This is data on the mind that most of us do not perceive at all. So far it is an instructive phenomenum with no obvious application as yet. I do think it is going to turn out to be useful.
I am now well aware that we fail to properly perceive the blue end of the spectrum. What we do perceive is that part filtered out by the physical atom,s and molecules of the atmosphere instead. Our brain effectively uses that as an observational standard and ignores parts of the spectrum close by leaving us effectively blind to the world of spirit.
It would be really handy to attach mental trigger words to unobserved parts of the spactrum that allowed them to be perceived on demand..
.
.
A circus of the senses
It makes letters colourised and numbers pulsate with cosmic time: a rare gift, or are we all on the synaesthetic spectrum?
http://aeon.co/magazine/psychology/are-we-all-born-with-synaesthesia/
Vladimir Nabokov once called his famed fictional creation Lolita ‘a
little ghost in natural colours’. The natural colours he used to paint
his ‘little ghost’ were especially vivid in part because of a
neurological quirk that generated internal flashes of colour whenever
letters of the alphabet appeared within his mind. In his memoir Speak Memory (1951), he described a few of them: ‘b has the tone called burnt sienna by painters, m is a fold of pink flannel, and today I have at last perfectly matched v with “Rose Quartz” in Maerz and Paul’s Dictionary of Color’.
The condition he had was synaesthesia, a neurological oddity that mixes
up the senses, making those who possess it see as well as hear music,
or taste the shapes they set their eyes upon.
Synaesthetes such as Nabokov see letters and numbers wreathed in
fixed, seemingly idiosyncratic colours. Grapheme-colour synaesthesia,
the term for this variety, is the most common sub-type of synaesthesia,
occurring among four people in 100. It’s also the most widely studied.
Other common varieties are chromaesthesia, in which tones or notes set
off flashes of colour and a symphonic wall of sound can summon a
three-dimensional landscape, and spatial-sequence synaesthesia, in which
seconds, weekdays, months or years encircle those who experience it,
like planetary rings. Some have lexical-gustatory synaesthesia, which
lends every word or name a strong, specific taste, making some
delicious, and others too bitter to utter. Still other synaesthetes
report ordinal-linguistic personification, in which they ascribe
distinct genders, colours or personality types to letters and numbers:
‘4’ might be an ill-tempered, ungenerous man, constantly heckling his
wife, while ‘6’ turns out to be a dignified, genteel woman with
exquisite manners.
Nothing could be more intensely subjective or taken-for-granted than
the ineffable way that each of us perceives the world. This is why many
synaesthetes go through a lifetime without realising that their everyday
sense experience is exceptional or strange. Those who do, report a
moment of startled self-awareness when friends respond with an
uncomprehending: ‘What do you mean, my name tastes of split-pea soup?’
Such eureka moments have grown increasingly common since the 1980s, when
cognitive tests were first developed to judge the authenticity of the
reports through to the mid-1990s, when brain scans and brain-wave
measurements began tracking the physiology of synaesthesia’s various
forms. Writing in The Oxford Handbook of Synesthesia in 2013,
Richard Cytowic, a neurologist and synaesthesia researcher at George
Washington University, describes the ‘astonishment and enthusiasm’
reported by synaesthetes after tests validated that they weren’t ‘making
it all up’.
As an increasing number of synaesthetes recognise for the first time
that they are unusual, new forms of the phenomenon emerge. In 2008, two
neuroscientists at the University of California, San Diego,
V S Ramachandran and his then-student David Brang, stumbled on the first
recorded ‘tactile-emotion’ synaesthete: a young woman who reacted
viscerally to textures. Her eureka moment occurred when she told Brang
how she’d cry as a child every time her parents dressed her in denim,
which repulsed and depressed her. The feel of wax, on the other hand,
deeply embarrassed her, while silk left her in a state of gurgling
contentment.
Researchers have also realised that one individual can experience
different forms of synaesthesia. The same person who feels revolted by a
texture can see letters and numbers swathed in colours. It’s common for
synaesthesia to recur within families. Nabokov’s father and mother saw
letters and numbers tinted in hues, and his mother also saw clouds of
colours accompany the music she heard. Nabokov’s wife Véra and their son
Dmitri shared the same version of synaesthesia he and his parents had –
grapheme‑colour synaesthesia. As Nabokov put it: ‘One letter which he
[Dmitri] sees as purple, or perhaps mauve, is pink to me and blue to my
wife. This is the letter M. So the combination of pink and blue makes
lilac in his case. Which is as if genes were painting in aquarelle.’
But now it turns out that synaesthetes
might not belong to a club as exclusive as once thought. Their rich
palette and vivid sensations might be accessible to us all. Even though
not kin to Nabokov, we too could be reading our books in aquarelle. The
under-examined complexities of ordinary perception, some neuroscientists
and developmental psychologists contend, suggest that, like the
Nabokovs, we all inhabit the synaesthetic spectrum – we just need to
look back in time, to when we were infants with developing brains.
The first glimmer of this idea appeared in a thought experiment in Emile
(1762), a novel by the Enlightenment-era philosopher Jean-Jacques
Rousseau. He hypothesised that a child born fully grown, the size of a
man and with the faculties of a baby, would have the barest amount of
self-awareness and mingled sense-impressions, amounting to a muddled
proto-synaesthesia. Rousseau wrote: ‘His eye would not perceive colour,
his ear sounds, his body would be unaware of contact with neighbouring
bodies, he would not even know he had a body. All his sensations would
be united in one place, they would exist only in the common
“sensorium”.’
In 1818, this idea inspired Mary Shelley’s description of the early
sensory experience of another strange newborn. ‘A strange multiplicity
of sensations seized me,’ says the monster in her novel Frankenstein,
‘and I saw, felt, heard, and smelt, at the same time; and it was,
indeed, a long time before I learned to distinguish between the
operations of my various senses.’
The psychologist William James conjured a similar picture of the baby’s sensory world in his Principles of Psychology (1890).
He wrote (and the excited capitalisations are all his) that ‘any number
of impressions, from any number of sensory sources, falling
simultaneously on a mind WHICH HAS NOT YET EXPERIENCED THEM
SEPARATELY, will fuse into a single undivided object for that mind’. As a
consequence, ‘The baby, assailed by eyes, ears, nose, skin, and
entrails at once, feels it all as one great blooming, buzzing confusion;
and to the very end of life, our location of all things in one space is
due to the fact that the original extents or bignesses of all the
sensations which came to our notice at once, coalesced together into one
and the same space.’ If the Jamesian perceptual model held true, if
most of us separate out the senses as we mature, could synaesthetes
simply be continuing the process of fusion the majority leave behind? In
other words, are all babies synaesthetic?
This extraordinary concept was picked up again in 1988, in the book The World of the Newborn.
Its authors, the developmental psychologist Daphne Maurer of
McMaster University in Ontario and her writer husband Charles Maurer,
conjured a sense-world of the newborn that recalled the
proto-synaesthesia of Rousseau’s fully grown child:
His world smells to him much as our world smells
to us, but he does not perceive odours as coming through his nose
alone. He hears odours, and sees odours, and feels them too. His world
is a melee of pungent aromas – and pungent sounds, and bitter-smelling
sounds, and sweet-smelling sights, and sour-smelling pressures against
the skin. If we could visit the newborn’s world, we would think
ourselves inside a hallucinogenic perfumery.
The Maurers proposed that all infants were synaesthetic, with
exuberant connections snaking between the parts of their brains that
transformed various stimuli to perception. The pitched crosstalk between
these various brain areas, they said, likely resulted in a synaesthetic
infantile sensorium. The idea had first struck Charles Maurer while
reading the Soviet psychologist Alexander Luria’s The Mind of a Mnemonist
(1968), whose subject recalled the ‘vague synaesthetic sensations’ of
his early childhood, where ‘a mass of fog, then of colours’ meant there
was noise, possibly a conversation. Maurer asked his wife, who was then
studying how sight developed among infants, if all newborns could be
synaesthetic.
Over an interview on Skype, Daphne Maurer recalled her response: ‘I
said, uh, I don’t know... Let me think about how that’d be manifest and
go back and look at the data on infants.’ Her voice had the woozy,
dream-like tones of someone spending a lifetime trying to get across to
tiny babies. ‘And when I went back to look, I thought it makes sense.’
The evidence she found came from a body of studies of brain anatomy
from the 1980s and ’90s, all charting how the number and extent of
neural connections waned from infancy to adulthood. Spurred by
anatomical tracing – a technology that helped mark groups of neurons and
follow their developmental trajectory – the studies chronicled
how networks of neurons in the brains of kittens, infant rhesus monkeys
and humans thinned out as some skills were emphasised over others. More
recent studies, which Maurer now cites as additional proof, show that in
humans neural pruning appears to be especially pronounced between the
ages of seven and nine.
The pruning faded the psychedelic phenomena – except for synaesthetes, whose thicket of brain connections were strengthened and reinforced
While sifting through behavioural experiments, Maurer found
persuasive hints to support the hypothesis that synaesthesia declined as
the infant brain matured and neural connections were pruned. An early
example was a 1974 study by researchers at Harvard Medical School. ‘If
you put electrodes on the newborn’s head and stimulate the wrist, you’ll
see an increase in activity in the tactile cortex,’ she told me. ‘And
if you turn on white noise at the same time, you’ll get larger changes
in the tactile cortex.’ In other words, in the infant brain, touch and
sound amplify each other. But the same part of an adult’s brain, which
doesn’t process sound, doesn’t experience a corresponding increase in
activity.
The study reinforced impressions made through many years spent in
hospital wards studying sight development in newborns. Maurer recalled
that babies in frenetic wards ‘started to cry and shut down’, while
those who received a single, gentle sensation – a soft voice or a light
down blanket smoothed atop them – broke into ‘some very gentle smiles.
Babies seem to respond to the overall level of stimulation, regardless
of where it was coming from. It’s as if the nervous system was just
summing up sound and sight and touch.’
Over time, specificity takes control. Here Maurer cites the work of
Helen Neville, a neuroscientist at the University of Oregon, whose 1995
study found that speech sparked brain waves across auditory and visual
regions of the brain in six-month-olds. But the effect tapered off, with
speech mainly provoking activity in auditory regions by the time the
children turned three. These studies and others have led Maurer to
conclude that the hyper-connected neural networks observed in babies
tapered down over time, or got ‘pruned’ by their environment and their
experience. She reckoned that the pruning had the effect of fading out
the attendant psychedelic phenomena – except among synaesthetes, in
whose brains the thicket of connections got strengthened and reinforced.
It’s impossible to truly replicate the phenomenological experience of
an infant, but two psychologists at the University of California in San
Diego have recently shown the phenomenon in play for the first time.
Katie Wagner and Karen Dobkins presented two-month-olds,
three-month-olds, eight-month-olds and adults with dark outlines of
circles and triangles against two sets of background colours: either red
and green, or blue and yellow. In one arm of the study, they
hypothesised that synaesthetic infants who associated triangles with red
would be inclined to glance more at triangles set against a green
background, much like adult counterparts.
After analysing the results of about 100 rounds of these tests per
infant, Wagner and Dobkins confirmed the effect for two- and
three-month-olds, while eight-month-olds and adults no longer
demonstrated any strong association or preference. The results of the
study, they wrote in Psychological Science in 2011, ‘demonstrate
[that] synaesthetic associations’ start ‘early in life and … decline
with age’, providing clear support for the Maurers’ big ideas.
Other research shows infantile synaesthesia reconfigures in
toddlerhood, as babies grow. That work comes from Julia Simner, a
neuroscientist at the University of Edinburgh who has tried to capture
the process in time-lapse view. In a 2009 study published in Brain,
she asked 615 six-year-old school children to match up 13 colours with
26 letters of the English alphabet and the numerals 0 to 9. Ten seconds
later, they were tested on their matches. The 47 best scorers were
tested again a year later. In the intervening time, their associations
strengthened, providing a glimpse into how synaesthesia progresses in
real-time. When Simner checked back in with her would-be synaesthetes
three years later, when they were 10 or 11, she found the constancy of
their fixed associations had further strengthened. The trajectory was
clear: 34 per cent fixed their letters and digits by age seven, 48 per
cent by age eight, and 71 per cent by age 11.
Daphne Maurer also has an ongoing study along these lines. She’s been
following three children of female grapheme-colour synaesthetes since
age three or four. These children have been asked to choose colours from
a selection of 96 crayons to go with letters of the alphabet, single
digits, and four basic shapes. The task is staggered over several weeks
and repeated several times. So far, she has found that non-synaesthetic
children choose different crayons every time, while the offspring of
synaesthetic mothers consistently pick the same shades to go with
letters, numbers and shapes. Consistency increases the next year again,
going from 40 per cent to 75 per cent. Maurer has been struck by how
nuanced these children’s associations become, much like their
synaesthetic parents. One child, for instance, complained that the green
attached to a letter was not quite the right shade.
Lifelong time-lapse studies have proven
costly and challenging, so synaesthesia researchers today increasingly
focus on what's termed cross-modal integration: the ways in which the
brain combines different sensory inputs, such as smells and sounds. You
might think our senses work independently, honing in on an individual
sight or sound like a pinhole camera or laser beam. In actuality, all of
our senses are constantly, seamlessly melding together to capture the
world in a sharper, more vivid way. Just recall the cottony inedible
mush you ate when you last had a cold, or how you know precisely which
direction to flee when you hear a dog let out a low-pitched growl. Those
are sights, sounds, smells and a host of other perceptions coming
together, crisscrossing in the brain.
Such interactions between the senses produce ‘extra-perceptions’ – a
kind of undertone. For example, you might have the sense that the source
of a high-pitched yap is a tinier, less intimidating shape than that of
a low-pitched growl. The earliest such cross-sensory correspondence was
discovered in 1929, by Edward Sapir, a linguist at the University of
Chicago, and by Wolfgang Köhler, a psychologist at the University of
Berlin. Sapir told participants in his study to attribute two nonsense
words, mil and mal, to two tables, one of which was smaller than the other. All but one participant identified mil as the tinier table. Meanwhile, Köhler’s participants were asked to match two made-up words, takete and maluma, to two shapes, one a lumpy amoeboid, the other, a jagged shard. Most of them were certain that takete was the spiky one, and maluma
the blob. Subsequent studies have found that children and adults tend
to associate brightness with loudness, and a small ball with a
high-pitched sound.
Researchers are interested in finding out if these interactions exist
along a continuum – mild among non-synaesthetes and strong among
synaesthetes, indicating that we all have some ability to access the
sort of enriched perceptions that come with synesthesia. Daphne Maurer,
who regards these correspondences as connections between brain areas
that were spared during the pruning process, thinks this might be the
case.
So does the neuroscientist Edward Hubbard of the University of
Wisconsin-Madison. ‘Your actual experience of the world is highly
integrated, and constantly combines all sorts of information from
different sensory modalities,’ he told me. In synaesthesia, ‘we’re
seeing a heightened version’ of it.
A famous instance of this is the McGurk effect, a trippy perceptual
illusion discovered by the British psychologist Harry McGurk in 1976, in
which an audio recording of a person repeatedly saying ‘ba’ is played
along with video recording of a person repeatedly saying ‘ga’. The sound
is ultimately reconciled in the brain as something in-between: ‘da’.
the universality of this cross-sensory quality might make us all ‘closet synaesthetes’
‘This shows that speech perception is actually this multisensory
phenomenon, where we bring together inputs from various senses,’ Hubbard
said.
Back in 2001, a set of experiments by Hubbard and his then-advisor
Ramachandran revealed the likely cerebral crossroads through which such
connections streamed back and forth: the angular gyrus, a tiny area
sidling up to the major brain regions processing touch, hearing and
vision. Hubbard and Ramachandran showed three patients with damaged
angular gyri abstract shapes that they called bouba and kiki – their version of the maluma-takete task. ‘The patients were far less likely than healthy college undergraduates to readily recognise that the blob was bouba and the shard-like shape kiki. Hubbard said.
Hubbard and Ramachandran then asked the patients to explain metaphors
or figures of speech such as ‘he stepped down as director’. Not
surprisingly, the patients were generally impaired at a range of
linguistic tasks. The damage to their angular gyri had wiped out their
ability to sense the extra-sensoriness of language – it had damaged
their ability to recognise that a jagged thing could be something you
see with your eyes like a jagged shape or something you hear, like a
jagged guitar chord, or the word kiki. In other words, they
lacked the extrasensoriness most of us take for granted. Indeed, the
researchers concluded that the universality of this cross-sensory
quality, and the fact that it might be lodged in our anatomy, might make
us all ‘closet synaesthetes’.
It could be that synaesthesia is the true engine of metaphor and art.
Just ask Megan Hart. ‘The word love has always tasted like the scent of
fresh ink and soft paper to me. Like a newly written poem,’ she wrote
in her novel Tear You Apart (2013). The poem, like the novel, is synaesthetic at heart, and the synaesthetic self is the secret source.
That we are all on the synaesthetic spectrum hit home last November
at the Society for Neuroscience meeting in Washington DC, where
researchers said this talent just might explain why those with sensory
deficits still function so well. Jenessa Seymour, a doctoral candidate
at the University of Illinois at Urbana-Champaign, described an
experiment proving that individuals born deaf have a highly sharpened
sense of peripheral vision especially useful in low-light conditions.
The additional brainpower for this supervision, she said, came from a
brain region that would otherwise be used to combine sight and sound –
the posterior superior temporal gyrus.
Ryan Stevenson, a neuroscientist at the University of Toronto, has
honed in on the corner of this brain region: the superior temporal
sulcus, which is involved in speech perception, facial perception,
interpreting emotions, and understanding the intentions of others. All
these functions, he noted, were impaired in the autistic. In an
experiment, he tested children with and without autism on their ability
to combine auditory and visual information. First, he measured how
clearly the children were able to perceive simple non-speech sounds such
as flash-beeps and whistles. The children were then asked to combine
sound and vision in a test of the McGurk effect. They were shown a video
of a person mouthing ‘ga’ alongside audio of someone saying ‘ba’. The
researchers found that, while both groups were equally good at
perceiving flash-beeps and whistles, children with autism were far less
likely to report hearing the ‘combined’ sound ‘da’. Many of them
reported just what they heard, a lone ‘ba’.
Stevenson concluded that children with autism were slower to put
together what they saw with what they heard, particularly when it came
to speech. ‘It’s kind of like how you can hear better in a noisy room if
you see someone’s mouth,’ Stevenson explained. ‘But kids with autism
have a harder time differentially putting together what they heard and
saw.’
Taken together, the findings show that we are all closet synaesthetes
to a greater or lesser degree. The further along the autistic spectrum,
the less synaesthethetic we might be. Synaesthesia promotes connection
within one’s own mind – and between minds as well. To lack the
synaesthete’s skill is to stand apart. A circus of the senses forges our
early development and drives our humanity. By thinking back to our
infant mind, when our synaesthesia was at its height, we just might
amplify the sensations flooding in from the world.
20 January 2015
No comments:
Post a Comment