OT? How our brains react to music.

[John Musselwhite]

I'm sure we all agree that music is a wonderful thing, but this is too cool!
  ____________________________________________

A song in your head: Brainwaves Researchers at McGill University are using 
very fancy devices to learn how our brains react to music, writes Paul McKay.

Paul McKay The Ottawa Citizen Monday, November 18, 2002 CREDIT: Christinne 
Muschi, The Ottawa Citizen


Sex. Chocolate. Caffeine. Champagne. Cocaine.

If none of the above turn your cranial crank, it's also likely that Mozart 
or Alanis Morissette won't send shivers down your spine. And that your 
pulse rate should be checked by a doctor -- because the human survival 
instinct is hard-wired to the same brain circuits that process intense 
pleasure.

A team of researchers at the Montreal Neurological Institute, using the 
world's most advanced brain-mapping machines, have found that the same 
neural clusters that process the seductive pleasures of sex, chocolate and 
even hard drugs also fire up for music.

There is also persuasive evidence that the brain tends to prune these 
neural circuits for maximum pleasure the way a gardener cuts unproductive 
branches to make a rose bush bloom. Music, it seems, may make the brain 
bloom best because it literally electrifies, at lightning speed, a web of 
nerve paths in both hemispheres of our cerebral cortex that connect the 
neural clusters processing musical pitch, rhythm, harmony, melody, short 
term memory, long term memory, and emotions. Now, for the first time, 
neuroscientists mapping the musical mind at McGill University have 
confirmed that those music circuits also comprise the inch-worm shaped 
clusters that process exquisite pleasures, including illicit ones. But 
unlike other addictions, it leaves no hangover, drug habits, clogged 
arteries, or sexual diseases.

Sound too good to be true? If it is, billions of brain cells, a $6-million 
MRI imaging machine, and a leading cognitive neuroscientist are all wrong.

Robert Zatorre and his colleagues at McGill University have been heading 
studies into the effects of music on the human brain for more than two 
decades. Deep in the bowels of an old stone building on the McGill campus, 
they scan human brains the way a geologist scans mineral maps, except they 
are tracing, in real time, the topography of human brains while circuits 
and clusters of neurons fire.

They and their international colleagues have used sophisticated PET and MRI 
scanners to peer inside brains to detect where pitch, melody, harmony and 
rhythm are processed. The answer, it turns out, changes with the complexity 
and composition of the music. There are distinct clusters of cortex that 
seem to be responsible for each component of music, such as rhythm or 
harmony. Yet even the simplest song heard or sung by a child sends showers 
of neural sparks across both sides of the brain, linking each element of 
music to respective cranial regions. Music also lights up the lobes where 
memory is stored, the clusters where logic and speech are processed, the 
brain stem where sounds relayed by the ear are filtered, and the cerebral 
throne of emotion.

The brain even processes harmonic and dissonant music in different neural 
circuits.

For a landmark study published last year, Zatorre's McGill team created an 
experiment with remarkable results. Ten students, each with advanced 
musical training, were asked to select a favourite piece of music. Among 
the selections were Samuel Barber's Adagio for Strings and Rachmaninoff's 
Piano Concerto No. 3 in D minor.

Each of the subjects was played an excerpt from their favoured music while 
they were scanned for brain neuron firing, cranial blood flow, heart rate, 
EMG, respiration and skin temperature. All 10 subjects were also played an 
excerpt from another student's selection, a calibrated patch of ordinary 
noises, and a passage of silence.

Sure enough, chills tingled down the students spines as they heard their 
favourite music selections. Their other vital signs spiked upwards during 
77 per cent of the scans. But the real discovery came as the 
computer-linked scanner/ cameras took split-second snapshots through the 
multiple folds and mounds of grey matter: Blood flowed to areas where 
neurons fired in galaxies of electro-chemical energy bursts, but away from 
areas where brain neurons were relatively dormant.

During the moments of musical euphoria, their cranial blood streamed to the 
parts of the brain which previous, independent studies had isolated as the 
places where sex, chocolate, champagne or cocaine can produce ecstasy. In 
effect, 10 different cortex clusters burst into neural fireworks, creating 
the familiar spine-tingling chills of pleasure. Equally intriguing, the 
blood flowed away from brain cells associated with depression and fear.

"We have shown that music recruits neural systems of reward and emotion 
similar to those known to respond specifically to biologically relevant 
stimuli, such as food and sex, and those artificially activated by drugs of 
abuse," Zatorre concluded in his published paper. "This is quite 
remarkable, because music is neither strictly necessary for biological 
survival or reproduction, nor is it a pharmacological substance."

Our brain neurons, says Zatorre, are hard-wired for music -- from cradle to 
grave. And the more we use 'em, the less we lose 'em.

"All normal children will spontaneously sing something like the Sesame 
Street song," he says in his McGill office while fielding phone calls to 
book precious time on an MRI machine -- which costs $400 per hour, and 
primarily is used to scan patients. "That's a very sophisticated 
neurological feat. It means their brains recognize the theme, and associate 
it with their favourite TV show. They will try to sing it, on their own. 
They may not reproduce it very accurately, but it is recognizable. No one 
can teach them this, versus reading or math. Like blind children learning 
to walk, they just do it when they are ready. It is wired into our nervous 
system.

"The vast majority of people with no musical training can sing a song, and 
still recognize a tune when it has been altered by a different key, 
instrument or rhythm. That seems to be innate, something our brains are 
wired to do. And there is no known culture which does not have some sort of 
music."

The Zatorre study followed earlier McGill probes into how harmony and 
dissonance affect the neural clusters known to process emotions; where in 
the brain we select key features of voices; how people process melodies; 
where musical pitch and rhythm are processed; and where the mind's eye 
imagines and perhaps invents music.

The brain's chief task, Zatorre concludes, is to keep astonishing itself. 
And music may do it best.

"Music involves perception, memory, emotion, motor control, all the 
learning aspects. It brings together a lot of different functions in a very 
coherent way," says Zatorre, who is also an accomplished organist. "The 
brain wants patterns to assemble but it also craves diversity, so a very 
important part of music is surprise. And you can only be surprised if you 
anticipate - and don't assume a random series of notes."

"The best music plays with that tension. If it goes too far in lacking 
structure, it collapses into random sounds. Then your nervous system loses 
interest; it just becomes noise. If you go too far to the other extreme, 
where everything is completely predictable, soon you'll never play it 
again. The brain likes to be challenged."

Zatorre and Isabel Peretz, a noted neuropsychologist at the University of 
Montreal (see accompanying story) collaborate on complementary studies, and 
assembled a newly published compilation of academic reports called The 
Biological Foundations of Music. It summarizes much of the past decade's 
international research into the origins of human music, particularly 
neurological evidence uncovered by brain scanning technology and related 
experiments.

That text is augmented by continuing studies of the musical mind at 
universities in Montreal, Toronto, Boston, California, and Europe. 
Published in scientific journals and posted on university and medical 
school Web sites, they reveal alluring evidence that:

- The brains of musicians, especially those who begin dedicated practice 
before age 7, have larger neural clusters involving music processing such 
as the neural region that directs a violinist's hands -- sound perception 
and discrimination begins before birth, and neurons begin firing before 
language skills develop in infants, aided by parental cooing and lullabies.

- The brain selects the most efficient neural highways to process music, 
closing those that create musical traffic jams and opening those that make 
sounds flow faster. The more these circuits are used, the more their 
musical range and capacity expands. Both hemispheres of the brain share 
music processing functions and are connected by a key neural bridge, the 
corpus callosum, which unites specialized regions sending complex musical 
data at blinding speeds. Recent studies indicate the 100 million-nerve 
conduit is up to 15 per cent larger in musicians trained since age eight.

- Music acts as a specialized fuel to fire millions of brain nerves that 
otherwise remain dormant or undeveloped. As the brain burns musical fuel, 
it creates chemicals that produce contentment and even ecstasy. Recent 
studies of choir singers show elevated levels of these after performances.

"The PET and MRI scans only became available in the last two decades," says 
Zatorre. "They have really revolutionized the whole field of cognitive 
neuroscience -- the study of the brain mechanisms that allow us to perceive 
and think and act and reason and remember. They allow us to probe the 
workings of the brain in normal people. Before we had to rely exclusively 
on those with brain damage."

Asked to summarize what brain circuits are deployed when humans process 
music, Zatorre momentarily jettisons his meticulous scientific caution and 
flashes a grin.

"Everything from the neck up." he answers.

Paul McKay is a Citizen reporter. More music and photos for this story, and 
previous stories in this series, can be seen at www.enchantedear.com 
<http://www.enchantedear.com> .

More details about the Zatorre/McGill studies can be found at 
www.zlab.mcgill.ca <http://www.zlab.mcgill.ca> ..

© Copyright 2002 The Ottawa Citizen