Nano-bio interfaces enable communication between synthetic materials and biological systems at the nanoscale, with their functionality shaped by material properties, surface chemistry and topography. This Review discusses the key considerations and methods for engineering nano-bio interfaces for bioelectrical signal detection and biochemical signal transduction.
Creatures like sea stars, jellyfish, sea urchins and sea anemones don’t have brains, yet they can capture prey, sense danger and react to their surroundings.
So does that mean brainless animals can think?
“Brainless does not necessarily mean neuron-less,” Simon Sprecher, a professor of neurobiology at the University of Fribourg in Switzerland, told Live Science in an email. Apart from marine sponges and the blob-like placozoans, all animals have neurons, he said.
Creatures like jellyfish, sea anemones and hydras possess diffuse nerve nets — webs of interconnected neurons distributed throughout the body and tentacles, said Tamar Lotan, head of the Cnidarian Developmental Biology and Molecular Ecology Lab at the University of Haifa in Israel.
“The nerve net can process sensory input and generate organized motor responses (e.g., swimming, contraction, feeding, and stinging), effectively performing information integration without a brain,” she told Live Science in an email.
This simple setup can support surprisingly advanced behavior. Sprecher’s team showed that the starlet sea anemone (Nematostella vectensis) can form associative memories — learning to link two unrelated stimuli. In the experiment, the researchers trained sea anemones to associate a harmless flash of light with a mild shock. Eventually, the light alone made them retract.
Another experiment showed that sea anemones can learn to recognize genetically identical neighbors after repeated encounters and curb their usual territorial aggression. The fact that anemones change their behavior toward genetically identical neighbors suggests they can distinguish between “self” and “non-self”
Octopuses and other cephalopods are masters of camouflage, thanks largely to color-changing skin that can help them seemingly vanish into the background. Now, researchers report a big step towards being able to recreate their superpower.
A team led by UC San Diego was able to mass-produce a key pigment, xanthommatin, that occurs in the psychedelic skin of many cephalopods. Until now, xanthommatin has proven impractical to collect from animals or make in a lab.
The researchers technically didn’t make the pigment. They bioengineered bacteria to make it, coaxing microbes to not only produce this rare substance, but to do so with unprecedented efficiency, yielding up to 1,000 times more xanthommatin than previous methods.
Researchers are one step closer to understanding how some plants survive without nitrogen. Their work could eventually reduce the need for artificial fertilizer in crops such as wheat, maize, or rice.
“We are one step closer to greener and climate-friendlier food production,” say Kasper Røjkjær Andersen and Simona Radutoiu, both professors of molecular biology at Aarhus University. The findings are published in the journal Nature.
The two researchers led a new study where they discovered an important key to understanding how we can reduce agriculture’s need for artificial fertilizer.
What is it that makes a super recognizer —someone with extraordinary face recognition abilities—better at remembering faces than the rest of us?
According to new research carried out by cognitive scientists at UNSW Sydney, it’s not how much of a face they can take in—it comes down to the quality of the information their eyes focus on.
“Super-recognizers don’t just look harder, they look smarter. They choose the most useful parts of a face to take in,” says Dr. James Dunn, lead author on the research that was published in the journal Proceedings of the Royal Society B: Biological Sciences.
A theoretical framework predicts the emergence of non-reciprocal interactions that effectively violate Newton’s third law in solids using light, report researchers from Japan. They demonstrate that by irradiating light of a carefully tuned frequency onto a magnetic metal, one can induce a torque that drives two magnetic layers into a spontaneous, persistent “chase-and-run” rotation. This work opens a new frontier in non-equilibrium materials science and suggests novel applications in light-controlled quantum materials.
In equilibrium, physical systems obey the law of action and reaction as per the free energy minimization principle. However, in non-equilibrium systems such as biological or active matter—interactions that effectively violate this law—the so-called non-reciprocal interactions are common.
For instance, the brain comprises inhibitory and excitatory neurons that interact non-reciprocally; the interaction between predator and prey is asymmetric, and colloids immersed in an optically active media demonstrate non-reciprocal interactions as well. A natural question arises: Can one implement such non-reciprocal interaction in solid-state electronic systems?
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People with autism spectrum disorders commonly have difficulty processing sensory information, which can make busy, bright or loud settings—such as schools, airports and restaurants—stressful or even painful. The neurological causes for altered sound processing are complex, and researchers are interested in better understanding them to make life better for people with autism.
In a study that combines behavioral tests, computer models and electrophysiological recordings of neuron activity, researchers have found that hyperactivity of neurons in the auditory cortex and the reaction of these neurons to an unusually broad range of frequencies contribute to this altered sound processing in rat models. The research is published in the journal PLOS Biology.
“One of the things we thought wasn’t being looked at enough was this idea of sensory discrimination: being able to distinguish between different features in our environment,” said Benjamin Auerbach, a professor of molecular and integrative physiology at the University of Illinois Urbana-Champaign.