The budgie’s brain contains a cognitive map of human-like vocal sounds

The Budgerigars are some of the most fashionable birds, and it is reflected in their brains. The Budgie Brains contain maps of voice sounds similar to those found in the human brain, not seen in other birds.

“We've seen that parts of the brain have a representation of voice sounds similar to the important speech areas of the human brain,” he says. Michael Long in Grossmann School of Medicine, New York University.

Budgerigars (Melopstitacus undulatus), also known as a paraquiet, is a small parrot native to Australia. They are epic vocal learners and can mimic a variety of sounds, including human speech. The boudgie, known as the pack, had a vocabulary of about 1,728 words. According to the Guinness World Records. “The ability to mimic phonetically is very rare in the animal kingdom,” Long says.

and Zetian Yang, Additionally, NYU medical schools used silicon probes for a long time to record electrical activity in the Budgies' brains. They focused on a part of the forebrain, the central nucleus of the forebrain horn, which was known to be involved in motor control of vocalization. When Budgies made the call, Long and Yang tracked how their electrical activity had changed.

“Our research was the first to measure parrot brain activity during vocalization,” Long says.

The pair discovered neurons in the central nucleus of the anterior horn thyroid. “There are cells that are active because of consonants,” Long says. Others make vowels, but some are active for high-pitched sounds, others for low pitch.

This brain structure is compared to a keyboard. “There's this kind of key, or in this case, a set of brain cells, and you can represent each of these vocal outcomes and play whatever it wants,” he says. “What the parrot presented is this beautiful and elegant solution to creating vocal sounds.” The human brain has a similar vocal map.

Long and Yang repeated the experiment with a zebra finch (taeniopygia guttata), not vocal mimic. “They have one song they learn,” Long says. “It's about two seconds, sometimes less.” It takes several months to perfect.

Unlike the Budgerigars, the Zebra Finch showed no signs of a “map” of the sound of the brain's voice. Instead, “A Zebra Finch develops chords that are almost almost inexplicable for this song,” says Long. He says that Budgie's brain uses a simple, intuitive system to generate complex calls, while Zebra Finch Brain uses a complex system to make something simple.

“It shows that neural activity and associated vocal behavior are closer to parrots and humans than songbirds and parrots.” Erich Jarvis At Rockefeller University in New York.

“Almost everything we know about the detailed mechanistic basis of learned vocalization comes from several species of songbirds singing relatively simple songs.” Jesse Goldberg At Cornell University in New York. “The parrot therefore offers an incredible opportunity to study both the mechanisms and evolution of complex vocal learning and production.”

I say there are several reasons why I evolved imitation. Zhilei Zhao At Cornell University. One is courtship. “Women actually prefer men with the ability to copy,” he says, and if a man loses his ability, “they are more likely to fool him.” Also, the Budgies have a very dynamic social life. “Form small groups for several days.” Once the group is established, members begin to create unique “contact calls.” “People think it might be something like a password for this group,” says Zhao.

Other skilled mimics may have similar vocal maps in their brains. “My very strong speculation is that other parrots have the same functionality, but they are simply not explored.” He also doubts something similar, the Lyrebirds, a phenomenal mimic that can even mimic artificial sounds like camera shutters.

In the long run, I hope that studying how boudgies produce sounds for a long time will help people understand language disorders. People with strokes often experience aphasia. I can't call the correct words in my head. “You reach for those words and it’s not there,” Long says. “Now we have the opportunity to fight to understand what we think is at the root of many communication disorders that affect people in devastating ways.”