• Waiting Doom
  How hospitals are killing E.R. patients.
  Zachary F. Meisel
  posted July 24, 2008
• Your Health This Week
  Are C-section rates rising because mothers are getting older? And why cholesterol drugs for kids are such a bad idea.
  Sydney Spiesel
  posted July 14, 2008
• The Nose That Never Knows
  The miseries of losing one's sense of smell.
  Elizabeth Zierah
  posted July 8, 2008
• The Sex Difference Evangelists
  The next best-seller.
  Amanda Schaffer
  posted July 7, 2008
• Dr. R2-D2
  The invasion of the surgeon robots.
  Kent Sepkowitz
  posted June 27, 2008
• Search for more medical examiner articles
• Subscribe to the medical examiner RSS feed
• View our complete medical examiner archive

Why Do We Sleep?

Listen to an interview with the author here, or sign up for Slate's free daily podcast on iTunes.

This is the fourth installment of a five-part series.

Marcos Frank's lab at the University of Pennsylvania is set up to eavesdrop on the neurons of young kittens, ferrets, and rats. In one room, an air table (a platform that can be suspended on a cushion of air) provides a vibration-free surface on which to perform surgery, cutting tiny holes in the animals' craniums to expose a portion of their brains. (He uses anesthesia, and the animals don't suffer.) Surrounding the table are surgical probes in Tupperware containers, catheters, gas valves, amplifiers, modified cameras, and an unreasonable thicket of cables—high-tech gear bound up with a rubber band.

When I arrive, Frank, wearing a tan ski cap and jeans, is reassembling a camera. Standing amid its parts, he explains that much of his work is aimed at deciphering how sleep alters brain circuitry, down to the level of individual neurons. In a typical experiment, he modifies the visual inputs that a group of developing animals receive, then allows some animals to sleep while others are kept awake in the dark. Later, he tries to pinpoint minuscule differences in how the animals' brain cells are firing, in response to visual patterns on a screen. This means performing surgery to expose a group of brain cells, then suspending electrodes over particular cells to listen in. "It's like dropping a microphone into a crowd of people, so that you're above one person and listening to what they're saying—although we don't actually know the language," he says.

Frank is an important mediator—and incisive critic—in the debate about sleep and memory. He argues that behavioral researchers are in danger of hitting a "dead end" with contradictory findings on which parts of sleep enhance what kinds of memories. But he also finds fault with cell-level work that associates sleep with a particular molecular or genetic effect but doesn't show how that matters for the animal.

We don't know what the ultimate function of sleep is, Frank says. But many lines of converging evidence now support the idea that sleep promotes brain plasticity—that is, it reinforces changes in the brain brought about by waking experience.

In a set of experiments published in 2001, Frank demonstrated that sleep buttresses changes in the visual cortexes of newborn cats, which in turn change how the cats see. Neuroscientists have long known that if you take a young kitten and block one of its eyes, its brain will beef up the wiring that responds to the open eye. Frank demonstrated that in 1-month-old kittens, sleep heightens this experience. Plasticity can be thought of as a "cellular correlate of memory," he says. In other words, sleep strengthened the cats' neuronal "memory" of having an eye patched. (Since then, Frank has found that neurons need to "talk in their sleep"—that is, they need to be active—for this enhancement to occur.)

Frank's work is impressive. And there is some evidence that the plasticity he observes in the visual systems of baby cats applies to other parts of the brain. Sleep probably has something to do with plasticity throughout life, but its precise role may change as baby brains grow up. There is speculation that early on, REM serves in part as a substitute for external experience, creating a kind of internal sound and light show that helps to ready the brain for experience and set up the foundations of some circuitry. But neuronal wiring is better established in adults, and we may not need this sort of stimulation. Adults spend proportionally less time in REM than babies do. So, perhaps as we age, we simply need less of whatever REM does for the brain during development. Or perhaps sleep serves to promote different kinds of plastic changes in adults—which we also get from non-REM sleep, which increases in adults.

PRINTDISCUSSE-MAIL

• Arts & Life
  If Only Aliens Would Abduct the New X-Files Movie
• Arts & Life
  A Great Horror Film About Paper Bags
• Arts & Life
  Brideshead Revisited Is Literature's Finest Schlock
• Sports
  How Michael Chang Ruined Tennis for Asian-
  Americans

• Today's Headlines
• Can't Go Wrong With A Cheeseburger, Area Man Reports
  Fri, 25 Jul 2008 10:00:21 -0400
• Courageous E-mail To Boss In Drafts Folder Since December
  Fri, 25 Jul 2008 08:00:05 -0400
• Novak Hits Pedestrian With Corvette
  Fri, 25 Jul 2008 07:00:45 -0400
• » More from the Onion

• Today's Headlines
• Poll: Hispanic Voters Back Obama by Wide Margins
  Fri, 25 Jul 2008 02:04:26 GMT
• Opinion: Germans See Themselves in Obama
  Thu, 24 Jul 2008 22:53:52 GMT
• How the Mosley Orgy Ruling Could Affect U.K. Media
  Thu, 24 Jul 2008 20:34:59 GMT
• » More from Newsweek

• Today's Headlines
• Over the Rainbow: Angie and Jo
  Tue, 22 July 2008 16:21:23 GMT
• The New Tavis Smiley, Beware!
  Tue, 22 July 2008 16:27:58 GMT
• Go for the Bronze
  Fri, 25 July 2008 4:18:27 GMT
• » More from The Root