Adobe Systems
Department of Biophysics, Medical Faculty, Masaryk University in Brno
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Lectures on Medical Biophysics
Introduction to biophysics of receptors
Biophysics of hearing and vestibular sense
ucho

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Lecture outline
̶General features of sensory perception
̶Perception of sound
̶Properties of sound
̶Biophysical function of the ear
̶Biophysical function of the vestibular system
̶

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Biophysics of  sensory perception
Sensory perception – reception and perception of information from outer and inner medium.
ØFrom outer medium: Vision, hearing, smell, taste and sense of touch
ØFrom inner medium: information on position, active and passive movement (vestibular organ,
nerve-endings in the musculoskeletal system ). Also: changes in composition of inner medium and
pain.
ØComplex feelings: hunger, thirst, fatigue etc.

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Categorising receptors
a) According to the acting energy:
mechanoceptors
thermoceptors
chemoceptors
photoceptors
- adequate and inadequate stimuli
b) According to the complexity:
free nerve-endings (pain)
sensory bodies (sensitive nerve fibre + fibrous envelope - cutaneous sensation)
sensory cells (parts of sensory organs) - specificity
non-specific: receptors of pain - react on various stimuli.
c) According to the place of origin and way of their reception:
- teleceptors (vision, hearing, smell),
- exteroceptors (from the body surface - cutaneous sensation, taste),
- proprioceptors, in vestibular organ, muscles, tendons, joints - they inform about body position
and movement,
-interoceptors - in inner organs
-
In biophysics, the receptors are energy transducers above all.

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Conversion function of receptors
Primary response of sensory cell to the stimulus: receptor potential and receptor current are
proportional to the intensity of stimulus. The receptor potential triggers the action potential.
Transformation of amplitude modulated receptor potential into the frequency-modulated action
potential.
Increased intensity of stimulus, i.e. increased amplitude of receptor potential evokes an increase
in action potential frequency.

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Sensory cell
ØA typical sensory cell consists of two segments:
ØThe outer one is adequate stimulus-specific. (microvilli, cilia, microtubular or lamellar
structures)
ØThe inner one contains mitochondria
ØElectric processes in a receptor cell:
ØThe voltage source is in the membrane of the inner segment - diffusion potential of K+ (U1,
resistance R1 is given by the permeability for these ions).
ØDepolarisation of a sensory cell is caused by increase of the membrane permeability for cations in
outer segment (R2, U2; R3, U3). During depolarisation, the cations diffuse from outer segment into
the inner one.
ØThere are additional sources of voltage in supporting (neuroglial) cells (U4, R4).

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Biophysical relation between the stimulus and sensation
̶The intensity of sensation increases with stimulus intensity non-linearly. It was presumed earlier
the sensation intensity is proportional to the logarithm of stimulus intensity (Weber-Fechner law,
1860). Intensity of sensation is IR, intensity of stimulus is IS, then:
̶
 IR = k1 log(IS).
̶Today is the relation expressed also exponentially (so-called Stevens law, 1957):
 IR = k2 ISa,
̶ k1, k2 are the proportionality constants, a is an exponent specific for a sense modality (smaller
than 1 for sensation of sound or light, greater for sensation of warmth or tactile stimuli). The
Stevens law expresses better the relation between the stimulus and sensation at very low or high
stimulus intensities.

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Adaptation
If the intensity of a stimulus is constant for long time, the excitability of most receptors
decreases. This phenomenon is called adaptation. The adaptation degree is different for various
receptors. It is low in pain sensation - protection mechanism.
Adaptation time-course. A - stimulus, B - receptor with slow adaptation, C - receptor with fast
adaptation
time
time
time

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Biophysics of sound perception
Physical properties of sound:
̶Sound - mechanical oscillations of elastic medium, f = 16 - 20 000 Hz.
̶It propagates through elastic medium as particle oscillations around equilibrium positions. In a
gas or a liquid, they propagate as longitudinal waves (particles oscillate in direction of wave
propagation - it is alternating compression and rarefaction of medium). In solids, it propagates
also as transversal waves (particles oscillate normally to the direction of wave propagation).
̶Speed of sound - phase velocity (c) depends on the physical properties of medium, mainly on the
elasticity and temperature.
̶The product r·c, where r is medium density, is acoustic impedance. It determines the magnitude of
acoustic energy reflection when the sound wave reaches the interface between two media of different
acoustic impedance.
̶Sounds: simple (pure) or compound. Compound sounds: musical (periodic character) and non-musical -
noise (non-periodic character).

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Main characteristics of sound: (tone) pitch, colour and intensity
̶The pitch is given by frequency.
̶The colour is given by the presence of harmonic frequencies in spectrum.
̶Intensity - amount of energy passed in 1 s normally through an area of 1 m2. It is the specific
acoustic power [W·m-2].

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Intensity level
̶The intensity level allows to compare intensities of two sounds.
̶Instead of linear relation of the two intensities (interval of 1012) logarithmic relation with the
unit bel (B) has been introduced. In practice: decibel (dB). Intensity level L in dB:
̶
 L = 10·log(I/I0)   [dB]
̶Reference intensity of sound (threshold intensity of 1 kHz tone) I0 = 10-12 W·m-2 (reference
acoustic pressure p0 = 2×10-5 Pa).

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Loudness, hearing field
̶Loudness is subjectively felt intensity approx. proportional to the logarithm of the physical
intensity change of sound stimulus. The ear is most sensitive for frequencies of 1-5 kHz.
̶The unit of loudness is sone. 1 sone corresponds (when hearing by both ears) with the hearing
sensation evoked by reference tone of 40 dB.
̶Loudness is a threshold quantity.
̶The loudness level is expressed in phons (Ph). 1 phone corresponds with intensity level of 1 dB
for the reference tone (1 kHz). For the other tones, the loudness level differs from the intensity
level. 1 Ph is the smallest difference in loudness, which can be resolved by ear. For 1 kHz tone,
an increase of loudness by 1 Ph needs an increase of physical intensity by 26%.
̶When connecting in a graph the threshold intensities of audible frequencies, we obtain the zero
loudness contour. For any frequency, it is possible to find an intensity at which the hearing
sensation changes in pain - pain threshold line in a graph. The field of intensity levels between
hearing threshold and pain threshold in frequency range of 16 - 20 000 Hz is called the hearing
field.

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Hearing field with equal loudness contours
frequency

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Loudness level of some sounds
Sort of sound
Loudness level [Ph]
whispering
10 - 20
Forest silence
20 - 30
Normal speech
40 - 60
Traffic noise
60 - 90
Pneumatic drill
100 - 110
Jet propulsion
120 - 130
rozhovor dvojice les auta jet horník

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Sound spectrum
Phoniatrics excursion:
After analysis of compound sounds, we obtain frequency distribution of amplitudes and phases of
their components - the acoustic spectrum.
In vowels: band spectrum. Harmonic frequencies of a basic tone form groups - formants - for given
vowel are characteristic.
The consonants are non-periodic, but they have continuous (noise) acoustic spectrum.
vojabb2
A
E
I
O
U
•http://web.inter.nl.net/hcc/davies/vojabb2.gif

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Biophysical function of the ear
The ear consists of outer, middle and inner ear.
̶Transmission of sounds into inner ear is done by outer and middle ear.
̶Outer ear: auricle (ear pinna) and external auditory canal. Optimally audible sounds come
frontally under the angle of about 15° measured away the ear axis.
̶Auditory canal is a resonator. It amplifies the frequencies
2-6 kHz with maximum in range of 3-4 kHz, (+12 dB). The canal closure impairs the hearing by 40 -
60 dB.
̶Middle ear consists of the ear-drum (~ 60 mm2) and the ossicles – maleus (hammer), incus (anvil)
and stapes (stirrup). Manubrium malei is connected with drum, stapes with foramen ovale (3 mm2).
Eustachian tube equalises the pressures on both sides of the drum.
̶A large difference of acoustic impedance of the air (3.9 kPa·s·m-1) and the liquid in inner ear
(15 700 kPa·s·m-1) would lead to large intensity loss (about 30 dB). It is compensated by the ratio
of mentioned areas and by the change of amplitude and pressure of acoustic waves (sound waves of
the same intensity have large amplitudes and low pressure in the air, small amplitudes and high
pressure in a liquid). Transmission of acoustic oscillations from the drum to the smaller area of
oval foramen increases pressure 20x.

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Lever system of ossicles
Protection against strong sounds: Elastic connection of ossicles and reflexes of muscles (mm.
stapedius, tensor tympani) can attenuate hearing of strong sounds by 15 dB.
tt
Maleus and incus form an unequal lever (force acting on stapes and the oval window increases
1.3-times).

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Mechanism of reception of acoustic signals
̶The inner ear is inside the petrous bone and contains the receptors of auditory and vestibular
analyser.
̶The auditory part is formed by a spiral, 35 mm long bone canal - the cochlea. The basis of cochlea
is separated from the middle ear cavity by a septum with two foramina.
̶The oval foramen is connected with stapes, the circular one is free.
̶Cochlea is divided into two parts by longitudinal osseous lamina spiralis and elastic membrana
basilaris. Lamina spiralis is broadest at the basis of cochlea, where the basilar membrane is
narrowest, about 0.04  mm (0.5 mm at the top of cochlea).
̶The helicotrema connects the space above (scala vestibuli) and below the basilar membrane (scala
tympani).

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Organ of Corti
orgcorti2
•http://www.sfu.ca/~saunders/l33098/Ear.f/corti.html
Lamina
 spiralis

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www.sickkids.on.ca/auditorysciencelab/ pictures1.asp.
Cochturn haircells
Pictures obtained from SEM. Organ of Corti with rows of hair-cells. Above general view after
removal of vestibular (Reissner)  and tectorial membrane. Right a detail of hair-cells.
[USEMAP]

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Organ of Corti
̶Perilymph - ionic composition like liquor, but it has 2x more proteins. Endolyph - protein content
like liquor, but only 1/10 of Na+ ions and 30x more K+ ions - like intracellular liquid.
̶Sensory cells of Corti's organ: hair-cells (inner and outer). In cochlea there are about 4000
inner and about 20000 outer hair-cells.
̶sensory hairs (cilia) - stereocilia, deformed by tectorial membrane. Bending of hairs towards
lamina spiralis leads to depolarisation, bending away lamina spiralis causes hyperpolarisation.
̶Periodic stimulation of outer cells causes their active oscillations with the same frequency.
These oscillations are transmitted through the tectorial membrane to the inner hair cells.
Therefore the (sound) oscillations are amplified.
̶About 95% neurons begin on inner cells (20 axons on one inner cell), about 5% neurons begin on
outer cells - nerve-endings of 10 outer cells are connected in 1 axon. There are about 25 - 30 000
axons in auditory nerve.

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Mechanism of sound perception: Békésy theory of travelling wave.
̶Békésy theory of travelling wave: Sound brings the basilar membrane into oscillations, and the
region of maximum oscillation shifts with increasing frequency from the top to the basis of
cochlea.
̶The receptor system in cochlea performs probably a preliminary frequency analysis. The further
processing is done in cerebral auditory centres.
̶Sound comes to the receptors in three ways: air (main), bone (the hearing threshold is by about 40
dB higher) and through circular foramen – small importance.

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Electric phenomena in sound reception:
̶Perilymph and endolymph differ in content of K+ and Na+. Endolymph content of K+ is near to the
intracellular content. The resting potential between endolymph and perilymph equals + 80 mV -
endocochlear potential.
̶The big hair-cells of Corti's organ have a negative potential -80 mV against the periplymph. The
potential difference between the endolymph and hair-cells is about 160 mV.
̶The stimulation of Corti's organ leads to cochlear microphone potential, which can be measured
directly on cochlea or in its close surroundings. At high frequencies, the maximum of microphone
potential shifts to the basis of cochlea, what is in agreement with the theory of travelling wave.
̶Negative summation potential is caused by stimulation of inner hair-cells of Corti's organ.
̶The mechanism of the origin of final action potential led by auditory nerve is not yet fully
explained. We suppose: The cochlear microphone potential and also the negative summation potential
take place directly in action potential origin. This potential keeps the receptors in functional
state.

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Otoacoustic emission
̶The inner ear itself is a source of sound which can appear immediately after external acoustic
stimulation or spontaneously. These sounds are very weak – most people do not hear them. They arise
by oscillations of outer hair cells at a frequency of 500 – 4500 Hz.
̶The otoacoustic emission is examined mainly in newborns. If present – hearing is probably normal.
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13905_Figure1

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Biophysical function of vestibular system
̶Vestibular system - organ of position and balance sense - placed in the semicurcular canals in
petrous bone lying in three mutually perpendicular planes. The canals start in utricle, which is
connected with sacculus. Both parts are placed in vestibulum communicating with ductus cochlearis.
̶One outlet of each canal is transformed in ampulla, divided by the ampullary crist into two parts.
Macula utriculi is in the lower part of utricle, the macula sacculi in sacculus. The crists and
ampullae are covered by sensory epithelium composed of hair-cells. There are also gelatinous
cupulae on ampullary crists and the statoconia membranes in maculae. Their function is to stimulate
stereocilia of sensory cells. The statoconia are crystals of CaCO3 - it increases the mass of
gelatinous membranes.

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̶The semicircular canals allow analyse the rotational motion of the head. Receptors of ampullary
crists react on angular acceleration. The cupulas of crists work as valves, which are deflected by
streaming endolymph and stimulate the hairs of sensory cells by bending – depolarisation or
hyperpolarisation takes place.
̶The receptors of utricle and sacculus react on linear acceleration and gravitation. When changing
the head position, the membrane with statoconia shifts against hairs of sensory cells - excitation
arises. Important for keeping erect position - static reflexes.
̶
Biophysical function of vestibular system

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Vestibular organ
innerearlabyrinth
•http://www.driesen.com/innerearlabyrinth.jpg

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Function of crists and cupullae
•http://www.bcm.tmc.edu/oto/studs/rotation.gif
crista1
•http://cellbio.utmb.edu/microanatomy/Ear/crista1.jpg

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Statoconia membrane in sacculus
macula3.jpg (75179 bytes)
•cellbio.utmb.edu/.../Ear/ organization_of_the_inner_ear.htm.

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Author:
Vojtěch Mornstein
Content collaboration and language revision:
Ivo Hrazdira, Carmel J. Caruana
Last revision September 2024