Thermodynamics and life
Ilya Prigogine
1917 - 2003
01
Lectures on Medical Biophysics
Dept. Biophysics, Medical Faculty,
Masaryk University
ionpump Ilya Prigogine
logo Masarykova univerzita – Lékařská fakulta

Lecture outline
•Basic concepts of non-equilibrium thermodynamics of living systems
•Diffusion
•Osmosis and osmotic pressure
•

Basic concepts of non-equilibrium thermodynamics of living systems
•There is an internal „source“ of entropy in non-equilibrium systems.
•The amount of entropy „produced“ per unit volume in unit time is called the entropy production
rate s (sigma).

Prigogine principle
•For states not too far from tmd. equilibrium, the Prigogine principle applies:
• At constant external conditions, an open system spontaneously proceeds towards a state with a
minimum entropy production rate.
•This state is called a stationary state (in biology: state of dynamic equilibrium, homeostasis
respectively).

Difference between an equilibrium and stationary state
koule1
Is it possible to maintain a state with different temperatures in an isolated system?

Difference between an equilibrium and stationary state
koule2
The temperature difference can be maintained only in an open system involving a heat pump which
requires an energy input to function.
Heat pump

Difference between an equilibrium and stationary state
The ion pump maintains a constant difference in concentration of ions and/but requires energy.
ionpump

Fluctuations and generalised le Chatelier principle
•Fluctuations are small deviations from the equilibrium or stationary state arising from internal
stochastic (random) processes. Small disturbances are small deviations from the equilibrium or
stationary state arising from external processes.
•Generalised le Chatelier principle:
–When a system is at a stationary state, any small fluctuations lead to fluxes of particles or
energy which cause the system to return to the original stationary state.
•Critical or bifurcation point (from this point the system can develop in two different ways – e.g.
return to the original stationary state or go to another one)

Dissipative structures
•Ordered non-equilibrium time-space structures are called dissipative structures. We cannot apply
Boltzmann formula on them. According to Prigogine, they originate as a consequence of a
fluctuation. They are stabilised by energy exchange with environment. The dissipative structures
belong among problems solved by non-linear non-equilibrium thermodynamics. They can appear only in
conditions far enough from equilibrium and a sufficient energy and substance flow is necessary.
(Example: „Bénard instability“)

Autocatalytic reactions
•A general equation of the autocatalytic reaction:
•nA + X ¬¾® 2X + (n - 1)A,
•    It can be followed by:
•X ¬¾® F
•In the autocatalytic reaction, a compound X is formed from compound A under in presence of the
substance X. It means that the substance X acts as a catalyst in its formation. When the substance
A is available in sufficient amount, the amount of X grows exponentially. F can be a product formed
from compound X.
•Autocatalytic reaction of it's kind is also the replication of DNA. It should be admitted that it
is a complex of „common“ chemical reactions can demonstrate itself as an autocatalytic reaction,
i.e. a complex of metabolic processes which results in formation of a copy carrying the same
genetic information.
•Autocatalitic reaction is a chemical dissipative structure and behaves like a chemical oscillator.

Belousov-Zhabotinsky reaction
bzr_raum1
http://www.jkrieger.de/bzr/2_4_versuch_raeuml.html#2_4

Examples of thermodynamic approach to problem solution:
•Non-equilibrium thermodynamics:
•Diffusion
•
•Equilibrium thermodynamics:
•Osmosis
•

Diffusion as an irreversible process
•Transport process -  tmd. system proceeds towards equilibrium state, in which concentrations of
all present substances are equalised in whole volume.
•The flow of diffusing substance is constant when there is no significant change of its
concentration on both sides of the (permeable) membrane (e.g., when the process is slow, volumes
are large or active transport is present).
•Density of diffusion flow J definition – amount of substance passing through unit area of a
boundary in unit time:
A is total area of the boundary, dt is a small time interval during which substance amount dn is
transported.

1st Fick law
A.E. Fick (1885):
(substance moves in the direction of the x-axis, one-dimensional case of diffusion):
D -  diffusion coefficient
[m2·s-1]
Typical values of D:
from 1·10-9 for small molecules to
1·10-12 for big macromolecules
MLM
Concentration gradient
•
difuze-engl

Diffusion coefficient
•Approximate formula for the diffusion coefficient was derived by A. Einstein:
k is Boltzmann constant
T is thermodynamic temperature
h is dynamic viscosity
r is particle radius.
The term 6phr is called friction or hydrodynamic coefficient f .

2nd Fick law
The 1st Fick law holds when the concentration gradient is constant over time. This condition is not
fulfilled for most real processes, so that we need the 2nd Fick law to describe such diffusion:
The term d2c/dx2 (second derivative of concentration c with respect to position x, d(dc/dx)/dx, or
an infinitesimal change of concentration gradient along x-axis. We can say: the rate of change with
time of substance concentration at a given point is proportional to the spatial change of the
concentration gradient. The proportionality constant D is again the diffusion coefficient.

Osmosis and osmotic pressure
•Solvent can pass through the membrane but not the solute. System proceeds to tmd. equilibrium by
equalisation of concentrations of substances in the whole system by solvent diffusion from space I
into the space II.
•Result: pressure increase in space II when the membrane is rigid.
osmosis1

Pfeffer experiment



van't Hoff formula
•P = cRT
•P is osmotic pressure [Pa]
•c concentration of dissolved compound (n/V)
•R universal (molar) gas constant
•T thermodynamic temperature
•Better fitting (approaching) formula:
•P = m'RT
•m' is molality (substance amount in 1 litre of solvent).

van't Hoff formula
•For electrolytes:
•P = icRT
•i is dimensionless van't Hoff correction factor, which says how many times more particles are
present in solution than the original number of dissolved non-dissociated particles (molecules).
•The product ic is sometimes called osmolar concentration or osmolarity with unit osmol·l-1.
•A strong electrolyte with concentration of 1 mol·l-1, dissociating into two ions, has the osmolar
concentration 2 osmol·l-1 and double the osmotic pressure of a non-dissociating compound of the
same concentration.
•The osmotic pressure of blood plasma or interstitial fluid is about 770 kPa. (1 M solution of a
non-dissociating compound has osmotic pressure 2.58 MPa at the same temperature).
•Oncotic pressure (3.3 kPa)

Tonicity of solutions
•solutions having osmotic pressure lower than blood plasma has are hypotonic, with the same
pressure are isotonic, and with higher pressure than blood plasma are hypertonic.
•endoosmosis: haemolysis
•The range of concentrations of hypotonic solutions in which partial or full haemolysis does not
occur = osmotic resistance of erythrocytes.
•exoosmosis: plasmorrhysis (in plants - plasmolysis)
•receptors (volumoreceptors in kidneys and osmoreceptors in hypothalamus)

How does it look?
rbc41
Echinocytes – erythrocytes exposed to a hypertonic solution.
http://webteach.mccs.uky.edu/COM/pat823/online_materials/diglectures/rbcs/imgshtml/image36.html
Plasmo6
Plasmolysis of epidermal cells of onion in hypertonic medium.
http://www.pgjr.alpine.k12.ut.us/science/whitaker/Cell_Chemistry/Plasmolysis.html

Author:
Vojtěch Mornstein
Language revision:
Carmel J. Caruana
Last revision and sound track addition: September 2020