Cell Language 235“6x9” b2861 The Cell Language Theory: Connecting Mind and MatterTable 4.17 Extracellular vesicles (e.g., exosomes) as molecular texts encoding the
information being exchanged between living cells.Linguistics/SemioticsCommunication
Intercellular Interpersonal
Second articulation (letters →
words) (to denote)Biochemical and small
polypeptidesWordsFirst articulation (words →
sentences) (to decide)Biopolymers and their complexes SentencesThird articulationa (sentences →
syllogisms/texts) (to argue)Extracellular vesicles containing
biochemical and biopolymersTextsTools of study Digital CymaScopeb Audio-analyzer
Sensor Microscopic (water moleculesc) Macroscopic
(diaphragm)
aSee Section 4.2.1 for more detail.
bThe first version of the digital CymaScope is now available as described in [561].
cWater molecules when acting as an n-molecule ensemble called “coherence domains” (see Section 4.17)
can detect and amplify extremely weak signals, well beyond the sensitivity of the macroscopic
diaphragm used in macroscopic audio-analyzers currently available on the market.We may refer to Statement (4.41) as the “exosome as molecular text”
(EMT) hypothesis or ‘exosome as molecular algorithm (EMA) hypothesis.
The EMT/EMA hypothesis is further characterized in Table 4.17 from the
cell linguistic perspective.
The commercially available CymaScope [493] (see Figure 4.15)
combined with the PDE-based statistical analysis of the CymaGlyphs
(i.e., the water wave patterns detected with CymaScope) may prove use-
ful in decoding the molecular message packaged in exosome. The key
steps in the Planckian Distribution Equation (PDE)-based CymaScopic
(PCS) analysis of exosomes are depicted in Figure 4.20.
The PDE-based CymaScopic analytic method illustrated in Figure 4.20
consists of five major steps:Step 1: Obtain CymaGlyphs perturbed by exosome samples #1 and #2
by inserting these samples in the sound paths between the sound
source and the image detector in the CymaScope.b2861_Ch-04.indd 235 17-10-2017 11:59:10 AM