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Department of Biophysics, Medical Faculty, Masaryk University in Brno
1
Lectures on Medical Biophysics
A part of this lecture was prepared on the basis of a presentation kindly provided by Prof.
Katarína Kozlíková from the Dept. of Medical Biophysics, Medical Faculty, Comenius University in
Bratislava

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Bioelectric phenomena
̶The electric signal play a key role in controlling of all vitally important organs. They ensure
fast transmission of information in the organism. They propagate through nerve fibres and muscle
cells where they trigger a chain of events resulting in muscle contraction. They take a part in
basic function mechanisms of sensory and other body organs.
̶On cellular level, they originate in membrane systems, and their propagation is accompanied by
production of electromagnetic field in the ambient medium.
̶Recording of electrical or magnetic signals from the body surface is fundamental in many important
clinical diagnostic methods.

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Biological membrane
̶It is not possible to understand the origin of resting and action membrane voltage (potential)
without knowledge of structure and properties of biological membrane.
̶In principle, it is an electrically non-conducting thin bilayer (6-8 nm) of phospholipid
molecules. There are also built-in macromolecules of proteins with various functions. Considering
electrical phenomena, two kinds of proteins are the most important: the ion channels and pumps. In
both cases these are components of transport mechanisms allowing transport of ions through the
non-conducting phospholipid membrane.

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Structure of the membrane
obr-4copy
Phospholipid bilayer
Integral proteins

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Channels
̶The basic mechanism of the ion exchange between internal and external medium of the cell are the
membrane channels. They are protein molecules but, contrary to the pumps with stable binding sites
for the transmitted ions, they form water-permeable pores in the membrane. Opening and closing of
the channels (gating) is performed in several ways. Besides the electrical gating we can encounter
gating controlled by other stimuli in some channels (chemical binding of substances, mechanical
tension etc.).
̶The passage of ions through the channel cannot be considered to be free diffusion because most
channels are characterised by certain selectivity in ion permeability. Sodium, potassium, calcium
or chloride channels are distinguished.
̶In this kind of ion transport there is no need of energy delivery.

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Electrical and chemical gating


Ion transport systems
Many ion transport systems were discovered in cell membranes. One of them, denoted as
sodium-potassium pump (Na/K pump or Na+-K+-ATP-ase) has an extraordinary importance for production
of membrane voltage. It removes Na-ions from the cell and interchanges them with K-ions. Thus, the
concentrations of these ions in the intracellular and extracellular medium (they are denoted as
[Na+], [K+] and distinguished by indexes i, e) are different. We can write:
Working Na/K pump requires constant energy supply. This energy is delivered to the transport
molecules by the adenosine triphosphate (ATP) which is present in the intracellular medium.

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Principle of the sodium-potassium pump
The sodium ions are released on the outer side of the membrane. Following conformation change of
the ion pump molecule enables binding of potassium ions which are carried inside the cell.
ion pump

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Function of biological membranes
̶They form the interface between the cells and also between cell compartments.
̶They keep constant chemical composition inside bounded areas by selective transport mechanisms.
̶They are medium for fast biochemical turnover done by enzyme systems.
̶Their specific structure and selective ion permeability is a basis of bioelectric phenomena.

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Excitability
Characteristic feature of living systems on any level of organisation of living matter
An important condition of adaptation of living organisms to environment
An extraordinary ability of some specialised cells (or tissues – muscle cells, nerve cells)
Each kind of excitable tissue responses most easily on a certain energetic impulse (the adequate
stimulus). Another energetic impulse can also evoke an excitation but much more energy is necessary
(the inadequate stimulus).

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Resting membrane potential
[USEMAP]

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membrane
Resting membrane potential – RMP (1)
Potential difference between a microelectrode inside the cell (negative potential) and a surface
electrode outside the cell (zero potential)  = membrane voltage = membrane potential
„Non-polarisable“ electrodes are used
membrane
Extracellular space
Extracellular space
Intracellular space

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Its values depend on:
- Type of the cell
- Art of the animal the cell is taken from
- For identical cells – on the composition and concentration of the ion components of the
extracellular liquids
The value of RMP at normal ion composition of the IC and EC liquid: -100 mV to -50 mV
Resting membrane potential – RMP (2)
Membrane thickness ~ 10 nm
Result: Electric field intensity in the membrane ~ 107 V/m
To compare: Electric field intensity on the Earth’s surface ~ 102 V/m

115
Diffusion potential DP (1)
Caused by diffusion of charged particles DP in non-living systems – solutions are separated by a
membrane permeable for Na+ and Cl-.
The compartments are electroneutral,  but there is a concentration gradient
Þ Diffusion of ions from [1] do [2]
Hydration envelope (water molecules are bound to ions) Na+ (more) a Cl- (less)
 Þ faster diffusion of Cl- against (!) concentration gradient
Þ Transient voltage appears across the two compartments
Þ Diffusion potential
115
Electric field repulses Cl- from [2]

116
Diffusion potential DP (2)
DP in living systems – the solutions are separated by a selectively permeable membrane for K+,
non-permeable for pro Na+ a Cl-.
In such a system, an equilibrium arises if there is no resulting flux of ions.
116
Þ Diffusion of K+ against its concentration gradient occurs until an electric gradient of the same
magnitude, but of opposite direction arises
Þ An equilibrium potential emerges – resulting diffusion flux is equal to zero

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membrane
Electrolyte I
anions cAII
cations cCI
A simple example of a membrane equilibrium (1)
Electrolyte II
cations cCII
anions cAI
The same electrolyte is on both sides of the membrane but of different concentrations (cI > cII),
the membrane is permeable only for cations
Result:
Electric double layer is formed on the membrane
layer 1: anions stopped in space I
layer 2:  cations attracted to the anions (II)

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membrane
Electrolyte I
anions cAII
cations cCI
A simple example of a membrane
equilibrium (2)
Electrolyte II
cations cCII
anions cAI
The concentration difference ”drives” the cations, electric field of the bilayer “pushes them back”
In equilibrium: potential difference U arises:
jI
jII
-
-
-
-
-
-
-
-
-
+
+
+
+
+
+
+
+
+
(Nernst equation)

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membrane
Electrolyte I
anions R-
anions cAII
cations cCI
Electrolyte II
cations cCII
anions cAI
Donnan equilibrium (1)
The same electrolyte is on both sides, concentrations are different (cI > cII), membrane is
permeable for small univalent ions C+ and A-, non-permeable for R- .
Diffusible ions: C+, A-   diffuse freely
non-diffusible ions: R- i.e. big anions
In presence of R-: Equal distribution of C+ and A- cannot be achieved
 Þ a special case of equilibrium -
Donnan equilibrium

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membrane
Electrolyte I
anions R-
anions cAII
cations cCI
Electrolyte II
cations cCII
anions cAI
Donnan equilibrium (2)
Equilibrium concentrations:
Donnan ratio:

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membrane
Electrolyte I
anions R-
anions cAII
cations cCI
Electrolyte II
cations cCII
anions cAI
Donnan equilibrium (3)
-
-
-
-
-
-
-
-
-
-
-
+
+
+
+
+
+
+
+
+
+
+
Donnan ratio:
Donnan potential:

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cell membrane
intra
extra
phosphate
anions
protein
anions
Na+
Cl-
K+
K+
Cl-
Donnan model in living cell (1)
diffuse: K+, Cl-
do not diffuse: Na+, anions,
also proteins and nucleic acids
Concentrations:
[K+] in > [K+] ex
[Cl-] in < [Cl-] ex

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Cell membrane
intra
extra
phosphate
anions
protein
anions
Na+
Cl-
K+
K+
Cl-
Donnan ratio:
Donnan potential:
-
-
-
-
-
-
-
-
-
-
-
+
+
+
+
+
+
+
+
+
+
+
Donnan model in living cell (2)

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Donnan potential (resting potential) [mV]:
object:       calculated:        measured:
  K+:   Cl-:
cuttlefish axon - 91 - 103 - 62
frog muscle  - 56   - 59 - 92
rat muscle - 95   - 86 - 92
Donnan model in living cell (3)
Donnan model differs from reality:
The cell and its surroundings are regarded as closed thermodynamic systems
The diffusible ions are regarded as fully diffusible, the membrane is no barrier for the diffusible
ions
The effect of ionic pumps on the concentration of ions is neglected
The interaction between membrane and ions is not considered
•
[USEMAP]

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Model of ion transport (1)
We suppose:
A constant concentration difference between outer and inner side of the membrane Þ constant
transport rate through membrane
Migration of ions through membrane Þ electric bilayer on both sides of the membrane
All kinds of ions on the both sides of the membrane are considered simultaneously
Empirical fact – different ions have different non-zero permeability
Electrodiffusion model with smaller number of simplifications.

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Model of ion transport (2)
Goldman - Hodgkin - Katz
P - permeability

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Model of ion transport (3)
„giant“ cuttlefish axon (t = 25°C):
pK : pNa : pCl = 1 : 0.04 : 0.45
calculated:      U = - 61 mV
measured: U = - 62 mV
frog muscle (t = 25°C):
pK : pNa : pCl = 1 : 0.01 : 2
calculated:      U = - 90 mV
measured: U = - 92 mV

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Action
potential

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Action potential
̶The concept of action potential denotes a fast change of the resting membrane potential caused by
over-threshold stimulus which propagates into the adjacent areas of the membrane.
̶This potential change is connected with abrupt changes in sodium and potassium ion channels
permeability.
̶The action potential can be evoked by electrical, chemical or mechanical stimuli which cause local
decrease of the resting membrane potential.

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Mechanism of action potential triggering
t
Um
UNa
Upr
UK
Umr
0
t
AP
Depolarization phase
Positive feedback: gNa Þ depol Þ gNa
Repolarization phase:
inactivation gNa and activation gK
hyperpolarization (deactivation gK)
Mechanism of the action potential triggering in the cell membrane is an analogy of a  monostable
flip-flop electronic circuit J.

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Zápatí prezentace
31

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Refractory period


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Action potential
̶Changes in the distribution of ions caused by action potential are balanced with activity of ion
pumps (active transport).
̶The action potential belongs among phenomena denoted as „all or nothing“ response. Such response
is always of the same size. Increasing intensity of the over-threshold stimulus thus manifests
itself not as increased intensity of the action potential but as an increase in action potential
frequency (rate).

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AP propagation is unidirectional because the opposite side of the membrane is in the refractory
period.
Propagation of the action potential along the membrane

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Propagation of the action potential along the neuron membrane (2)
cytosol
E – means voltage here, potential
g = electric conductivity, it can be distinguished for individual ions
(ms)

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Propagation of AP and local currents
OBR59
AP propagates along the membrane as a wave of negativity by means of local currents
time

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Saltatory conduction
Conduction of action potential along the myelinated nerve fibre

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Examples of action potentials
obr-1
A – nerve fibre
B – muscle cell of heart ventricle
C – cell of sinoatrial node
D – smooth muscle cell

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[USEMAP]


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Definition
̶Synapse is a specific connection between two neurons or between neurons an other target cells
(e.g. muscle cells), which makes possible transfer of action potentials.

We distinguish:
̶Electrical synapses (gap junctions) – close connections of two cells by means of ion channels.
They enable a fast two-way transfer of action potentials.
̶Chemical synapses – more frequent, specific structures,  they enable one-way transfer of action
potentials.

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Transmission of action potentials between neurons


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Chemical synapse


Adobe Systems Neuromuscular synapse, the junction between a motor neuron axon and a muscle fiber.
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Mitochondrion
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Synaptic gap (cleft)
Chemical synapse – electron micrograph

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Synaptic mediators (neurotransmitters)
̶The most frequent mediators (neurotransmitters) of excitation synapses are acetylcholine (in
neuromuscular end plates and CNS) and glutamic acid (in CNS). Both compounds act as gating ligands
mainly for sodium channels. Influx of sodium ions inside the cell evokes a membrane potential
change in positive sense – towards a depolarisation of the membrane (excitation postsynaptic
potential).
̶
̶Gamma-amino butyric acid (GABA) is a neurotransmitter of inhibitory synapses in brain. It acts as
a gating ligand of chloride channels. Chloride ions enter the cell and evoke so a membrane
potential change in negative sense – membrane hyperpolarization results (inhibitory postsynaptic
potential).

Excitation and inhibition postsynaptic potential



Summation of postsynaptic potentials



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Summary
̶Electric phenomena on biological membranes play a key role in functioning of excitatory tissues
(nerves, muscles)
̶Resting membrane potential  (correctly: membrane voltage) is a result of a non-equal distribution
of ions on both sides of the membrane.
̶It is maintained by two basic mechanisms: selective permeable ion channels and by transport
systems – both these systems have protein character
̶Changes of membrane voltage after excitation are denoted as action potentials
̶Membrane undergoes two phases after excitation: depolarization – connected with influx of sodium
ions into the cell -  and subsequent repolarization – connected with efflux of potassium ions from
the cell
̶In the refractory period, the membrane is either fully or partly insensitive to stimulation
̶Synapse is a connection of two cells which enables transmission of action potentials

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Authors:
Vojtěch Mornstein, Ivo Hrazdira
Language collaboration:
Carmel J. Caruana
Last revision September 2021, addition of soundtrack October 2020