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Sensory Systems

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Title: Sensory Systems


1
Sensory Systems
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2
Sensory Systems
  • Sensory Cells Transduction of Stimuli into
    signals for nervous system. Modified neurons
  • 1. Chemoreceptors Responding to Specific
    Molecules
  • 2. Mechanoreceptors Detecting Stimuli that
    Distort Membranes
  • 3. Photoreceptors and Visual Systems Responding
    to Light

3
Figure 45.1 Sensory Cell Membrane Receptor
Proteins Respond to Stimuli
1. Mechanoreceptor
2. Chemoreceptor
3. Photoreceptor
4
Sensory Cells and Transduction of Stimuli
  • Sensory cells have
  • membrane receptor proteins that detect a stimulus
    and respond by altering the flow of ions across
    the plasma membrane.
  • The resulting change in membrane potential causes
    the sensory cell to fire action potentials or to
    change its secretion of a neurotransmitter onto
    an associated neuron that fires action
    potentials.
  • The intensity of the stimulus is encoded in the
    frequency of the action potentials produced.
  • Simply depolarization events in sensory cell,
    interpreted in different ways according to the
    different places in the CNS.

5
Sensory Cells and Transduction of Stimuli
  • Some information is sensed without our being
    conscious of it.
  • levels of CO2, blood sugar, and O2. important
    for the maintenance of homeostasis.
  • Sensory cells and other types of cells form
    sensory organs, such as eyes, ears, and noses.
  • Sensory systems
  • the sensory cells the associated structures
    neuronal networks that process the
    information.

6
Sensory Cells and Transduction of Stimuli
  • In ionotropic sensory detection, the receptor
    protein itself is part of the ion channel and, by
    changing its conformation, opens or closes the
    channel pore.
  • In metabotropic sensory detection, the receptor
    protein is linked to a G protein that activates a
    cascade of intracellular events that eventually
    open or close ion channels.
  • The affected receptor ? action potential ?
    nervous system.
  • stimulus ? change in the resting membrane
    potential of a sensory cell receptor potential

7
Figure 45.2 Stimulating a Sensory Cell Produces
a Receptor Potential
8
Sensory Cells and Transduction of Stimuli
  • Primary sensory cells generate action potentials
    directly. An example is the crayfish stretch
    receptor.
  • Secondary sensory cells generate action
    potentials indirectly by inducing the release of
    neurotransmitter.
  • Adaptation
  • respond less when stimulation is repeated

9
ChemoreceptorsResponding to Specific Molecules
  • Chemoreceptors
  • detect chemical stimuli.
  • Chemoreceptors are responsible for smell and
    taste, and for monitoring internal environmental
    factors such as CO2 and O2 in the blood.
  • Corals, for example, can detect protein or even a
    single type of amino acid, causing them to extend
    tentacles in search of food.

10
Figure 45.3 Some Scents Travel Great Distances
(Part 1)
  • Pheromones - chemical signals to attract mates.
  • Female silkworm moths pheromone (bombykol) from
    glands at the tip of the abdomen, and males have
    its receptors on their antennae.
  • A single molecule can stimulate a perceivable
    action potential!! Activated 200 hairs or more /
    second ? looking for female.

11
ChemoreceptorsResponding to Specific Molecules
  • Chemoreceptor Olfaction.
  • In vertebrates, olfactory sensors in epithelial
    cells at the top of the nasal cavity.
  • The axons of these sensors project to the
    olfactory bulb of the brain.
  • The dendrites end in olfactory hairs at the
    surface of the nasal epithelium.

12
Figure 45.4 Olfactory Receptors Communicate
Directly with the Brain (Part 1)
13
Figure 45.4 Olfactory Receptors Communicate
Directly with the Brain (Part 2)
14
ChemoreceptorsResponding to Specific Molecules
  • Odorants?
  • Each olfactory receptor protein particular
    odorant molecules activates a G protein.
  • The G protein ? activates an enzyme ? a second
    messenger, such as cAMP.
  • The second messenger ? sodium channels open ?
    influx of Na ? depolarizes the membrane ? action
    potential

15
ChemoreceptorsResponding to Specific Molecules
  • How to distinguish the odorants?
  • The number of odorant molecules vs. the number of
    different receptor proteins.
  • Specific receptor protein? Combination?
  • Odor, strong ? more odorant molecules

16
ChemoreceptorsResponding to Specific Molecules
  • Vomeronasal organ (VNO) is
  • a small, paired tubular structure embedded in the
    nasal epithelium.
  • Chemoreceptors of the VNO.
  • VNO chemoreceptors ? an accessory olfactory bulb
    ? brain region for sexual and other instinctive
    behaviors.
  • Detect pheromone (mice)

17
ChemoreceptorsResponding to Specific Molecules
  • Gustation
  • the sense of taste, depends on clusters of
    sensory cells called taste buds.
  • Humans have 10,000 taste buds embedded in the
    epithelium of the tongue.
  • Many are in raised papillae, the small bumps on
    human tongues.
  • The sensory cells form synapses with dendrites of
    sensory neurons.

18
Figure 45.5 Taste Buds Are Clusters of Sensory
Cells
19
ChemoreceptorsResponding to Specific Molecules
  • Receptor proteins in the microvilli bind specific
    molecules. This causes the release of
    neurotransmitters to the dendrites of associated
    sensory neurons.
  • Taste buds are replaced every few days, but the
    associated neurons live on.
  • Taste buds can distinguish sweet, salty, sour,
    and bitter tastes.
  • Recently the savory meaty taste umami has been
    added to the list of distinguishable tastes.

20
MechanoreceptorsDetecting Stimuli that Distort
Membranes
  • Mechanoreceptors
  • sensitive to mechanical forces
  • skin sensations and sensing blood pressure.
  • Physical distortion of a mechanoreceptors plasma
    membrane causes ion channels to open.
  • The rate of the action potentials is related to
    the strength of the stimulus.
  • Fingertips sensitive finer spatial
    discrimination, much more dense mechanoreceptors

21
Figure 45.6 The Skin Feels Many Sensations
Skin - diverse mechanoreceptors
Non-hairy skin
Low frequency
Higher frequency
22
MechanoreceptorsDetecting Stimuli that Distort
Membranes
  • Stretch receptors
  • Position of its limbs and stresses on its
    muscles and joints.
  • 1. muscle spindles in muscle
  • muscle tone.

2. Golgi tendon organ tendons and ligaments.
prevent excessive force
23
Figure 45.7 Stretch Receptors Are Activated when
Limbs Are Stretched (Part 1)
24
Figure 45.7 Stretch Receptors Are Activated when
Limbs Are Stretched (Part 2)
25
MechanoreceptorsDetecting Stimuli that Distort
Membranes
  • Hair cells - mechanoreceptors.
  • Each hair cell has a set of stereocilia
    (microvilli).
  • When the stereocilia are bent in one direction,
    receptor potential becomes more negative when
    they are bent in the other direction, it becomes
    more positive.
  • When the membrane potential becomes more
    positive, the hair cell releases a
    neurotransmitter to the sensory neuron associated
    with it, and the sensory neuron sends action
    potentials to the CNS.

26
MechanoreceptorsDetecting Stimuli that Distort
Membranes
  • Hair cells are found in the lateral line system
    of fishes, providing information about movement
    through the water and moving objects that cause
    pressure waves in water.
  • Semicircular canals and the vestibular apparatus
    in the mammalian inner ear use hair cells to
    detect position and orientation of the head, as
    well as acceleration produced by movement.

27
Figure 45.8 The Lateral Line System Contains
Mechanoreceptors
28
Figure 45.9 Organs in the Inner Ear of Mammals
Provide the Sense of Equilibrium (Part 1)
29
Figure 45.9 Organs in the Inner Ear of Mammals
Provide the Sense of Equilibrium (Part 2)
30
MechanoreceptorsDetecting Stimuli that Distort
Membranes
  • Auditory systems
  • Use mechanoreceptors to convert pressure waves
    into action potentials.
  • Pinnae collect sound waves and direct them into
    the auditory canal, which leads to the middle
    inner ear.
  • The eardrum (tympanic membrane) covers the end of
    the auditory canal and vibrates in response to
    pressure waves.
  • Pressure on both sides of the eardrum
    equilibrates because the Eustachian tube allows
    airflow.

31
Figure 45.10 Structures of the Human Ear (Part 1)
32
MechanoreceptorsDetecting Stimuli that Distort
Membranes
  • Ossicles (the malleus, incus, and stapes) to oval
    window. 20 times amp.
  • Behind the oval window is the fluid-filled inner
    ear. Movements of the oval window result in
    pressure changes in the inner ear.
  • The inner ear, cochlea
  • three parallel canals
  • two membranes, Reissners membrane and the
    basilar membrane.

33
Figure 45.10 Structures of the Human Ear (Part 2)
  • The organ of Corti rests on the basilar membrane.
  • The organ of Corti contains hair cells whose
    stereocilia are in contact with the tectorial
    membrane.

34
Figure 45.10 Structures of the Human Ear (Part 3)
35
MechanoreceptorsDetecting Stimuli that Distort
Membranes
  • What causes the basilar membrane to flex?
  • The cochlea is filled with fluid and the upper
    and lower canals are connected at the distal end.
    Pressure waves displace the fluid in the upper
    canal of the cochlea.
  • Instead of traveling all the way around the
    canals, the waves of fluid cross the basilar
    membrane, causing it to flex.
  • High frequency causes the basilar membrane
    nearest the oval window to flex.
  • Low frequency causes flexing farther down the
    membrane.

36
Figure 45.11 Sensing Pressure Waves in the Inner
Ear (Part 1)
22,000 Hz
3,000 Hz
37
MechanoreceptorsDetecting Stimuli that Distort
Membranes
  • Deafness has two general causes
  • Conduction deafness is loss of function of the
    tympanic membrane or ossicles of the middle ear.
    The ossicles stiffen with age causing loss of
    ability to hear high frequency sound.
  • Nerve deafness is caused by inner ear or auditory
    pathway damage, including damage to hair cells.
  • Loud music or noises can cause damage to hair
    cells. This damage is cumulative and permanent.

38
Photoreceptors and Visual Systems Responding to
Light
  • Photosensensation
  • the sensitivity to light.
  • It ranges from the ability to orient to the sun
    to the ability to see.
  • Rhodopsins photosensitivity molecules in all
    animal species. a family of pigments

39
Photoreceptors and Visual Systems Responding to
Light
  • Rhodopsin molecules can absorb photons of light
    and undergo shape changes.
  • Rhodopsin molecules consist of a protein called
    opsin and a light-absorbing group,
    11-cis-retinal.
  • When 11-cis-retinal absorbs a photon, it changes
    to all-trans-retinal, which changes the
    conformation of the opsin. This change signals
    detection of light.
  • The all-trans back to cis- form of retinal.
    photoexcited rhodopsin ? membrane potential.

40
Figure 45.12 Rhodopsin A Photosensitive Molecule
41
Figure 45.13 A Rod Cell Responds to Light
  • A rod cell is a modified neuron.

rhodopsin
Dark depolarize
mitochondria
Light hyperpolarize
42
Photoreceptors and Visual Systems Responding to
Light
  • When light is absorbed by rhodopsin, it becomes
    photoexcited and activates a G protein called
    transducin.
  • The activated transducin activates a
    phosphodiesterase, which converts cGMP to GMP.
  • cGMP keeps sodium channels open in light, GMP
    levels rise and channels close.

43
Figure 45.14 Light Absorption Closes Sodium
Channels (Part 1)
At Dark
44
Figure 45.14 Light Absorption Closes Sodium
Channels (Part 2)
By Light
45
Photoreceptors and Visual Systems Responding to
Light
  • The advantage of this system is that it amplifies
    the signal.
  • Each single photon can cause activation of
    several hundred transducin molecules, which in
    turn, activate many phosphodiesterase molecules.
  • A single photon can close a huge number of sodium
    channels.

46
Figure 45.15 Ommatidia The Functional Units of
Insect Eyes
  • Arthropods have compound eyes consisting of many
    optical units called ommatidia.

47
Photoreceptors and Visual Systems Responding to
Light
  • Both vertebrates and cephalopod mollusks have
    highly evolved eyes.
  • Vertebrate eyes are fluid-filled spheres bound by
    tough connective tissue called sclera.
  • A transparent cornea in the front allows light
    passage.
  • Inside the cornea is the pigmented iris, which
    controls the amount of light that can enter.
  • The pupil is the region where light enters.
  • The lens makes fine adjustments in the focus of
    images on the photosensitive retina at the back
    of the eye.

48
Figure 45.16 Eyes Like Cameras
49
Photoreceptors and Visual Systems Responding to
Light
  • The most sensitive area of the retina is the
    fovea.
  • The lenses allow the eyes to focus light.
  • Fishes, amphibians, and reptiles focus by moving
    the lenses of their eyes closer to or farther
    from their retinas.
  • Mammals and birds alter the shape of the lens to
    focus.

50
Figure 45.17 Staying in Focus
51
Photoreceptors and Visual Systems Responding to
Light
  • The shape of the lens changes due to the action
    of two structures.
  • Connective tissue surrounding the lens keeps it
    spherical, but suspensory ligaments pull it into
    a flatter shape.
  • Ciliary muscles counteract the pull of the
    ligaments and allow the lens to become round.
  • The flatter lens is able to focus distant images
    but not nearer ones, which need the light-bending
    properties of the round lens to bring close
    images into focus.
  • Lenses become less elastic with age and we lose
    the ability to focus on objects close at hand.

52
Photoreceptors and Visual Systems Responding to
Light
  • The retina includes layers of cells that process
    visual information from the photoreceptors and
    produce an output signal that is transmitted via
    the optic nerve.
  • Light must pass through all the layers of cells
    before photons are captured by rhodopsin.
  • There are two types of vertebrate photoreceptors
    cones and rods.
  • Rod cells are more sensitive to light. Cone cells
    respond to different wavelengths of light for
    color vision.
  • Cones also provide the sharpest vision. The fovea
    has only cone cells.

53
Photoreceptors and Visual Systems Responding to
Light
  • Humans have three kinds of cone cells One type
    absorbs violet and blue wavelengths, one absorbs
    green, and one absorbs yellow and red.
  • The human fovea has about 160,000 cone cells per
    square millimeter a hawk has 1,000,000.
  • Hawks also have two foveas per eye and can see
    both their flight path and the ground below.
  • There are no photoreceptors where blood vessels
    and bundles of axons going to the brain pass
    through the back of the eye. This creates a blind
    spot on the retina.

54
Figure 45.19 Absorption Spectra of Cone Cells
55
Photoreceptors and Visual Systems Responding to
Light
  • The human retina is organized into five layers of
    cells.
  • Cells at the front of the retina are ganglion
    cells. They fire action potentials and their
    axons form the optic nerves.
  • The photoreceptor cells are at the back of the
    retina. Ganglion cells and photoreceptors are
    connected by bipolar cells.
  • Photoreceptor cells ? bipolar cells ? ganglion
    cells

56
Figure 45.20 The Retina
57
Photoreceptors and Visual Systems Responding to
Light
  • Horizontal cells connect neighboring pairs of
    photoreceptors and bipolar cells.
  • This provides a means for the lateral flow of
    information.
  • Amacrine cells connect neighboring pairs of
    bipolar cells and ganglion cells.
  • These help make eyes more sensitive to small but
    rapid changes.

58
Photoreceptors and Visual Systems Responding to
Light
  • Each ganglion cell has a well-defined receptive
    field, which consists of a specific group of
    photoreceptor cells.
  • This integrates the light signal into one output.
  • The receptive field of a ganglion cell can be
    divided into two concentric areas, called the
    center and the surround.

59
Photoreceptors and Visual Systems Responding to
Light
  • There are two kinds of receptive fields
    on-center and off-center.
  • Ganglia with on-center receptive fields are
    maximally excited by light falling on the center.
  • Ganglia with off-center receptive fields are
    maximally stimulated by light falling on the
    surround.
  • Center effects are always stronger than surround
    effects.
  • The photoreceptors in the center of the receptive
    field of a ganglion cell are connected to that
    ganglion via bipolar cells.

60
Figure 45.21 What Does the Eye Tell the Brain?
(Part 1)
61
Figure 45.21 What Does the Eye Tell the Brain?
(Part 2)
62
Sensory Worlds Beyond Human Experience
Other animals?
  • Some species can see infrared and ultraviolet
    light.
  • One of the seven photoreceptors in each
    ommatidium of a fruit fly is sensitive to
    ultraviolet light.
  • Some flowers have patterns that are invisible to
    humans but can be seen by flies.
  • Pit vipers have pit organs, one in front of each
    eye, which can sense and locate infrared
    radiation in total darkness.

63
Sensory Worlds Beyond Human Experience
Other animals?
  • Elephants can communicate with infrasound, sounds
    below the range of human hearing.
  • The advantage of using low frequency sound to
    communicate is that it carries over very long
    distances.

64
Sensory Worlds Beyond Human Experience
Other animals?
  • Echolocation is sensing the world through
    reflected sound.
  • Dolphins, bats, and whales can use noises to
    echolocate.
  • They generate sounds at frequencies above human
    hearing.
  • These animals use muscles in the middle ear to
    dampen their sensitivity to sound while they are
    emitting sounds in order to protect their
    hearing.
  • To hear the returning echoes, they relax the
    muscles.

65
Sensory Worlds Beyond Human Experience
Other animals?
  • Some fish can sense electric fields.
  • Lateral lines of some species, such as catfish,
    contain electroreceptors.
  • These enable the fish to detect weak electric
    fields, which helps them locate prey.
  • Some fishes, such as electric fish, can use
    electric fields to navigate. Rocks, plants, and
    other structures disrupt their field and are
    interpreted.
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