Title:Study on Single-molecule Biophysics and Biochemistry in Dilute Liquids and Live Cells without Immobilization or Significant Hydrodynamic Flow:
The Thermodynamic Single-molecule Demon
Volume: 23
Issue: 14
Author(s): Gerd Baumann and Zeno Foldes-Papp*
Affiliation:
- Department of Geriatrics, Asklepios Clinic, Lindau - D 88131 (at Lake Constance), Bavaria, Germany
Keywords:
Live cell, Brownian movement, normal diffusive systems, thermodynamic jitter, anomalous diffusive systems, CTRW.
Abstract: Since mathematics provides a way to answer questions about the thermodynamic jitter in
a clear, rational manner, with evidence to support it, mathematics is the reliable method necessary to
get the best information on the movement of a single molecule / a single particle at the molecular
scale in dilute liquids and live cells without immobilization or hydrodynamic flow. The Brownian
movement (normal diffusive systems) and generally the thermodynamic jitter (anomalous diffusive
systems) are ultimately the direct or indirect cause of every measurement signal at the molecular
scale in diffraction limited and unlimited optical systems in dilute liquids and live cells without immobilization
or hydrodynamic flow. For example, emitted photons are the epiphenomenon of the
underlying process of thermodynamic jitter of single molecules / single particles at the molecular
scale. The key question is: How far apart do two molecules / two particles have to be in the time
domain so that the required degree of separation between the two individual molecules / the two
individual particles can be quantified at the molecular scale in order to distinguish them as separate
entities without immobilization or hydrodynamic flow? The Földes-Papp’s limits of the singlemolecule
time resolution in dilute liquids and live cells without immobilization or hydrodynamic
flow are the exact answers. The diffusive process is complicated and not minimalist. A minimalist
model has a third possibility, it may be right but irrelevant.