Your Child's Brain
You hold your
newborn so his sky blue eyes are just inches from the brightly patterned
ZZZt: a neuron from his
retina makes an electrical connection with one in his brain’s visual
cortex. You gently touch his palm
with a clothespin; he grasps it, drops it, and you return it to him with
soft words and a smile.
Crackle: neurons from his
hand strengthen their connection to those in his sensory-motor cortex.
He cries in the night; you feed him, holding his gaze because
nature has seen to it that the distance from a parent’s crooked elbow to
his eyes exactly matches the distance at which a baby focuses.
Zap: neurons in the
brain’s amygdala send pulses of electricity through the circuits that
control emotion. You hold him on
your lap and talk….and neurons from his ears start hard wiring
connections to the auditory cortex.
thought you were just playing with your kid.
When a baby
comes into the world her brain is a jumble of neurons, all waiting to be
woven into the intricate tapestry of the mind.
Some of the neurons have already been hard-wired, by the genes in
the fertilized egg, into circuits that command breathing or control
heartbeat, regulate body temperature or produce reflexes.
But trillions upon trillions more are like Pentium chips in a
computer before the factory preloads the software.
They are pure and of almost infinite potential, unprogrammed
circuits that might one day compose rap songs and do calculus, erupt in
fury and melt in ecstasy. If the
neurons are used, they become integrated into the circuitry of the brain
by connecting to other neurons; if they are not used, they may die.
It is the experiences of childhood, determining which neurons are
used, that wire the circuits of the brain as surely as a programmer at a
keyboard reconfigures the circuits in a computer.
Which keys are typed – which experiences a child has – determines
whether the child grows up to be intelligent or dull, fearful or
self-assured, articulate or tongue-tied.
Early experiences are so powerful, says pediatric nuerobiologist
Harry Chugani of Wayne State University, that “they can completely
change the way a person turns out.”
the brain is crisscrossed with more than 100 billion neurons, each
reaching out to thousands of others so that, all told, the brain has
more than 100 trillion connections.
It is those connections – more than the number of galaxies in the
known universe – that give the brain its unrivaled powers.
The traditional view was that the wiring diagram is
predetermined, like one for a new house, by the genes in the fertilized
egg. Unfortunately, even though
half the genes – 50,000 – are involved in the central nervous system in
some way, there are not enough of them to specify the brain’s
incomparably complex wiring. That
leaves another possibility: genes might determine only the brain’s main
circuits, with something else shaping the trillions of finer
connections. That something else
is the environment, the myriad messages that the brain receives from the
outside world. According to the
emerging paradigm, “there are two broad stages of brain wiring,” says
developmental neurobiologist Carla Shatz of the University of Calfornia,
Berkeley: “an early period, when experience is not required, and a later
one, when it is.”
wired, there are limits to the brain’s ability to create itself.
Time limits. Called
“critical periods,” they are windows of opportunity that nature flings
open, starting before birth, and then slams shut, one by one, with every
additional candle on the child’s birthday cake.
In the experiments that gave birth to this paradigm in the 1970s,
Torsten Wiesel and David Hubel found that sewing shut one eye of a
newborn kitten rewired its brain: so few neurons connected from the shut
eye to the visual cortex that the animal was blind even after its eye
was reopened. Such rewiring did
not occur in adult cats whose eyes were shut.
Conclusion: there is a
short, early period when circuits connect the retina to the visual
cortex. When brain regions mature
dictates how long they stay malleable.
Sensory areas mature in early childhood; the emotional limbic
system is wired by puberty; the frontal lobes – seat of understanding –
develop at least through the age of 16.
implications of this new understanding are at once promising and
disturbing. They suggest that,
with the right input at the right time, almost anything is possible.
But they imply, too, that if you miss the window you’re playing
with a handicap. They offer an
explanation of why the gains a toddler makes in Head Start are so often
evanescent: this intensive instruction begins too late to fundamentally
rewire the brain. And they make
clear the mistake of postponing instruction in a second language.
As Chugani asks, “What idiot decreed that foreign-language
instruction not begin until high school?”
Neurobiologists are still at the dawn of understanding exactly what kids
of experiences, or sensory input, wire the brain in which ways.
They know a great deal about the circuit for vision.
It has a neuron-growth spurt at the age of 2 to 4 months, which
corresponds to when babies start to really notice the world, and peaks
at 8 months, when each neuron is connected to an astonishing 15,000
other neurons. A baby whose eyes
are clouded by cataracts from birth will, despite cataract-removal
surgery at the age of 2, be forever blind.
For other systems, researchers know what happens, but not – at
the level of neurons and molecules – how.
They nevertheless remain confident that cognitive abilities work
much like sensory ones, for the brain is parsimonious in how it conducts
its affairs: a mechanism that
works fine for wiring vision is not likely to be abandoned when it comes
to circuits for music. “Connects
are not forming willy-nilly,” says Dale Purves of Duke University, “but
are promoted by activity.”
Before there are words, in the world of a newborn, there are
sounds. In English they are
phonemes such as sharp ba’s and da’s, drawn-out ee’s and ll’s and
sibilant sss’s. In Japanese they
are different – barked hi’s,
merged rr/ll’s. When a child
hears a phoneme over and over, neurons form his ear stimulate the
formation of dedicated connections in his brain’s auditory cortex.
This “perceptual map,” explains Patricia Kuhl of the University
of Washington, reflects the apparent distance – and thus the similarity
– between sounds. So in
English-speakers, neurons in the auditory cortex that respond to “ra”
lie far from those that respond to “la.”
But for Japanese, where the sounds are nearly identical, neurons
that respond to “ra” are practically intertwined, like L.A. freeway
spaghetti, with those for “la.”
As a result, a Japanese-speaker will have trouble distinguishing the two
find evidence of these tendencies across many languages.
By 6 months of age, Kuhl reports, infants in English-speaking
homes already have different auditory maps (as shown by electrical
measurements that identify which neurons respond to different sounds)
from those in Swedish-speaking homes.
Children are functionally deaf to sounds absent from their native
tongue. The map is completed by
the first birthday. “By 12
months,” says Kuhl, “infants have lost the ability to discriminate
sounds that are not significant in their language, and their babbling
has acquired the sound of their language.”
Kuhl’s findings help explain why learning a second language after, rather than with, the first is so difficult. “The perceptual map of the first language constrains the learning of a second,” she says. In other words, the circuits are already wired for Spanish, and the remaining undedicated neurons have lost their ability to form basic new connections for, say, Greek. A child taught a second language after the age of 10 or so is unlikely ever to speak it like a native. Kuhl’s work also suggests why related languages such as Spanish and French are easier to learn than unrelated ones: more of the existing circuits can do double duty.
With this basic circuitry established, a baby is primed to turn sounds into words. The more words a child hears, the faster she learns language, according to psychiatrist Janellen Huttenlocher of the University of Chicago. Infants whose mothers spoke to them a lot knew 131 more words at 20 months than did babies of more taciturn, or less involved, mothers; at 24 months, the gap had widened to 295 words. (Presumably the findings would also apply to a father if he were the primary caregiver.) It didn’t matter which words the mother used – monosyllables seemed to work. The sound of words, it seems, builds up neural circuitry that can then absorb more words, much as creating a computer file allows the user to fill it with prose. “There is a huge vocabulary to be acquired,” says Huttenlocher, “and it can only be acquired through repeated exposure to words.”
Music: Last October researchers at the University of Konstanz in Germany reported that exposure to music rewires neural circuits. In the brains of nine string players examined with magnetic resonance imaging, the amount of somatosensory cortex dedicated to the thumb and fifth finger of the left hand – the fingering digits – was significantly larger than in nonplayers. How long the players practiced each day did not affect the cortical map. But the age at which they had been introduced to their muse did: the younger the child when she took up an instrument, the more cortex she devoted to playing it.
Like other circuits formed early in life, the ones for music endure. Wayne State’s Chugani played the guitar as a child, then gave it up. A few years ago he started taking piano lessons with his young daughter. She learned easily, but he couldn’t get his fingers to follow his wishes. Yet when Chugani recently picked up a guitar, he found to his delight that “the songs are still there,” much like the muscle memory for riding a bicycle.
Math and logic: At UC Irvine, Gordon Shaw suspected that all higher-order thinking is characterized by similar patterns of neuron firing. “If you’re working with little kids,” says Shaw, “you’re not going to teach them higher mathematics or chess. But they are interested in and can process music.” So Shaw and Frances Rauscher gave 19 preschoolers piano or singing lessons. After eight months, the researchers found, the children “dramatically improved in spatial reasoning,” compared with children given no music lessons, as shown in their ability to work mazes, draw geometric figures and copy patterns of two-color blocks. The mechanism behind the “Mozart effect” remains murky, but Shaw suspects that when children exercise cortical neurons by listening to classical music, they are also strengthening circuits used for mathematics. Music, says the UC team, “excites the inherent brain patterns and enhances their use in complex reasoning tasks.”
Emotions: The trunk lines for the circuits controlling emotion are laid down before birth. Then parents take over. Perhaps the strongest influence is what psychiatrist Daniel Stern calls attunement – whether caregivers “play back a child’s inner feelings.” If a baby’s squeal of delight at a puppy is met with a smile and a hug, if her excitement at seeing a plane overhead is mirrored, circuits for these emotions are reinforced. Apparently, the brain uses the same pathways to generate an emotion as to respond to one. So if an emotion is reciprocated, the electrical and chemical signals that produced it are reinforced. But if emotions are repeatedly met with indifferences or a clashing response – Baby is proud of building a skyscraper out of Mom’s best pots, and Mom is terminally annoyed – those circuits become confused and fail to strengthen. The key here is “repeatedly”: one dismissive harrumph will not scar a child for life. It’s the pattern that counts, and it can be very powerful: in one of Stern’s studies, a baby whose mother never matched her level of excitement became extremely passive, unable to feel excitement or joy.
Experience can also wire the brain’s “calm down” circuit, as Daniel Goleman describes in his best-selling “Emotional Intelligence.” One father gently soothes his crying infant, another drops him into his crib; one mother hugs the toddler who just skinned her knee, another screams “It’s your own stupid fault!” The first responses are attuned to the child’s distresses; the others are widely out of emotional sync. Between 10 and 18 months, a cluster of cells in the rational prefrontal cortex is busy hooking up to the emotion regions. The circuit seems to grow into a control switch, able to calm agitation by infusing reason into emotion. Perhaps parental soothing trains this circuit, strengthening the neural connections that form it, so that the child learns how to calm herself down. This all happens so early that the effects of nurture can be misperceived as innate nature.
Stress and constant threats also rewire emotion circuits. These circuits are centered on the amygdala , a little almond shaped structure deep in the brain whose job is to scan incoming sights and sounds for emotional content. According to a wiring diagram worked out by Joseph LeDoux of New York University, impulses from eye and ear reach the amygdala before they get to the rational, thoughtful neocortex. If a sight, sound or experience has proved painful before – Dad’s drunken arrival home was followed by a beating – then the amygdala floods the circuits with neurochemicals before the higher brain knows what’s happening. The more often this pathway is used, the easier it is to trigger: the mere memory of Dad may induce fear. Since the circuits can stay excited for days, the brain remains on high alert. In this state, says neuroscientist Bruce Perry of Baylor College of Medicine, more circuits attend to nonverbal cues – facial expressions, angry noises – that warn of impending danger. As a result, the cortex falls behind in development and has trouble assimilating complex information such as language.
Movement: Fetal movements begin at 7 weeks and peak between the 15th and 17th weeks. That is when regions of the brain controlling movement start to wire up. The critical period lasts a while: it takes up to two years for cells in the cerebellum, which controls posture and movement, to form functional circuits. “A lot of organization takes place using information gleaned from when the child moves about in the world,” says William Greenough of the University of Illinois. “If you restrict activity you inhibit the formation of synaptic connections in the cerebellum.” The child’s initially spastic movements send a signal to the brain’s motor cortex; the more the arm, for instance, moves, the stronger the circuit, and the better the brain will become at moving the arm intentionally and fluidly. The window lasts only a few years: a child immobilized in a body cast until the age of 4 will learn to walk eventually, but never smoothly.
There are many more circuits to discover, and many more environmental influences to pin down. Still, neuro labs are filled with an unmistakable air of optimism these days. It seems from a growing understanding of how, at the level of nerve cells and molecules, the brain’s circuits form. In the beginning, the brain-to-be consists of only a few advance scouts breaking trail: within a week of conception they march out of the embryo’s “neural tube,” a cylinder of cells extending from head to tail. Multiplying as they go (the brain adds an astonishing 250,000 neurons per minute during gestation), the neurons clump into the brain stem which commands heartbeat and breathing, build the little cerebellum at the back of the head which controls posture and movement, and form the grooved and rumpled cortex wherein thought and perception originate. The neural cells are so small, and the distance so great, that a neuron striking out for what will be the prefrontal cortex migrates a distance equivalent to a human’s walking from New York to California, says developmental neurobiologist Mary Beth Hatten of Rockefeller University.
Only when they reach their destinations do these cells become true neurons. They grow a fiber called an axon that carries electrical signals. The axon might reach only to a neuron next door, or it might wend its way clear across to the other side of the brain. It is the axonal connections that form the brain’s circuits. Genes determine the main highways along which axons travel to make their connection. But to reach particular target cells, axons follow chemical cues strewn along their path. Some of these chemicals attract: this way to the motor cortex! Some repel: no, that way to the olfactory cortex. By the fifth month of gestation most axons have reached their general destination. But like the prettiest girl in the bar, target cells attract way more suitors – axons – than they can accommodate.
How does the wiring get sorted out? The baby neurons fire electrical pulses once a minute, in a fit of what Berkeley’s Shatz calls auto-dialing. If cells fire together, the target cells “ring” together. The target cells then release a flood of chemicals, called trophic factors, that strengthen the incipient connections. Active neurons respond better to trophic factors than inactive ones, Barbara Barres of Stanford University reported in October. So neurons that are quiet when others throb lose their grip on the target cell. “Cells that fire together wire together,” says Shatz.
The same basic process continues after birth. Now, it is not an auto-dialer that sends signals, but stimuli from the senses. In experiments with rats, Illinois’s Greenough found that animals raised with playmates and toys and other stimuli grow 25 percent more synapses than rats deprived of such stimuli.
Rats are not children, but all evidence suggests that the same rules of brain development hold. For decades Head Start has fallen short of the high hopes invested in it: the children’s IQ gains fade after about three years. Craig Ramey of the University of Alabama suspected the culprit was timing: Head Start enrolls 2-,3-, and 4-year-olds. So in 1972 he launched the Abecedarian Project. Children from 120 poor families were assigned to one of four groups: intensive early education in a day-care center from about 4 months to age 8, from 4 months to 5 years, from 5 to 8 years, or none at all. What does it mean to “educate” a 4-month-old? Nothing fancy: blocks, beads, talking to him, playing games such as peek-a-boo. As outlined in the book “Learninggames,” (by Joseph Sparling and Isabelle Lewis – 226 pages. Walker. $8.95) each of the 200-odd activities was designed to enhance cognitive, language, social or motor development. In a recent paper, Ramey and Frances Campbell of the University of North Carolina report that children enrolled in Abecedarian as preschoolers still scored higher in math and reading at the age of 15 than untreated children. The children still retained an average IQ edge of 4.6 points. The earlier the children were enrolled, the more enduring the gain. And intervention after age 5 conferred no IQ or academic benefit.
All of which raises a troubling question. If the windows of the mind close, for the most part, before we’re out of elementary school, is all hope lost for children whose parents did not have them count beads to stimulate their math circuits, or babble to them to build their language loops? At one level, no: the brain retains the ability to learn throughout life, as witness anyone who was befuddled by Greek in college only to master it during retirement. But on a deeper level the news is sobering. Children whose neural circuits are not stimulated before kindergarten are never going to be what they could have been. “You want to say that it is never too late,” says Joseph Sparling, who designed the Abecedarian curriculum. “But there seems to be something very special about the early years.”
And yet…..there is new evidence that certain kinds of intervention can reach even the older brain and, like a microscopic screwdriver, rewire broken circuits. In January, scientists led by Paula Tallal of Rutgers University and Michael Merzenich of UC San Francisco described a study of children who have “language-based-learning disabilities” – reading problems. LLD affects 7 million children in the United States. Tallal has long argued that LLD arises from a child’s inability to distinguish short, staccato sounds – such as “d” and “b.” Normally, it takes neurons in the auditory cortex something like 0.015 second to respond to a signal from the ear, calm down and get ready to respond to the next sound; in LLD children, it takes five to 10 times as long. (Merzenich speculates that the defect might be the result of chronic middle-ear infections in infancy: the brain never “hears” sounds clearly and so fails to draw a sharp auditory map.) Short sounds such as “b” and “d” go by too fast – 0.04 second – to process. Unable to associate sounds with letters, the children develop reading problems.
The scientists drilled the 5- to 10-year olds three hours a day with computer produced sound that draws out short consonants like an LP played too slow. The result: LLD children who were one to three years behind in language ability improved by a full two years after only four weeks. The improvement has lasted. The training, Merzenich suspect, redrew the wiring diagram in the children’s auditory cortex to process fast sounds. Their reading problems vanished like the sounds of the letters that, before, they never heard.
Such neural rehab may be the ultimate payoff of the discovery that the experiences of life are etched in the bumps and squiggles of the brain. For now, it is enough to know that we are born with a world of potential – potential that will be realized only if it is tapped. And that is challenge enough.
"Let us come before Him with thanksgiving and extol Him with music and song." Psalms 95:2
"Shout for joy to the Lord, all the earth, burst into jubilant song with music." Psalms 98:4