2. BACKGROUND
• Synesthesia: inherent blending of the
senses.
– Grapheme-color is most common:
letters/numbers→colors
– Each synesthete associates each letter with different
colors
– Caused by excess neuronal connections per mutated
enzyme
– Single nucleotide polymorphism (16th chromosome)
• Genetically transmitted to ~0.01% of
population
3. Welcome to my world
of synesthesia!
Welcome to my world
of synesthesia!
5. MATERIALS & METHODS
• Color frequency (wavelengths) compared to letter
frequency (%)
• Synesthete color charts collective of synesthetes of
the language (color the majority of synesthetes
associated with each letter was used)
• English: dictionary vs. Brown Corpus (better
cross-section of English language) vs. children’s
books (synesthetic associations form as the subject
learns the alphabet and remain the same)
• English, Spanish, German to verify causation vs.
coincidence
7. DATA: FIGURE 1 (ENGLISH DICTIONARY)
Synesthetic Associational Pattern between R2= 0.6597
R² = 0.659
1000 Frequencies
Color wavelength (nm)
300
0.1 1 10 100
Frequency in the English Language (%)
9. DATA: FIGURES 3 AND 4 (SPANISH/GERMAN)
Synesthetic Associational Pattern
Between Frequencies in the Spanish r² = 0.47
Language
700
Color wavelength (nm)
600
500
400
300
200
100
0
0.01 0.1 1 10
Frequency in the Spanish Language (%) Synesthetic Associational Pattern
Between Frequencies in the German
Language
700
Color wavelength (nm)
600
500
400
300
200
100
0
r² = 0.72
0.01 0.1 1 10
Frequency in the German Language (%)
10. DATA: FIGURE 5 (CHILDREN’S BOOKS)
Synesthetic Associational Pattern Between
Frequencies in Children's Books R² = 0.5656
R² = 0.565
1000
Color Wavelength (nm)
100
0 2 4 6 8 10 12 14
Letter Frequency (%)
11.
12. NEUROPHYSIOLOGICAL THEORY
• From data, theorized which “color” and “letter” areas of the brain are fused in
synesthetes
• V4- color center in occipital lobe
– Previously suggested by fMRIs of synesthetes
– Columnar structure of neurons organized by long, middle, short wavelength
cone signals as matches previous data
– Neuron preference for more saturated colors as well as long-wavelength
colors
• Left Middle Temporal Gyrus (LMTG)- semantic processing/sensory integration
– Lends itself to functional neuroconnections
– Core component of individuality of semantic system
• fusion of V4 and LMTG supported functionally and topographically
13. V4 and the LMTG. They are closely situated, as
supports the theory of their connectivity in
synesthetes.
14. DISCUSSION AND APPLICATIONS
• First synesthetic color/letter association pattern found
• Mapping of not only synesthetic connections, but also
V4/LMTG (perhaps the largely uncharted LMTG is
organized according to frequency of letters, etc.)
• Induce (visual memory, artistic talent)/reduce
(overwhelming colors for some synesthetes) synesthesia
• Autism, schizophrenia, and epilepsy also caused by
excess neuronal connections- synesthetes provide a
model brain not inhibited by medication or cognitive
impairments.
– For example, sensory areas of the brain connected with the
limbic system (anger management) in autistics, causing
simple sensory cues to extremely anger the patient
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the r-squared values commonly found in psychology (.09 to .25). Explain that although these r-square's indicate that we fail to account for a great deal of the variability in human behavior, that's to be expected because (1) we have measurement error, and (2) we wouldn't expect a single variable (e.g., IQ) to account for all the variance in another variable (college performance).
Neurophysiologically, this pattern can be described by the wavelength-specific color receptor neurons of V4 being fused with the language processing neurons of the left middle temporal gyrus that are prone to perform semantic recognition. The characteristics of these two areas, such as frequency selectivity of V4, match the characteristics of synesthesia first discovered in this research: more frequent letters (interpreted in the LMTG) correspond with colors of longer wavelength (as are preferable in V4), corresponding with the letter frequencies of the native language of the synesthete.
Priming, greek/hebrew case study, mturk, biological methylation epigenetics