Edible Memories? - Bumblebee Solvers - Reward Algorithm - Social Craving

[Breedlove, S]

https://www.quantamagazine.org/are-memories-transferable-or-edible-20260605/

Are Memories Transferable — or Edible?

By Claire L. Evans

It was the dead of winter in Boston. The surface of the Charles River was frozen solid. But Zachary Kelso (opens a new tab) braved the biting cold to finally put to rest a mystery that has haunted neuroscience labs for over half a century.

To do that, Kelso, a research assistant in the Harvard lab of the neuroscientist Sam Gershman (opens a new tab), needed some worms. Specifically, planarians: arrow-headed flatworms, which are among the simplest creatures to possess a brain and a nervous system with bilateral symmetry like ours. Normally, labs order these widely used model organisms from biological supply companies. But the mail-order worms weren’t up to snuff. So Gershman had dispatched Kelso to the Charles’ icy banks to catch some wild ones. “I thought, ‘I’m going to look crazy because I’m using a hammer to beat through the ice,’” Kelso recalled. “So I wore the more business end of business casual.”

In philosophy, “qualia” refers to the subjective qualities of our experience: what it’s like for Alice to see blue or for Bob to feel delighted. Qualia are “the ways things seem to us,” as the late philosopher Daniel Dennett put it. In these essays, our columnists follow their curiosity, and explore important but not necessarily answerable scientific questions.

It wouldn’t be the last time Kelso found himself in this situation. The Charles River planarians, it turned out, didn’t cut it either. Neither did the worms he sourced while stream-hopping around Eugene, Oregon, in March 2025. Nor did the ones he fished from Michigan lakes that June — this time in thigh-high waders — while picnicking families gawked from shore. Kelso diligently turned over rocks, angled with bits of meat tied to a string, and even followed maps from a vintage guidebook called The Fresh-Water Triclads of Michigan (opens a new tab). But his adventure was fruitless. Sure, he caught plenty of planarians. But back in Gershman’s lab, none of them would do what they were supposed to do.

(C) Simons Foundation

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https://www.sciencenews.org/article/bumblebees-problem-solving-spontaneous

 Bumblebees can solve problems on their own

By Erin Garcia de Jesús

Buff-tailed bumblebees can figure out on their own how to use a ball as a ladder to nab sugar from an out-of-reach fake flower, researchers report in the June 4 Science. The insects worked out the trick without specific training for the solution, suggesting a remarkable capacity for solving problems.

Bumblebees are brainy, with studies showing they may have emotions and can teach one another to score goals in a six-legged version of soccer. The new finding adds yet another skill to their repertoire. “Spontaneous problem-solving is something that has never been shown in any invertebrate before,” says Olli Loukola, a behavioral ecologist at the University of Oulu in Finland.

Vertebrates including chimpanzees and parrots can problem solve on their own, although researchers typically focus on captive animals with plenty of experience working out puzzles. “Our study is the first one where we can be 100 percent sure that these individuals don’t have any prior experience about any problem-solving tasks,” Loukola says.

Loukola and colleagues first taught bees two necessary associations: Balls are moveable objects and a blue ring — representing a flower — means food. The team then let the bees loose in plexiglass arenas too small for them to fly to reach a blue ring printed on the ceiling.

© Society for Science & the Public 2000–2026. 
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https://www.thetransmitter.org/systems-neuroscience/reward-learning-algorithm-hardwired-into-dopamine-circuit/

 Reward-learning algorithm hardwired into dopamine circuit

By Natalia Mesa

Dopamine neurons register surprise: Their activity surges when an experience exceeds expectations and falls silent with disappointment. These prediction errors help brains and artificial-intelligence systems learn from experience by updating future expectations, according to a long-standing model. 

But because dopamine neurons receive input from several sources, the exact circuit mechanisms that compute the difference have remained mysterious, says Naoshige Uchida, professor of molecular and cellular biology at Harvard University. 

It turns out that a circuit of just two types of neurons is central to this computation. Dopamine neurons in the ventral tegmental area calculate the error based on input originating from D1 medium spiny neurons in the striatum, according to unpublished mouse data Uchida and his team presented at this year’s Computational and Systems Neuroscience (COSYNE) annual meeting and reported in a preprint posted on bioRxiv in October 2025. 

This result suggests that “reward learning doesn’t necessarily involve higher-order computation,” says Kauê Costa, assistant professor of psychology at the University of Alabama at Birmingham, who was not involved in the work. “The canonical view is that these types of computations would involve higher-order areas.” 

But it also bolsters the reward prediction error model, which has come under scrutiny in recent years, says Nathaniel Daw, professor of computational and theoretical neuroscience at Princeton University, who was not involved in the study. “It’s amazing” how much explanatory power the model has had in predicting neuronal responses, he adds. “It’s been a long road to get here. It’s a really beautiful study.”

© 2026 Simons Foundation

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https://knowablemagazine.org/content/article/mind/2026/why-we-crave-social-interaction

Why we crave company

By Elizabeth Preston

To our human eyes, a mouse’s furred face doesn’t betray much emotion. But if you watch the body language of a mouse who’s reunited with one of her sisters after five days in a cage alone, you might suspect you know what she’s feeling.

The formerly isolated mouse chatters in squeaks too high for a human to hear. She follows her sister, crawling beneath the other mouse’s body as if trying to get a hug. She looks like she’s feeling what you or I feel when meeting a long-lost friend or a family member — maybe with more sniffing.

Loneliness isn’t just for humans, and neither are its harms. Over the past decade or so, some researchers have come to believe that an animal’s craving for the company of others isn’t just a preference, but a basic, deeply held need. When we don’t socialize enough, we feel the lack like hunger or thirst, they say. When we’ve had our fill of togetherness, we feel satisfied or quenched.

The amount of socializing a creature needs may be particular to that species, and even to that individual. Scientists have found within-species social differences in birds, monkeys, fish and even cockroaches.

Among humans, “you can feel lonely at a party, or you can feel fine alone in your office,” says Kay Tye, a neuroscientist at the Salk Institute for Biological Studies in California. Whatever the ideal degree of togetherness, Tye and others think that an animal’s need to balance time alone and time with others represents a kind of homeostasis: an equilibrium that’s critical for survival. Today, they are on a hunt to find where, in the brain, this equilibrium is controlled — and hoping their work will hold dividends for lonely humans.

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