1. Can a moth evade a bat in the dark?
Figure 50.1 Can a moth evade a bat in the dark?

2. Sensory receptors in human skin
Heat
Gentle touch
Pain
Cold
Hair
Epidermis
Dermis
Figure 50.3 Sensory receptors in human skin
Hypodermis
Nerve
Connective tissue
Hair movement
Strong pressure

3. Chemoreceptors in an insect
Figure 50.4
0.1 mm

4. Specialized electromagnetic receptors
Eye
Infrared receptor
(a) Rattlesnake – infrared receptors detect body heat of prey
Figure 50.5
(b) Beluga whales sense Earth’s magnetic field – as they navigate migrations.

5. Ciliated receptor cells
The statocyst of an invertebrate
Ciliated receptor cells
Cilia
Statolith
Figure 50.6
Sensory axons

6. Many arthropods sense sounds with body hairs that vibrate or with localized “ears” consisting of a tympanic membrane and receptor cells
Figure 50.7 An insect “ear”—on its leg
Tympanic membrane
1 mm

7. Human Ear Figure 50.8 The structure of the Middle ear Outer ear
Inner ear
Skull bone
Stapes
Semicircular canals
Incus
Malleus
Auditory nerve to brain
Cochlear duct
Bone
Auditory nerve
Vestibular canal
Tympanic canal
Cochlea
Oval window
Eustachian tube
Pinna
Auditory canal
Tympanic membrane
Round window
Organ of Corti
Tectorial membrane
Hair cells
Figure 50.8 The structure of the
Hair cell bundle from a bullfrog; the longest cilia shown are about 8 µm (SEM).
Basilar membrane
Axons of sensory neurons
To auditory nerve

8. Sensory reception by hair cells.
“Hairs” of hair cell
Neuro- trans- mitter at synapse
More neuro- trans- mitter
Less neuro- trans- mitter
Sensory neuron
–50
–50
Receptor potential
–50
–70
–70
–70
Membrane potential (mV)
Membrane potential (mV)
Membrane potential (mV)
Action potentials
Signal
Signal
Signal
–70
–70
–70
Figure
Time (sec)
Time (sec)
Time (sec)
(a) No bending of hairs
(b) Bending of hairs in one direction
(c) Bending of hairs in other direction

9. Organs of equilibrium in the inner ear
Semicircular canals
Flow of fluid
Vestibular nerve
Cupula
Hairs
Hair cells
Vestibule
Figure 50.11
Axons
Utricle
Body movement
Saccule

10. The lateral line system in a fish has mechanorecptors that sense water movement
Surrounding water
Scale
Lateral line canal
Opening of lateral line canal
Cupula
Epidermis
Sensory hairs
Figure
Hair cell
Supporting cell
Segmental muscles
Lateral nerve
Axon
Fish body wall

11. Smell in humans Brain Olfactory bulb Odorants Nasal cavity Bone
Action potentials
Olfactory bulb
Odorants
Nasal cavity
Bone
Epithelial cell
Odorant receptors
Chemo- receptor
Figure 50.15
Plasma membrane
Cilia
Odorants
Mucus

12. Eye cup of planarians provides information about light intensity and direction but does not form images.
Ocellus
Light
Figure Ocelli and orientation behavior of a planarian
Photoreceptor
Nerve to brain
Visual pigment
Screening pigment
Ocellus

13. Compound eyes (a) Fly eyes Cornea Lens Crystalline cone Rhabdom
2 mm
(a) Fly eyes
Cornea
Lens
Crystalline cone
Rhabdom
Figure 50.17
Photoreceptor
Axons
Ommatidium
(b) Ommatidia

14. Fovea = center of visual field
Vertebrate Eye
Sclera
Choroid
Retina
Ciliary body
Fovea = center of visual field
Suspensory ligament
Cornea
Optic nerve
Iris
Pupil
Aqueous humor
Figure 50.18
Lens
Central artery and vein of the retina
Vitreous humor
Optic disk (blind spot)

15. Humans and other mammals focus light by changing the shape of the lens.
Ciliary muscles relax.
Ciliary muscles contract.
Choroid
Suspensory ligaments pull against lens.
Suspensory ligaments relax.
Retina
Lens becomes thicker and rounder.
Lens becomes flatter.
Figure Focusing in the mammalian eye
(a) Near vision (accommodation)
(b) Distance vision

16. Membrane potential (mV)
Receptor potential production in a rod cell
INSIDE OF DISK
EXTRACELLULAR FLUID
Light
Disk membrane
Active rhodopsin
Phosphodiesterase
Plasma membrane
CYTOSOL
Sodium channel
cGMP
Inactive rhodopsin
Transducin
GMP
Na+
Dark
Figure Receptor potential production in a rod cell
Light
Membrane potential (mV)
–40
Hyper- polarization
Na+
–70
Time

17. Neural pathways for vision
Right visual field
Optic chiasm
Right eye
Left eye
Figure 50.24
Left visual field
Optic nerve
Primary visual cortex
Lateral geniculate nucleus

18. Skeletal Muscle Thick filaments myosin Thin filaments actin
Bundle of muscle fibers
Nuclei
Single muscle fiber (cell)
Plasma membrane
Myofibril
Z lines
Sarcomere
Figure The structure of
TEM
0.5 µm
M line
Thick filaments myosin
Thin filaments actin
Z line
Z line
Sarcomere

19. The sliding-filament model of muscle contraction
Sarcomere
0.5 µm Z M Z
Relaxed muscle
Contracting muscle
Fully contracted muscle
Figure 50.26
For the Cell Biology Video Conformational Changes in Calmodulin, go to Animation and Video Files.
For the Cell Biology Video Cardiac Muscle Contraction, go to Animation and Video Files.
Contracted Sarcomere

20. Myosin-actin interactions underlying muscle fiber contraction
Thick filament
Myosin-actin interactions underlying muscle fiber contraction
Thin filaments
Thin filament
Myosin head (low- energy configuration
ATP
ATP
Thick filament
Myosin binding sites
Thin filament moves toward center of sarcomere.
Actin
Myosin head (low- energy configuration
ADP
Myosin head (high- energy configuration
P i
Figure Myosin-actin interactions underlying muscle fiber contraction
ADP
ADP +
P i
P i
Cross-bridge

21. (a) Myosin-binding sites blocked
Tropomyosin
Ca2+-binding sites
Actin
Troponin complex
(a) Myosin-binding sites blocked
Ca2+
Figure The role of regulatory proteins and calcium in muscle fiber contraction
Myosin- binding site
(b) Myosin-binding sites exposed when Ca2+ released.

22. Ca2+ Regulation of skeletal muscle contraction
Synaptic terminal of motor neuron
Synaptic cleft
T Tubule
Plasma membrane
ACh SR
Ca2+ ATPase pump
Ca2+
ATP
CYTOSOL
Figure 50.29b The
Ca2+
ADP
P i

23. Spinal cord Motor unit 1 Motor unit 2 Synaptic terminals Nerve
Motor units in a vertebrate skeletal muscle
Spinal cord
Motor unit 1
Motor unit 2
Synaptic terminals
Nerve
Motor neuron cell body
Motor neuron axon
Figure 50.30
Muscle
Muscle fibers
Tendon

24. Summation of twitches Tetanus Summation of two twitches Tension
Single twitch
Figure 50.31
Time
Action potential
Pair of action potentials
Series of action potentials at high frequency

25. The interaction of antagonistic muscles and skeletons in movement
Human
Grasshopper
Extensor muscle relaxes
Biceps contracts
Tibia flexes
Flexor muscle contracts
Forearm flexes
Triceps relaxes
Biceps relaxes
Extensor muscle contracts
Tibia extends
Figure 50.32
For the Discovery Video Muscles and Bones, go to Animation and Video Files.
Forearm extends
Flexor muscle relaxes
Triceps contracts

26. Crawling by peristalsis
Longitudinal muscle relaxed (extended)
Circular muscle contracted
Circular muscle relaxed
Longitudinal muscle contracted
Bristles
Head end
Head end
Figure 50.33
Head end

27. Bones and joints of the human skeleton
Head of humerus
Examples of joints
Skull
Scapula 1
Clavicle
Shoulder girdle
Scapula
Sternum 1
Ball-and-socket joint
Rib 2
Humerus 3
Vertebra
Radius
Ulna
Humerus
Pelvic girdle
Carpals
Ulna
Phalanges
Metacarpals
Figure 50.34 2
Hinge joint
Femur
Patella
Tibia
Fibula
Ulna
Radius
Tarsals Metatarsals Phalanges 3
Pivot joint

28. Energy-efficient locomotion on land
Figure 50.35

29. You should now be able to:
Distinguish between the following pairs of terms: sensation and perception; sensory transduction and receptor potential; tastants and odorants; rod and cone cells; oxidative and glycolytic muscle fibers; slow-twitch and fast-twitch muscle fibers; endoskeleton and exoskeleton.
List the five categories of sensory receptors and explain the energy transduced by each type.

30. Explain the role of mechanoreceptors in hearing and balance.
Give the function of each structure using a diagram of the human ear.
Explain the sliding-filament model of muscle contraction.
Explain how a skeleton combines with an antagonistic muscle arrangement to provide a mechanism for movement.