Sinapsis - Episodio 1: Creatividad y cerebro

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Art is an essential part of human life

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Since the Stone Age, cavemen transformed

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the materials around them

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to shape, for example,

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the fangs of a mamooth into exuberant female bodies

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and they used natural pigments

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to paint on their caves' walls.

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The artwork that we admire in museums, theaters or concert halls,

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that we listen to on our electronic devices

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or that we experience through a screen

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arose from that sudden need to transform the environment

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that characterizes our species, the Homo sapiens.

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This process of generating something new

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by transforming or transcending the existent

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is called "CREATIVITY".

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How to study creativity?

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Nowadays, technological advances

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allow us to measure physical changes in brain activity

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while a subject performs a task.

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This is called "functional neuroimaging",

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which facilitated the fusion of two disciplines

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cognitive psychology, which studies the functioning of the mind

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and neurobiology, which studies the biology of the nervous system

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This fusion gave birth to Cognitive Neuroscience,

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an experimental discipline seeking to answer questions such as:

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“What happens in the brain when we learn, perceive or remember?

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What is the biological basis of emotions and feelings?

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How does our brain process different types of information from the world?

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Eric Kandel, neuroscientist who received the Nobel Prize in 2000

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for his discoveries concerning the biological bases of memory,

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refers to this field of study as "the new science of mind".

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Art and neuroscience offer complementary perspectives

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on the human mind.

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At this intersection was born

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SINAPSIS :Connections between art and your brain

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I am Fernanda Pérez Gay, I have a PhD in neuroscience,

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and in this first episode of SINAPSIS

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I will guide you through the long journey

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undertaken by psychologists, neurologists and neuroscientists to

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investigate the neural roots of creativity.

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Creativity and the brain.

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The brain is said to be the most complex object in the known Universe

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The human brain has approximately

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EIGHTY SIX MILLION NEURONS!

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and each one of them can make up to 15,000 synapses

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with other neurons in other areas of the brain.

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If we do the math, this will give us an approximate of

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ONE QUINTILLON neural connections!

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If we wanted to calculate the number of possible neural circuits

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and the brain states or configurations that emerge from them

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we would face astronomical numbers.

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Let's begin by saying that our brain has two hemispheres:

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the right hemisphere and the left hemisphere,

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each with four lobes:

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The frontal lobe,

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the parietal lobe,

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the temporal lobe

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and the occipital lobe.

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Our two hemispheres are not completely independent:

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they are connected by a thick bundle of nerve fibers:

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the corpus callosum.

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The right and left hemispheres have some differences

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in the way they process information:

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Each hemisphere may be predominantly activated for a certain type of task.

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Let's take, for example, language: It is well known

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that grammar and word meaning are produced and decoded in the left hemisphere,

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while the right hemisphere processes the musicality of language (intonation).

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Have you ever heard that

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the left hemisphere is logic, rational and analytic,

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while the right hemisphere is artistic, holistic and creative?

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This is actually one of the most popular myths about brain functioning!

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However, this idea is based in some findings

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that emerged precisely in the first approaches

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to the science of creativity.

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Before the era of functional neuroimaging

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creativity was approached mostly in clinical settings,

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studying patients that had suffered brain damage.

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When a particular region of the brain is injured,

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the function of other brain regions may become enhanced.

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In this line, the famous neurologist Hughlings Jackson

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described cases of children with damage to the left hemisphere

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noting some of them heightened their musical ability.

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Given these findings, he thought that, in normal conditions,

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the left hemisphere inhibited the function of the right hemisphere:

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Damage to the left side of the brain would interrupt this inhibition,

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leading to creative outbursts

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orchestrated by the right hemisphere.

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Other neurologists studied cases of patients with dementia

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whose damage was largely restricted to the left hemisphere,

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reporting that, while the disease advanced, some of these patients

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showed a sudden emergent of artistic talent.

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A century later, using a functional neuroimaging technique

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researchers found that, when a task becomes routine

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or a stimulus is presented repeatedly,

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activation of the right hemisphere decreases,

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whereas the left hemisphere continues to be active.

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These findings suggested that the left hemisphere

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processes routine or familiar information,

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while the right hemisphere is specialized in novelty seeking.

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Another study that supported the role

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of the right hemisphere in creativity focused on puzzle solving.

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There are two ways of solving a puzzle:

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the first one requires methodical testing of potential solutions,

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and the second implies a moment of creative insight (Eureka!).

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Based on this model, two scientists (Jung-Beeman & Kounios)

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ran a series of experiments in which subjects

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had to solve simple problems in the lab,

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while they recorded their electrical brain activity.

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Their study revealed that a region of the right temporal lobe

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exhibited a spike of very high-frequency electrical activity

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(known as "gamma" brain waves)

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at two different points in time:

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1. At the beginning of the task

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and 2. Just before the sudden revelation of the solution.

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Despite these findings, to affirm that creativity resides in the right hemisphere

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would be to oversimplify the evidence.

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In fact, creativity is a complex process

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and can be expressed in many ways.

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The evidence we mentioned so far leaves many open questions,

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for example : what happens with creativity in literature or math,

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capacities that depend to a large extent on the activity of the left hemisphere?

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Wouldn't it be a little simplistic to assume that

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in a densely interconnected brain,

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creativity is restricted to a particular region?

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Stay with us in SINAPSIS

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to answer some of these questions with the most recent studies

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of the neuroscience of creativity.

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"NEURO-WONDERS"

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Have you ever found a problem's solution when you weren't actively thinking of it?

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Many researchers have pointed out

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that unconscious thought processes

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can play an important role in creativity.

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While our conscious brain activity draws away from the problem,

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those thought processes of which we are not aware keep active,

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suddently revealing the idea

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we had been actively looking without any succes

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Two psychologist from the Netherlands hypothesized that,

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when we re-direct our attention

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to other tasks beyond the problem we are trying to solve,

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our brain makes a transition from

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a CONVERGENT, more rigid thinking

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to a DIVERGENT, more associative thinking.

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In a series of psychology experiments, they asked subjects

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to make a list of places that started with the letter A

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They found that distracting subjects with other task after the instruction

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resulted in lists that were more creative and unconventional

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than the lists of those subjects that had to respond immediately.

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This is an example of how relaxing and letting the mind wander a little bit,

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can promote novel and more original solutions to a problem.

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Highly creative subjects have certain common characteristics:

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their FLUENCY (they produce high amounts of ideas),

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their FLEXIBILITY (their ideas are very diverse)

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and their ORIGINALITY (their ideas are novel or unusual).

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So.. where is creativity located in the brain?

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Can we localize it?

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Is it really restricted to a particular brain region or hemisphere?

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In recent years, many research teams

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have identified brain regions

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that exhibit higher activity during creative thinking tasks.

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These areas, linked to creative thought

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can be found in both the right AND THE LEFT hemisphere

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and are associated to different aspects of the creative process.

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For example, the Dorsolateral Prefrontal Cortex

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is essential to evaluate and select concepts that may not be evidently related

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and integrate them into the same creative idea

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while the Posterior Parietal Cortex

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helps us to retrieve information linked to previously formed creative ideas

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Also, some regions in the temporal lobe

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are in charge of associating these ideas with long term memory.

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These brain areas, of course, do not work in isolation:

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Modern neuroscience consider that complex mental functions

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do not result from the activity of a particular brain region

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but rather emerge from "neural circuits" or "large-scale brain networks",

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which include widespread, interconnected brain regions.

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Until now, researchers have identified three main brain networks

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linked to the funcioning of highly creative brains:

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The "Executive Control Network"

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The "Default Mode Network"

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and the "Saliency Network".

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To explain the interaction of these three networks

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let's take an everyday example:

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Imagine that you need to engage in a task that requires creative thought:

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having to create something new from a blank canvas

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or a white page.

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When we sit down centering our attention

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on solving a problem or generating new ideas,

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we are engaging our "Executive Control Network".

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The brain stuctures in this network allow us to focus

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our attention on a single task for an extended period of time.

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As you may know,

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it is not usually during intense work moments that we come up with innovative ideas,

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but rather during leisure or relaxing time

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-when we are taking a shower, going for a walk,

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or when we are about to go to sleep-.

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It is then that we experience the famous EUREKA!

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and finally find the solution we had been looking for.

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How do we explain this?

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Our "Default Mode Network" is active when

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we are "day dreaming" or letting our mind wander.

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This network keeps generating ideas through

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spontaneous association while we distract or relax.

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After identifying novel or potentially useful ideas within our mind wanderings

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our "Salience Network" acts like a switch

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forwarding this information to the "Executive Control Network"

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to put these ideas into action.

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One of the most recent studies about neuroimaging of creativity

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found that the connection pattern of these three networks

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allows to predict individual creative thinking ability.

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This study (by Roger Beaty et al., published in PNAS, 2018)

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provides a first integrative model of brain functioning behind creative thinking.

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It is clear that we still have many unanswered questions,

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for example:

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Have you ever heard about the link between creativity and mental illness?

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Is it true that subjects diagnosed with mental conditions are more creative?

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This question is a tough one.

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To speak about it, we invited a specialist,

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Dr. Jesús Ramírez-Bermudez,

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MD, neuropsychiatrist, researcher and writer.

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"HUNTING FOR ANSWERS"

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When we think about the link between creativity and psychopathology,

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we have to admit that this approach has a long cultural history.

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The classical reference may be the

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"Problema XXX", which is at least attributed to Aristotle,

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the famous greek philosopher, in which he questions

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why is it that all "exceptional men"

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(who have become eminent in poetry or the arts or even in politics)

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shared a "melancholic temperament"

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historically thought of in the hippocratical tradition

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as the "black bile disease",

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which would correspond -to a certain extent-

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to what we refer today as "Major Depressive Disorder"

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In a second historical moment we have the work of Karl Jaspers,

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the iconic founder of present-day psychiatry

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and a very important existential philosopher,

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who wrote a book titled "Genius and madness" in which

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he stated that, in certain patients, there was a clear link

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between creativity and schizophrenia.

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He gave the examples of Van Gogh and Hölderlin.

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Even if it's quite difficult to make retrospective diagnosis,

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he gave himself that permission to make this connection

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claiming that the extremely unusual and interesting experiences

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that patients with mental conditions live

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could have a big impact in their artistic creation.

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Finally, in a third, more contemporary moment, bringing us closer to modern science

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we have the research done by Peter Emanuel Sifneos,

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who coined the concept of "Alexithymia"

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defined as an incapacity to verbalize emotions,

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in which people find it extremely difficult to describe their own mental states

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particularly their subjective feelings.

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This is a phenomenon he observed as

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a consequence of traumatic memories

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people made when imprisoned in Nazi concentration camps.

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A couple years later,

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Klaus D. Hoppe, an important american psychiatrist

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found that "alexithymia" could also be observed

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in people that had undergone a surgical procedure

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called "callosotomy", used in cases of refractory epilepsy,

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in which the "corpus callosum" is completely severed

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preventing the communication between the two brain hemispheres.

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Hoppe thus suggested that the inverse of "alexithymia"

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would be a CREATIVE phenomenon he named "symbolexia":

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Defined as a heightened capacity of different brain modules

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to receive information from other modules elsewhere in the brain

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through the corpus callosum by means of INTERHEMISPHERIC communication.

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This leads us to the question that we are asking today

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in the fields of clinical and cognitive neuroscience:

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How do communication between different brain networks

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allows the transformation of information

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that is behind the creative phenomenon?

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Creativity is not a single trait, nor an isolated process

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On the contrary, it takes place on a cultural context

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that can shape it and promote it but also paralyze it.

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To be able to understand a complex phenomenon such as creativity

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we need to integrate neuroscientific findings

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with the perspective of psychology, the social sciences, the humanities

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and of course, with the artists' perspectives.

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Even if we can find common cognitive processes

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and their brain correlates

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the experiences and emotions lived by each artist when they create their artwork

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will remain inscrutable for neuroscience.

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The brain -wrote Emily Dickinson- is deeper than the sea—

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"For—hold them—Blue to Blue—

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the one the other will absorb— as sponges—Buckets—do—"

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We invite you to keep immersing in the fascinating brain waters

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by following our social media accounts (IG:@sinapsis2019, FB: @sinapsisarteycerebro, TW: @sinapsis_2019)

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And staying tuned for the next episoides of SINAPSIS: Connexions between art...

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...and your brain.

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Closing Credits: Original idea, research, script writing and host: Dr. Fernanda Pérez-Gay Juárez // Production: Ivan Méndez Rivera //Production assistants: Luis Ángel Pérez Córdova, Miguel Ángel Cañedo Zavaleta.

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Video editing, post-production and graphic motion animation: Rodrigo Pérez-Grovas Álvarez. // Communication assistant: Ana Laura Pérez Flores.

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Featured specialist: Dr. Jesús Ramírez-Bermúdez// Brain dissections and photography: Dr. Julio César Pérez

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Acknowledgements: We thank the Faculty of Medicine of UNAM for allowing us to film in the Anatomy Department.

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Music: -Original composition by Manuel Velázquez -Album Into Madness -Other songs by Scott Holmes, André Codeman Dee Yan-Jey

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English translation: Fernanda Pérez-Gay **Funded by Fonds de Recherche du Québec.

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Original project funding: FONCA (Arts and Culture Trust Fund), Mexican Secretariat of Culture

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ACT Program (Arte, Ciencia y Tecnologías -Art, Science et Technologies) - FONCA, UNAM.

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Mexico city, Mexico, 2019