Problem 2
Question
Vibrations of the _____, located within the _____, bend stereocilia in the hair cells of the mammalian ear and activate sensory neurons. a. tympanic membrane, cochlear duct b. round window, middle ear c. basilar membrane, organ of Corti d. ossicle, outer ear e. ampulla, semicircular canals
Step-by-Step Solution
Verified Answer
The correct answer is (c) basilar membrane, organ of Corti.
1Step 1: Identify the Vibrational Element
The element that vibrates in response to sound waves within the ear is the basilar membrane, which acts as a type of mechanical analyzer and speaker, separating out the frequencies of incoming sound waves.
2Step 2: Identify the Location
These vibrations of the basilar membrane occur within the organ of Corti, the sensory organ of hearing which is located on the basilar membrane in the cochlea of the inner ear.
3Step 3: Confirmation
Referencing this information, the correct answers to fill in the blanks of the given question are 'basilar membrane' and 'organ of Corti' respectively, making option (c) the correct choice.
Key Concepts
Organ of CortiCochleaSensory Neurons
Organ of Corti
The organ of Corti is the epicenter of our hearing capabilities. Situated on the basilar membrane inside the cochlea, it harbors an array of hair cells, which are the true heroes in converting sound vibrations into electrical signals. This assembly looks akin to a tiny piano, with each 'key' tuned to a specific frequency. Sound waves travel through the ear canal, vibrate the eardrum, and get transferred into the cochlea. It is here that the organ of Corti comes into play.
When the basilar membrane vibrates, so does the organ of Corti, leading to the bending of hair cell stereocilia – little hair-like projections. This bending is crucial; it causes a chemical change that generates electrical signals, which neurons pick up. This orchestration exemplifies how mechanical energy (sound waves) is transformed into the language of our nervous system – electrical impulses.
When the basilar membrane vibrates, so does the organ of Corti, leading to the bending of hair cell stereocilia – little hair-like projections. This bending is crucial; it causes a chemical change that generates electrical signals, which neurons pick up. This orchestration exemplifies how mechanical energy (sound waves) is transformed into the language of our nervous system – electrical impulses.
Cochlea
Imagine a snail's shell, with its coiled structure; that's pretty much what the cochlea in your inner ear looks like. But don't let its small size fool you; it's a powerhouse of auditory transduction. The cochlea is filled with fluid and lined with the basilar membrane. Sound vibrations cause this fluid to ripple, much like stones thrown in a pond. These ripples move the basilar membrane, thus stimulating the organ of Corti resting on top of it.
Due to the coiled shape of the cochlea, it can accommodate a wide range of sound frequencies along its length, with high frequencies detected at the base and low frequencies at the apex. It's a remarkable example of nature's design efficiency – packing a sophisticated frequency analyzer into such a compact space. Understanding this structure helps us appreciate how delicate and finely tuned our hearing is.
Due to the coiled shape of the cochlea, it can accommodate a wide range of sound frequencies along its length, with high frequencies detected at the base and low frequencies at the apex. It's a remarkable example of nature's design efficiency – packing a sophisticated frequency analyzer into such a compact space. Understanding this structure helps us appreciate how delicate and finely tuned our hearing is.
Sensory Neurons
Sensory neurons are the messengers of the body, announcing to the brain that something is happening in the environment. In the context of hearing, these neurons are like the audience receiving a performance by the organ of Corti. Once the hair cells inside the organ of Corti send out their electrical impulses, these neurons pick up the signal.
They carry this information to the brain along the auditory nerve, allowing us to perceive and interpret sounds. The speed and precision with which these neurons operate allow us to instantly recognize sounds and even determine their direction. When studying sensory neurons, it's important to grasp that they are the final translators of the sensory input, enabling us to experience the rich soundscape of our world.
They carry this information to the brain along the auditory nerve, allowing us to perceive and interpret sounds. The speed and precision with which these neurons operate allow us to instantly recognize sounds and even determine their direction. When studying sensory neurons, it's important to grasp that they are the final translators of the sensory input, enabling us to experience the rich soundscape of our world.
Other exercises in this chapter
Problem 1
The process in which incoming sensory stimulation is converted to electrical signals in neurons is called a. an action potential. b. sensory reception. c. perce
View solution Problem 3
. _____ sense pain; _____ sense heat or cold; and _____ sense touch a. Mechanoreceptors; thermoreceptors; nociceptors b. Nociceptors; thermoreceptors; mechanore
View solution Problem 4
Statocysts are sensory organs for a. hearing found in many invertebrates. b. equilibrium found in mammals. c. equilibrium found in many invertebrates. d. water
View solution Problem 5
In which process(es) are hair cells involved? a. balance in vertebrates and invertebrates b. hearing in mammals c. vision in animals with compound eyes d. heat
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