| File | Title | Manuscript Id |
|---|
| Chapter Introduction | life11e_ch45_1.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_1_dlap.xml | 57f5e72b757a2e3f5e000000 |
| key concept 45.1 Sensory Receptor Cells Convert Stimuli into Action Potentials
| life11e_ch45_2.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_2_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Sensory transduction involves changes in membrane potentials
| life11e_ch45_3.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_3_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Sensory receptor proteins act on ion channels
| life11e_ch45_4.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_4_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Sensation depends on which neurons receive action potentials from sensory cells
| life11e_ch45_5.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_5_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Many receptors adapt to repeated stimulation
| life11e_ch45_6.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_6_dlap.xml | 57f5e72b757a2e3f5e000000 |
| recap | life11e_ch45_7.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_7_dlap.xml | 57f5e72b757a2e3f5e000000 |
| key concept 45.2 Chemoreceptors Respond to Specific Molecules
| life11e_ch45_8.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_8_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Olfaction is the sense of smell
| life11e_ch45_9.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_9_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Some chemoreceptors detect pheromones
| life11e_ch45_10.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_10_dlap.xml | 57f5e72b757a2e3f5e000000 |
| The vomeronasal organ contains chemoreceptors
| life11e_ch45_11.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_11_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Gustation is the sense of taste
| life11e_ch45_12.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_12_dlap.xml | 57f5e72b757a2e3f5e000000 |
| recap | life11e_ch45_13.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_13_dlap.xml | 57f5e72b757a2e3f5e000000 |
| key concept 45.3 Mechanoreceptors Respond to Physical Forces
| life11e_ch45_14.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_14_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Many different receptor cells respond to touch and pressure
| life11e_ch45_15.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_15_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Mechanoreceptors are also found in muscles, tendons, and ligaments
| life11e_ch45_16.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_16_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Hair cells are mechanoreceptors of the auditory and vestibular systems
| life11e_ch45_17.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_17_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Auditory systems use hair cells to sense sound waves
| life11e_ch45_18.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_18_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Flexion of the basilar membrane is perceived as sound
| life11e_ch45_19.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_19_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Various types of damage can result in hearing loss
| life11e_ch45_20.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_20_dlap.xml | 57f5e72b757a2e3f5e000000 |
| The vestibular system uses hair cells to detect forces of gravity and momentum
| life11e_ch45_21.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_21_dlap.xml | 57f5e72b757a2e3f5e000000 |
| recap | life11e_ch45_22.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_22_dlap.xml | 57f5e72b757a2e3f5e000000 |
| key concept 45.4 Photoreceptors Respond to Light
| life11e_ch45_23.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_23_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Invertebrates have a variety of visual systems
| life11e_ch45_24.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_24_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Image-forming eyes evolved independently in vertebrates and cephalopods
| life11e_ch45_25.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_25_dlap.xml | 57f5e72b757a2e3f5e000000 |
| The vertebrate retina receives and processes visual information
| life11e_ch45_26.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_26_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Opsins are the universal photoreceptor molecule in animals
| life11e_ch45_27.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_27_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Rod and cone cells are the photoreceptors of the vertebrate retina
| life11e_ch45_28.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_28_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Information flows through layers of neurons in the retina
| life11e_ch45_29.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_29_dlap.xml | 57f5e72b757a2e3f5e000000 |
| recap | life11e_ch45_30.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_30_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Investigating Life | life11e_ch45_31.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_31_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Chapter Summary
| life11e_ch45_32.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_32_dlap.xml | 57f5e72b757a2e3f5e000000 |
| Apply What You’ve Learned
| life11e_ch45_33.html | 57f5e72b757a2e3f5e000000 |
| DLAP questions | life11e_ch45_33_dlap.xml | 57f5e72b757a2e3f5e000000 |