Mammals dream about the world they are entering even before birth

“It’s like dreaming about what you are going to see before you even open your eyes.”

Imagine opening your eyes for the first time as a brand new baby. The world is so mysterious, full of obstacles and strange shapes. And yet it does not take babies all that long to get their bearings, to latch on to their parents, and to start interacting. How do they do this so quickly? A new study published in Science proposes that babies of mammals dream about the world they are about to enter before being born, developing important skills.

The team, led by professor Michael Crair, who specializes in neuroscience, ophthalmology, and visual science, wanted to understand why when mammals are born, they are already somewhat prepared to interact with the world.

“At eye opening, mammals are capable of pretty sophisticated behavior,” said Craig, “But how do the circuits form that allow us to perceive motion and navigate the world? It turns out we are born capable of many of these behaviors, at least in rudimentary form.”

Unusual retinal activity

The scientists observed waves of activity radiating from the retinas of newborn mice before their eyes first open. Imaging shows that soon after birth, this activity disappears. In its place matures a network of neural transmissions that carries visual stimuli to the brain, as explained by a Yale press release. Once it reaches the brain, the information is encoded for storage.

What’s particularly unusual about this neonatal activity is that it demonstrates a pattern that would happen if the animal was moving forward somewhere. As the researchers write in the study, “Spontaneous waves of retinal activity flow in the same pattern as would be produced days later by actual movement through the environment.”

Crair explained that this “dream-like activity” makes sense from an evolutionary standpoint, as it helps the mouse get ready for what will happen to it after it opens its eyes. It allows the animal to “respond immediately to environmental threats,” Crair shared.

What is creating the waves?

The scientists also probed what is responsible for creating the retinal waves that mimic the forward motion. They turned on and off the functionality of starburst amacrine cells — retinal cells that release neurotransmitters — and discovered that blocking them stopped the retinal waves from flowing, which hindered the mouse from developing the ability to react to visual motion upon birth. These cells are also important to an adult mouse, affecting how it reacts to environmental stimuli.

Graphic showing the origin and functionality of directional retinal waves.

What about human babies?

While the study focused on mice, human babies also seem to be able to identify objects and motion right after birth. This suggests the presence of a similar phenomenon in babies before they are born.

“These brain circuits are self-organized at birth and some of the early teaching is already done,” Crair stated. “It’s like dreaming about what you are going to see before you even open your eyes.”

This article was reprinted with permission of Big Think, where it was originally published.

Related
Farmers can fight invasive insects with AI and a robotic arm
As the invasive spotted lanternfly threatens to expand its range, Carnegie Mellon researchers are developing a robot to fight back.
How intestinal viruses could help you live to be 100
People who live past age 100 have a greater diversity of bacteriophages (that is, viruses that infect bacteria) in their intestines.
Model human embryo, created from stem cells, survives past two weeks
A model human embryo capable of developing past day 14 could revolutionize our understanding of human development.
Have we got the brain all wrong? Study shows its shape is more important than its wiring
Neural activity may be more influenced by the shape of the brain – its grooves, contours, and folds – than by its complex interconnections.
Flexible brain implant tested in people for the first time
Startup Precision Neuroscience has tested its flexible, ultra-thin brain implants in people for the first time.
Up Next
Subscribe to Freethink for more great stories