15.2 – Anatomy & Physiology of the Sensory System

Audition (Hearing), Equilibrium (Balance), and Somatosensation (Touch)

Watch Hearing & Balance: Crash Course Anatomy & Physiology #17 (11 min) on YouTube

Media 15.2: CrashCourse. (2015, May 4). Hearing & balance: Crash Course anatomy & Physiology #17 [Video]. YouTube. https://youtu.be/Ie2j7GpC4JU

Audition (Hearing)

Hearing, or audition, is the transduction of sound waves into a neural signal that is made possible by the structures of the ear (see Figure 15.1).

The structure of the ear with the major parts labeled. Image description available.
Figure 15.1 Structures of the Ear. The external ear contains the auricle, ear canal, and tympanic membrane. The middle ear contains the ossicles and is connected to the pharynx by the Eustachian tube. The inner ear contains the cochlea and vestibule, which are responsible for audition and equilibrium, respectively. From Betts et al., 2013. Licensed under CC BY 4.0. [Fig. 15.1 Image description.]
  • The external ear consists of the auricle, sometimes referred to as the pinna, ear canal, and tympanic membrane.
    The C-shaped curves of the auricle direct sound waves toward the auditory canal. The canal enters the skull through the external auditory meatus of the temporal bone. At the end of the auditory canal is the tympanic membrane, which vibrates after it is struck by sound waves.
  • The middle ear consists of the ossicles, oval window, and tympanic membrane.
    The three ossicles are the malleus, incus, and stapes, which are Latin names that roughly translate to hammer, anvil, and stirrup. The malleus is attached to the tympanic membrane and articulates with the incus. The incus, in turn, articulates with the stapes. The stapes is then attached to the inner ear, where the sound waves will be transduced into a neural signal. Vibrations of the ossicles travel through the oval window, moving fluid  in a wave-like motion. The frequency of the fluid waves match the frequencies of the sound waves. The middle ear is connected to the pharynx through the Eustachian tube, which helps equilibrate air pressure across the tympanic membrane. The tube is normally closed but will pop open when the muscles of the pharynx contract during swallowing or yawning.
  • The inner ear is often described as a bony labyrinth, as it is composed of a series of canals embedded within the temporal bone.
    It consists of the cochlea which is responsible for hearing and the vestibule that is responsible for balance. The neural signals from these two regions are relayed to the brain stem through separate fiber bundles. However, these two distinct bundles travel together from the inner ear to the brain stem as the vestibulocochlear nerve. Sound is transduced into neural signals within the cochlear region of the inner ear, which contains the sensory neurons of the spiral ganglia. These ganglia are located within the spiral-shaped cochlea of the inner ear. The cochlea is attached to the stapes through the oval window.

The image below is a cross-sectional view of the cochlea that shows the scala vestibuli and scala tympani run along both sides of the cochlear duct (see Figure 15.2). The cochlear duct contains several organs of Corti, which tranduce the wave motion of the two scala into neural signals. The organs of Corti lie on top of the basilar membrane, which is the side of the cochlear duct located between the organs of Corti and the scala tympani. As the fluid waves move through the scala vestibuli and scala tympani, the basilar membrane moves at a specific spot, depending on the frequency of the waves. Higher frequency waves move the region of the basilar membrane that is close to the base of the cochlea. Lower frequency waves move the region of the basilar membrane that is near the tip of the cochlea.

Cross-section of the cochlea. Image description available.
Figure 15.2 Cross Section of the Cochlea. The three major spaces within the cochlea are highlighted. The scala tympani and scala vestibuli lie on either side of the cochlear duct. The organ of Corti, containing the mechanoreceptor hair cells, is adjacent to the scala tympani, where it sits atop the basilar membrane. From Betts et al., 2013. Licensed under CC BY 4.0. [Fig. 15.2 Image description.]

The cochlea encodes auditory stimuli for frequencies between 20 and 20,000 Hz, which is the range of sound that human ears can detect. The unit of Hertz measures the frequency of sound waves in terms of cycles produced per second. Frequencies as low as 20 Hz are detected by hair cells at the apex, or tip, of the cochlea. Frequencies in the higher ranges of 20 KHz are encoded by hair cells at the base of the cochlea, close to the round and oval windows. Most auditory stimuli contain a mixture of sounds at a variety of frequencies and intensities (represented by the amplitude of the sound wave). The hair cells along the length of the cochlear duct, which are each sensitive to a particular frequency, allow the cochlea to separate auditory stimuli by frequency, just as a prism separates visible light into its component colours.

Did You Know?

Sound travels at speed of 1,130 feet per second.

Equilibrium (Balance)

Along with audition, the inner ear is responsible for encoding information about equilibrium. The cells that sense head position, head movement, and body motion are located within the vestibule of the inner ear. Head position is sensed by otolith organs, whereas head movement is sensed by the semicircular canals (see Figure 15.3). The neural signals generated in the vestibular ganglion are transmitted through the vestibulocochlear nerve to the brain stem and cerebellum.

The left panel of this image shows a person’s head in a still position. Underneath this, the ampullary nerve is shown. The right panel shows a person rotating his head, and the below that, the direction of movement of the cupula is shown.
Figure 15.3 Rotational Coding by Semicircular Canals. Rotational movement of the head is encoded by the hair cells in the base of the semicircular canals. As one of the canals moves in an arc with the head, the internal fluid moves in the opposite direction, causing the cupula and stereocilia to bend. The movement of two canals within a plane results in information about the direction in which the head is moving, and activation of all six canals can give a very precise indication of head movement in three dimensions. From Betts et al., 2013. Licensed under CC BY 4.0. [Fig. 15.3 Image description.]

Somatosensation (Touch)

Somatosensation is considered a general sense, as opposed to the special senses discussed in this section. Somatosensation is the group of sensory modalities that are associated with touch, proprioception, and interoception. These modalities include pressure, vibration, light touch, tickle, itch, temperature, pain, proprioception, and kinesthesia. This means that its receptors are not associated with a specialized organ, but are instead spread throughout the body in a variety of organs. Many of the somatosensory receptors are located in the skin, but receptors are also found in muscles, tendons, joint capsules, ligaments, and in the walls of visceral organs.

Did You Know?

With the aging process, humans lose sensory receptors cells including cells which detect pain and temperature changes.

The two types of somatosensory signals that are transduced by free nerve endings are pain and temperature. Temperature receptors are stimulated when local temperatures differ from body temperature. Some thermoreceptors are sensitive to just cold and others to just heat. Nociception is the sensation of potentially damaging stimuli. Mechanical, chemical, or thermal stimuli beyond a set threshold will elicit painful sensations. Stressed or damaged tissues release chemicals that activate receptor proteins in the nociceptors.

​For example, the sensation of heat associated with spicy foods involves capsaicin, the active molecule in hot peppers. Capsaicin molecules bind to a transmembrane ion channel in nociceptors that is sensitive to temperatures above 37°C. The dynamics of capsaicin binding with this transmembrane ion channel is unusual because the molecule remains bound for a long time. Because of this, it will decrease the ability of other stimuli to elicit pain sensations through the activated nociceptor. For this reason, capsaicin can be used as a topical analgesic, such as in products such as Icy Hot™.

Concept Check

  • What structure exists within the ear to assist with maintaining equilibrium?
  • What are the medical terms used to describe the sense of taste and touch?

Sensory System Ear Anatomy

Sensory System Ear Anatomy labeling activity (Text Version)

Label the diagram with correct words listed below:

  1. Parieto-occipital sulcus
  2. Ear canal
  3. Stapes (attached to oval window)
  4. Tympanic cavity
  5. Vestibule
  6. Cochlear nerve
  7. Eustachian tube
  8. Middle ear
  9. Tympanic membrane
  10. Malleus
  11. Incus
  12. Inner ear
  13. Round window
  14. External ear
  15. Cochlea
  16. Vestibular nerve

Illustration showing the view of the human ear. A line extends from structures identifying location.

Check your answers [1]

Activity source: Sensory System Ear Anatomy by Gisele Tuzon, from Building a Medical Terminology Foundationillustration from Anatomy and Physiology (OpenStax)licensed under CC BY 4.0./ Text version added.

Vision (Sight)

Watch Vision: Crash Course Anatomy & Physiology #18 (10 min) on YouTube

Media 15.3: CrashCourse. (2015, May 11). Vision: Crash Course Anatomy & Physiology #18 [Video]. YouTube. https://youtu.be/o0DYP-u1rNM

Vision is the special sense of sight that is based on the transduction of light stimuli received through the eyes. The eyes are located within either orbit in the skull. The bony orbits surround the eyeballs, protecting them and anchoring the soft tissues of the eye (see Figure 15.4). The eyelids, with lashes at their leading edges, help to protect the eye from abrasions by blocking particles that may land on the surface of the eye.

The inner surface of each lid is a thin membrane known as the palpebral conjunctiva. The conjunctiva extends over the sclera, connecting the eyelids to the eyeball. Tears are produced by the lacrimal gland, located beneath the lateral edges of the nose. Tears produced by this gland flow through the lacrimal duct to the medial corner of the eye, where the tears flow over the conjunctiva, washing away foreign particles.

Lateral view of the eye. Image description available.
Figure 15.4 The Eye in the Orbit. The eye is located within the orbit and surrounded by soft tissues that protect and support its function. The orbit is surrounded by cranial bones of the skull. From Betts et al., 2013. Licensed under CC BY 4.0. [Fig. 15.4 Image description.]

Movement of the eye within the orbit is accomplished by the contraction of six extraocular muscles that originate from the bones of the orbit and insert into the surface of the eyeball. Four of the muscles are arranged at the cardinal points around the eye and are named for those locations. They are the:

  1. superior rectus
  2. medial rectus
  3. inferior rectus
  4. lateral rectus

When each of these muscles contract, the eye moves toward the contracting muscle. For example, when the superior rectus contracts, the eye rotates to look up.

The eye itself is a hollow sphere composed of three layers of tissue.

  1. The outermost layer is the fibrous tunic, which includes the white sclera and clear cornea. The sclera accounts for five-sixths of the surface of the eye, most of which is not visible, though humans are unique compared with many other species in having so much of the “white of the eye” visible (see Figure 15.5). The transparent cornea covers the anterior tip of the eye and allows light to enter the eye.
  2. The middle layer of the eye is the vascular tunic, which is mostly composed of the choroid, ciliary body, and iris. The choroid is a layer of highly vascularized connective tissue that provides a blood supply to the eyeball. The choroid is posterior to the ciliary body, a muscular structure that is attached to the lens by zonule fibers. These two structures bend the lens, allowing it to focus light on the back of the eye. Overlaying the ciliary body, and visible in the anterior eye, is the iris—the coloured part of the eye. The iris is a smooth muscle that opens or closes the pupil, which is the hole at the center of the eye that allows light to enter. The iris constricts the pupil in response to bright light and dilates the pupil in response to dim light.
  3. The innermost layer of the eye is the neural tunic, or retina, which contains the nervous tissue responsible for photoreception.

The eye is also divided into two cavities:

  1. The anterior cavity
    • The anterior cavity is the space between the cornea and lens, including the iris and ciliary body. It is filled with a watery fluid called the aqueous humor.
  2. The posterior cavity
    • The posterior cavity is the space behind the lens that extends to the posterior side of the interior eyeball, where the retina is located. The posterior cavity is filled with a more viscous fluid called the vitreous humor.

The retina is composed of several layers and contains specialized cells for the initial processing of visual stimuli. The photoreceptors (rods and cones) change their membrane potential when stimulated by light energy. The change in membrane potential alters the amount of neurotransmitter that the photoreceptor cells release onto bipolar cells in the outer synaptic layer. It is the bipolar cell in the retina that connects a photoreceptor to a retinal ganglion cell (RGC) in the inner synaptic layer. There, amacrine cells additionally contribute to retinal processing before an action potential is produced by the RGC. The axons of RGCs, which lie at the innermost layer of the retina, collect at the optic disc and leave the eye at the optic nerve (see Figure 15.5). Because these axons pass through the retina, there are no photoreceptors at the very back of the eye, where the optic nerve begins. This creates a “blind spot” in the retina, and a corresponding blind spot in our visual field.

Lateral and medial view of eye ball. Image description available.
Figure 15.5. Structure of the Eye. The sphere of the eye can be divided into anterior and posterior chambers. The wall of the eye is composed of three layers: the fibrous tunic, vascular tunic, and neural tunic. Within the neural tunic is the retina, with three layers of cells and two synaptic layers in between. The center of the retina has a small indentation known as the fovea. From Betts et al., 2013. Licensed under CC BY 4.0. [Fig. 15.5 Image description.]

Photoreceptors in the retina (rods and cones) are located behind the axons, RGCs, bipolar cells, and retinal blood vessels. A significant amount of light is absorbed by these structures before the light reaches the photoreceptor cells. At the exact center of the retina is a small area known as the fovea. At the fovea, the retina lacks the supporting cells and blood vessels, and only contains photoreceptors. Therefore, visual acuity, is greatest at the fovea. This is because the fovea is where the least amount of incoming light is absorbed by other retinal structures (see Figure 15.5). As one moves in either direction from this central point of the retina, visual acuity drops significantly.

Example: Visual Acuity (VA)  between the fovea and peripheral retina

The difference in visual acuity between the fovea and peripheral retina is easily evidenced by looking directly at a word in the middle of this paragraph. The visual stimulus in the middle of the field of view falls on the fovea and is in the sharpest focus. Without moving your eyes off that word, notice that words at the beginning or end of the paragraph are not in focus. The images in your peripheral vision are focused by the peripheral retina, and have vague, blurry edges and words that are not as clearly identified. As a result, a large part of the neural function of the eyes is concerned with moving the eyes and head so that important visual stimuli are centered on the fovea.

There are three types of cone opsins, that are sensitive to different wavelengths of light and provide us with colour vision. By comparing the activity of the three different cones, the brain can extract colour information from visual stimuli (see Figure 15.6). For example, a bright blue light that has a wavelength of approximately 450 nm would activate the “red” cones minimally, the “green” cones marginally, and the “blue” cones predominantly. The relative activation of the three different cones is calculated by the brain, which perceives the colour as blue. However, cones cannot react to low-intensity light, and rods do not sense the colour of light. Therefore, our low-light vision is, in essence, in grayscale. In other words, in a dark room, everything appears as a shade of gray. If you think that you can see colours in the dark, it is most likely because your brain knows what colour something is and is relying on that memory.

Colour sensitivity of photopigments. Chart description available.
Figure 15.6 Comparison of Colour Sensitivity of Photopigments. Comparing the peak sensitivity and absorbance spectra of the four photopigments suggests that they are most sensitive to particular wavelengths. From Betts et al., 2013. Licensed under CC BY 4.0. [Fig. 15.6 Image description.]

Sensory Systems Medical Terms, Abbreviations and Anatomy

Sensory System Medical Terms

Sensory System Medical Terms (Text Version)

Practice the following sensory system words by breaking into word parts and pronouncing.

  1. anisocoria (an-ī-sō-KŌR-ē-ă)
    • condition of absence of equal pupil (size)
  2. aphakia (ă-FĀ-kē-ă)
    • condition of no lens
  3. audiogram (OD-ē-ō-gram)
    • graphic record (radiographic image) of hearing
  4. audiologist (od-ē-OL-ŏ-jĭst)
    • specialist who studies and treats the hearing
  5. audiology (od-ē-OL-ŏ-jē)
    • study of the hearing
  6. audiometer (od-ē-OM-ĕt-ĕr)
    • instrument used to measure hearing
  7. audiometry (od-ē-OM-ĕ-trē)
    • measuring hearing
  8. aural (OR-ăl)
    • pertaining to the ear
  9. binocular (bĭn-ŎK-ū-lăr)
    • pertaining to both eyes
  10. blepharitis (blĕf-ăr-Ī-tĭs)
    • inflammation of the eyelid
  11. blepharoplasty (BLĔF-ă-rō-plăs-tē)
    • surgical repair of the eyelid
  12. blepharoptosis (BLĔF-ă-rōp-TŌ-sĭs)
    • condition of drooping of the eyelid
  13. cochlear (KOK-lē-ăr)
    • pertaining to the cochlea
  14. cochlear implant (KOK-lē-ă IM-plant)
    • pertaining to the cochlear implant
  15. conjunctivitis (kŏn-jŭnk-tĭ-VĪT-ĭs)
    • inflammation of the conjunctiva
  16. corneal (KOR-nē-ă)
    • pertaining to the cornea
  17. cryoretinopexy (krī-ō-RET-in-ō-pek-sē)
    • surgical fixation of the retina using extreme cold
  18. dacrocystitis (dak-rē-ŏ-sis-TĪT-ĭs)
    • inflammation of the tear (lacrimal) sac
  19. dacryocystorhinostomy (dak-rē-ŏ-sis-tŏ-rī-NOS-tŏ-mē)
    • creation of an artificial opening between the lacrimal sac and the nose
  20. diplopia (dip-LŌ-pē-ă)
    • condition of double vision
  21. electrocochleography (ē-lek-trō-kok-lē-OG-ră-fē)
    • process of recording the electrical activity in the cochlea
  22. endophthalmitis (ĕn-dŏf-thăl-MĪ-tĭs)
    • inflammation within the eye
  23. intraocular (in-tră-OK-yŭ-lăr)
    • pertaining to within the eye
  24. iridectomy (ir-ĭ-DEK-tŏ-mē)
    • excision of (part of) the iris
  25. iridoplegia (ir-ĭ-dō-PLĒ-j(ē-)ă, īr)
    • condition of paralysis of the iris
  26. iridotomy (ĭr-ĭ-DŎT-ō-mē)
    • incision into the iris
  27. iritis (ī-RĪT-ĭs)
    • inflammation of the iris
  28. isocoria (ī-sō-KŌ-rē-ă)
    • condition of equal pupils
  29. keratitis (ker-ă-TĪT-ĭs)
    • inflammation of the cornea
  30. keratomalacia (kĕr-ă-tō-mă-LĀ-shē-ă)
    • softening of the cornea
  31. keratometer (kĕr-ă-TŎM-ĕ-ter)
    • instrument used to measure (the curvature) of the eye
  32. keratoplasty (KER-ăt-ō-plas-tē)
    • surgical repair of the cornea
  33. labyrinthectomy (lab-ĭ-rin-THEK-tŏ-mē)
    • excision of the inner ear (labyrinth)
  34. labyrinthitis (lab-ĭ-rin-THĪT-ĭs)
    • inflammation of the inner ear (labyrinth)
  35. lacrimal (LAK-rĭ-măl)
    • pertaining to the tear duct
  36. leukocoria (loo-kō-KŎR-ē-ă)
    • condition of a white pupil
  37. mastoidectomy (măs-tŏy-d-ĔK-tō-mē)
    • excision of the mastoid bone
  38. mastoiditis (mas-toyd-ĪT-ĭs)
    • inflammation of the mastoid bone
  39. mastoidotomy (măs-toyd-ŎT-ō-mē)
    • incision into the mastoid bone
  40. myringitis (mĭr-ĭn-JĪ-tĭs)
    • inflammation of the tympanic membrane
  41. myringoplasty (mĭr-ĬN-gō-plăst-ē)
    • surgical repair of the tympanic membrane
  42. myringotomy (mĭr-ĭn-GŎT-ō-mē)
    • incision into the tympanic membrane
  43. nasolacrimal (nā-zō-LAK-rĭ-măl)
    • pertaining to the nose and the tear duct
  44. nasopharyngeal (nā-zō-FAR-in-gēl)
    • pertaining to the nose and pharynx (throat)
  45. oculomycosis (ŏk-ū-lō-mī-KŌ-sĭs)
    • abnormal condition of the eye caused by a fungus
  46. ophthalmalgia (ŏf-thăl-MĂL-jē-ă)
    • condition of pain in the eye
  47. ophthalmic (of-THAL-mik)
    • pertaining to the eye
  48. ophthalmologist (ŏf-thăl-MŎL-ō-jĭst)
    • specialist of the eye
  49. ophthalmology (Ophth) (ŏf-thăl-MŎL-ō-jē)
    • study of the eye
  50. ophthalmopathy (ŏf-thăl-MŎP-ă-thē)
    • disease of the eye
  51. ophthalmoplegia (of-thal-mō-PLĒ-j(ē-)ă)
    • condition of paralysis of the eye
  52. ophthalmoscope (of-THAL-mŏ-skōp)
    • instrument used to view the eye
  53. ophthalmoscopy (of-thal-MOS-kŏ-pē)
    • process of viewing the eye
  54. optic (OP-tik)
    • pertaining to vision
  55. optometry (op-TOM-ĕ-trē)
    • measuring vision
  56. otalgia (ō-TĂL-jē-ă)
    • condition of pain in the ear
  57. otologist ( ō-TŎL-ō-jĭst)
    • specialist who studies and treats disorders and diseases of the ear
  58. otology (ō-TŎL-ō-jē)
    • study of the ear
  59. otomastoiditis (ō-tō-mas-toyd-ĪT-ĭs)
    • inflammation of the ear and mastoid bone
  60. otomycosis (ō-tō-mī-KŌ-sĭs)
    • abnormal condition of fungus in the ear
  61. otopyorrhea (ō-tō-pī-ō-RĒ-ă)
    • discharge of pus from the ear
  62. otorhinolaryngologist (ō-tō-RĪ-nō-lăr-ĭn-GŎL-ō-jĭst)
    • specialist or physician who studies and treats disease and disorder of the ears,
  63. otorrhea (ō-tō-RĒ-ă)
    • discharge from the ear
  64. otosclerosis (ō-tō-sklē-RŌ-sĭs)
    • condition of hardening of the ear
  65. otoscope(Ō-tō-skōp)
    • instrument used to view the ear
  66. otoscopy (ō-TŎS-kō-pē)
    • process of viewing the ear
  67. phacomalacia (făk-ō-mă-LĀ-shē-ă)
    • condition of softening of the lens
  68. photophobia (fō-tō-FŌ-bē-ă)
    • condition of sensitivity to light
  69. pseudophakia (SOOD-ō-FĀ-kē-a)
    • condition of fake lens
  70. pupillary (PŪ-pĭ-lĕr-ē)
    • pertaining to pupil
  71. pupillometer (pū-pĭl-ŎM-ĕ-tĕr)
    • instrument used to measure the pupil
  72. pupilloscope (pū-pĭl-ŎS-kōp)
    • instrument used to view the pupil
  73. retinal (RĔT-ĭ-năl)
    • pertaining to the retina
  74. retinoblastoma (ret-ĭn-ō-blas-TŌ-mă)
    • tumour arising from a developing retinal cell
  75. retinopathy (ret-ĭn-OP-ă-thē)
    • disease of the retina
  76. retinoscopy (ret-ĭn-OS-kŏ-pē)
    • process of viewing the retina
  77. sclerokeratitis (sklĕr-ō-kĕr-ă-TĪ-tĭs)
    • inflammation of the sclera and cornea
  78. scleromalacia (sklĕ-rō-mā-LĀ-sē-ă)
    • condition of softening of the sclera
  79. sclerotomy (sklĕ-ROT-ŏ-mē)
    • incision into the sclera
  80. stapedectomy (stā-pĕ-DEK-tŏ-mē)
    • excision of the stapes
  81. tonometer (tō-NOM-ĕt-ĕr)
    • instrument used to measure pressure (within the eye)
  82. tonometry (tō-NOM-ĕ-trē)
    • process of measuring pressure
  83. tympanometer (tĭm-pă-NŎM-ĕ-tēr)
    • instrument used to measure the middle ear
  84. tympanometry (tĭm-pă-NŎM-ĕ-trē)
    • measurement of the tympanic membrane
  85. tympanoplasty (tĭm-păn-ō-PLĂS-tē)
    • membranesurgical repair of the tympanic
  86. vestibular (ves-TIB-yŭ-lăr)
    • pertaining to the vestibule
  87. vestibulocochlear (ves-tĭ-būl-ō-KŌ-klē-ar)
    • vestibul/o/cochle/ar
    • pertaining to the vestibule and cochlea
  88. xerophthalmia (zer-of-THAL-mē-ă)
    • xer/ophthalm/ia
    • condition of dry eye

Activity source: Sensory System Medical Terms by Kimberlee Carter, from Building a Medical Terminology Foundation by Kimberlee Carter and Marie Rutherford, licensed under CC BY- 4.0. /Text version added.

Anatomy Labeling Activity

Sensory System Eye Anatomy (Text Version)

Label the diagram with correct words listed below:

  1. Eyebrow
  2. Conjunctiva
  3. Levator palpebrae superioris muscle
  4. Palpebral conjunctiva
  5. Cornea
  6. Eyelashes
  7. Orbicularis oculi muscle


Check your answers [2]

Activity source: Sensory System Eye Anatomy by Gisele Tuzon, from Building a Medical Terminology Foundationillustration from Anatomy and Physiology (OpenStax)licensed under CC BY 4.0./ Text version added.

Sensory System Eye Anatomy

Sensory System Eye Anatomy (Text Version)

Label the diagram with correct words listed below:

  1. Fovea centralis
  2. Suspensory ligaments
  3. Ciliary muscle
  4. Retina
  5. Posterior chamber
  6. Iris
  7. Vitreous chamber
  8. Anterior chamber
  9. Choroid
  10. Ciliary process
  11. Optic disc (blind spot)
  12. Lens
  13. Central retinal artery and vein
  14. Suspensory ligaments
  15. Lateral rectus muscle
  16. Optic (II) nerve
  17. Sclera
  18. Medial rectus muscle
  19. Scleral venous sinus (canal of Schlemm)
  20. Cornea
  21. Pupil

Sensory System Eye Anatomy Diagram (Text Version)

This diagram shows a lateral and medial view of the eyeball. The major parts are labelled. Labels read from top, clockwise: showing the posterior cavity including the following structures: ______[Blank 1], ______[Blank 2] (canal of Schlemm), ______[Blank 3], _____[Blank 4], ______[Blank 5], _____[Blank 6], and ____[Blank 7]. Next is the anterior cavity (contains aqueous humor), ______[Blank 8], _____[Blank 9], and ______[Blank 10]. The Ciliary body ________[Blank 11] and ________[Blank 12], ______[Blank 13], _____[Blank 14] (blind spot of the eye), ______[Blank 15], _____[Blank 16], _______[Blank 17], ______[Blank 18], ________[Blank 19], and ________[Blank 20].

 

Check your answers [3]

Activity source: Sensory System Eye Anatomy by Gisele Tuzon, from Building a Medical Terminology Foundationillustration from Anatomy and Physiology (OpenStax)licensed under CC BY 4.0./ Text version added.

Sensory System Terms Not Easily Broken into Word Parts

Sensory System not easily broken into word parts (Text Version)
  1. astigmatism (Ast)
    • blurry vision due to irregular curvature of the cornea or lens
  2. Optician
    • specialist who fills prescriptions for lenses but cannot prescribe
  3. anosmia
    • condition of being without smell/inability to smell
  4. stye
    • infection of an oil gland of the eyelid (hordeolum)
  5. amblyopia
    • reduced vision in one eye
    • associated with strabismus (lazy eye)
  6. Optometrist
    • specialist who diagnoses, treats, and manages diseases and disorders of the eye
    • Doctor of Optometry
  7. visual acuity (VA)
    • sharpness or clearness of vision
  8. cataract
    • abnormal progressive disease of lens characterized by lack of transparency or cloudiness

Activity source: Sensory System Terms Not Easily Broken into Word Parts by Kimberlee Carter, from Building a Medical Terminology Foundation by Kimberlee Carter and Marie Rutherford, licensed under CC BY- 4.0. /Text version added.

Common Abbreviations for the Sensory System

Sensory System Abbreviations
  • ARMD (age-related macular degeneration)
  • Ast (astigmatism)
  • Em (emmetropia)
  • IOL (intraocular lens)
  • IOP (intraocular pressure)
  • LASIK (laser-assisted in situ keratomileusis)
  • Ophth (ophthalmology)
  • PHACO (phacoemulsification)
  • PRK (photorefractive keratectomy)
  • VA (visual acuity)
  • AOM (acute otitis media)
  • ENT (ears, nose, throat)
  • EENT (eyes, ears, nose, and throat)
  • HOH (hard of hearing)
  • OM (otitis media)

Activity source: Sensory System Abbreviation by Kimberlee Carter, from Building a Medical Terminology Foundation by Kimberlee Carter and Marie Rutherford, licensed under CC BY- 4.0. / Text version.

Image Descriptions

Figure 15.1 image description: This image shows the structure of the ear with the major parts labeled. The ear is divided into 3 parts from left to right: external ear, middle ear, and inner ear. Labels for each part read: external ear (auricle, ear canal), middle ear (tympanic membrane, malleus, incus, tympanic cavity), inner ear (stapes, vestibule, vestibular nerve, cochlear nerve, cochlea, round window, eustachian tube). [Return to Figure 15.1].

Figure 15.2 image description: This diagram shows the structure of the cochlea in the inner ear. Labels read (from top, counterclockwise): bony cochlear wall, scala vestibuli, cochlear duct, tectorial membrane, basilar membrane, scala tympani, spiral ganglion, cochlear branch of N VIII, organ of Corti. [Return to Figure 15.2].

Figure 15.3 image description: The left panel of this image shows a person’s head in a still position. Underneath this, the ampullary nerve is shown. Labels read: cupula, ampulla, ampullary nerve). The right panel shows a person rotating his head, and the below that, the direction of movement of the cupula is shown. Label reads: as the head rotates, cupula bends in opposite direction of the rotation. [Return to Figure 15.3].

Figure 15.4 image description: This diagram shows the lateral view of the eye. The major parts are labeled. Labels read (from top): eyebrow, orbicularis oculi muscle, levator palpebrae superioris muscle, palpebral conjunctiva, eyelashes, cornea, conjunctiva. [Return to Figure 15.4].

Figure 15.5 image description: This diagram shows a lateral and medial view of the eyeball. The major parts are labelled. Labels read (from top, clockwise): posterior cavity (vitreous chamber, scleral venous sinus (canal of Schlemm), suspensory ligaments, lens, cornea, iris, pupil); anterior cavity (contains aqueous humor, posterior chamber, anterior chamber, suspensory ligaments); Ciliary body (ciliary process and muscle), medial rectus muscle, optic disc (blind spot), central retinal artery and vein, foveal centralis, retina, choroid, sclera, lateral rectus muscle. [Return to Figure 15.5].

Figure 15.6 image description: This graph shows the normalized absorbance versus wavelength for different cell types in the eye. The Y-axis is normalized absorbance, and the X axis is wavelength (nm) with the colours violet, blue, cyan, green, yellow, and red across the bottom. The lines in the graph indicate blue cones which peak at 420 nm; rods which peak at 498 nm; green cones, which peak at 534 nm, and red cones which peak at 564 nm. Blue cones line is labelled as short, green cones as medium, and red cones as long. [Return to Figure 15.6].

Attribution

Except where otherwise noted, this chapter is adapted from “Sensory Systems” in Building a Medical Terminology Foundation by Kimberlee Carter and Marie Rutherford, licensed under CC BY 4.0. / A derivative of Betts et al., which can be accessed for free from Anatomy and Physiology (OpenStax). Adaptations: dividing Sensory Systems chapter content into sub-chapters.

  1. Illustration showing the anterior view of the human digestive system. A line extends from structures identifying location. Textboxes containing anatomical structure names are shown at the end of each line identifying the structure name
    Check your answers: Sensory System Ear Anatomy labeling activity (Text Version)text
  3. Check your answers: Sensory System Eye Anatomy Diagram (Text Version)This diagram shows a lateral and medial view of the eyeball. The major parts are labelled. Labels read from top, clockwise: showing the posterior cavity including the following structures: vitreous chamber, scleral venous sinus (canal of Schlemm), suspensory ligaments, lens, cornea, iris, and pupil. Next is the anterior cavity (contains aqueous humor), posterior chamber, anterior chamber, and suspensory ligaments. The Ciliary body ciliary process and ciliary muscle, medial rectus muscle, optic disc (blind spot of the eye), central retinal artery and vein, foveal centralis, optic nerve, retina, choroid, sclera, and lateral rectus muscle.
definition

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Building a Medical Terminology Foundation 2e Copyright © 2024 by Kimberlee Carter; Marie Rutherford; and Connie Stevens is licensed under a Creative Commons Attribution 4.0 International License, except where otherwise noted.

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