reliable operation as it moves through the curved digestive tract.
What This Enables and Current Roadblocks
The device lets researchers study gut neurons without the headaches of surgical implants, including tissue damage, infection risk, and behavioral changes that can throw off experimental results. Animals stay in their natural state while scientists deliver light at specific locations along the digestive tract.
Several limitations currently restrict what the technology can do. The study only tested rats using a small sample size. The device only works on specially engineered lab rats whose gut cells have been modified to respond to light, like installing biological light switches. Current designs work only once and operate exclusively with blue light wavelengths.
The technology also depends on external power systems that keep animal mobility limited to specially equipped cages. While rats can move freely within the cage, they can't venture outside the magnetic field range generated by the coil system.
Researchers note that no actual light-controlled neuron experiments happened in this initial study. The work focused on proving the device concept and showing wireless power delivery actually works. Future research will need to demonstrate whether the light output can effectively control genetically modified gut neurons in living animals.
Manufacturing Innovation Opens New Doors
The 3D printing approach breaks away from traditional microelectronics manufacturing. Instead of relying on clean room facilities and semiconductor fabrication techniques, researchers used readily available printing technology to create precision components.
This manufacturing strategy enables rapid iteration and customization. The team designed custom molds with built-in channels for threading tiny wires and anchoring points for soldering, eliminating many traditional assembly headaches. The modular approach lets researchers easily swap different LED types or modify circuit components.
Future versions could pack in multiple LEDs emitting different wavelengths, letting researchers target various light-sensitive proteins at the same time. Such upgrades could allow scientists to activate some neurons while silencing others within the same experiment, providing more sophisticated control over gut neural circuits.
The research team also envisions scaling the technology for different animal models, though human applications remain distant and would require extensive additional development to meet medical device standards and safety requirements.
This swallowable light source represents an early but important step toward better tools for studying gut neuroscience. While current applications focus on basic research in laboratory animals, the underlying wireless power and miniaturization technologies could eventually inform development of therapeutic devices for human digestive disorders.