1 / 22

Topic A.3 Perception of Stimuli

Explore the specialized receptors in the human body that allow us to perceive sensory stimuli. Learn about different types of receptors and their functions, including smell, vision, and hearing. Understand how these receptors work together to interpret the environment.

lowet
Download Presentation

Topic A.3 Perception of Stimuli

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Topic A.3Perception of Stimuli

  2. Sensory Receptors • Receptors in the nervous system the are sensitive to changes in the environment around the cells. • Humans have the 4 following types of specialized receptors • Mechanoreceptors • Respond to mechanical forces and movements • Chemoreceptors • Respond to chemical substances • Thermoreceptors • Respond to temperature changes • Photoreceptors • Respond to light

  3. Smell • Detection of chemicals in the air is carried out by the Olfactory receptors. • These cells have cilia that project into the nasal cavity and their membrane contains odorant receptor molecules which assist in the sense of smell • Different organisms have differing amounts of odorant receptors • Mice have over a thousand different receptors which allows them to have a very keen sense of smell • Humans are severely lacking in odorant receptors which provides an imprecise sense of smell

  4. Eye Functions • 1. sclera = opaque (usually white), fibrous, protective layer of the eye containing collagen and elastic fibers • 2. cornea = transparent front part of the eye that covers the iris, pupil, and anterior chamber,providingmost of an eye's optical power • 3. conjunctiva = membrane that covers the sclera (white part of the eye) and lines the inside of the eyelids • 4. eyelid - outside flesh covering of the eye. Protects from damage • 5. choroid = vascular layer of the eye lying between the retina and the sclera. The choroid provides oxygen and nourishment to the outer layers of the retina

  5. 6. aqueous humor = thick, watery substance in the eye • 7. pupil = variable-sized, black circular opening in the center of the iris that regulates the amount of light that enters the eye • 8. lens = transparent, biconvex structure in the eye that, along with the cornea, helps to refract light to focus on the retina • 9. iris = colored part of the eye • 10. vitreous humour = the clear aqueous solution that fills the space between the lens and the retina • 11. fovea = responsible for sharp central vision • 12. optic nerve = transmits visual information from the retina to the brain • 13. blind spot = the specific region of the retina where the optic nerve and blood vessels pass through to connect to the back of the eye • 14. retina = thin layer of neural cells that lines the back of the eyeball

  6. Photoreceptors • Light enters the eye through the cornea and the lens which focuses it onto the retina. • The retina is a thin layer of light-sensitive tissue at the back of the eye. • The retina involves two types of photoreceptors • Rods and Cones • Many nocturnal animals only have rods and cannot distinguish color

  7. Rods and Cones • Rods are very sensitive to light. But not color • When exposed to bright light “bleaching” of rods can occur • Cones are able to absorb different ranges of wavelengths of light

  8. Cones Continued • There are three types of cones in the human eye. • Red, Green, Blue • The relative stimulation of each of the three cone types allows for interpretation of color • Color vision is only in bright light and tends to fade in dim light

  9. Bipolar cells • Rods and cones synapse with neurons called bipolar cells • Bipolar cells send the electrical impulses from the rods and cones to the Ganglion cells

  10. Neurons and action potentials • If a rod or cone cell is not stimulated by light they will depolarize and release an INHIBITORY Neurotransmitter onto a bipolar cell. • This causes that bipolar cell to become hyperpolarized and not transmit impulses to its associated retinal ganglion cell. • When light is absorbed by a rod or cone cell it becomes hyperpolarized and stops sending that inhibitory neurotransmitter to the bipolar cell • This then allows the bipolar cell to depolarize, activating the adjacent ganglion cell. • Groups of rods send signals to the brain via a single bipolar cell • Grainy Picture • Cones send signals to the brain via their own individual bipolar cell • High Definition vision!!

  11. Ganglion Cells • Ganglion cells have cell bodies in the retina and synapse with bipolar cells • Ganglion cells pass across the front of the retina to form the “blind spot” • The “Blind spot” is actually where the ganglion cells combine to form the Optic Nerve

  12. Contralateral processing

  13. The Human Ear Transmit pressure waves into auditory sounds Brain interprets the information from the receptors

  14. Parts & Functions of the Ear

  15. Outer Ear Pinna

  16. Middle Ear Eardrum 3 smallest bones in the body (malleus, Incus and Stapes)

  17. Inner Ear Does both auditory and balance Cochlea and Vestibula or semicircular canals

  18. Transmission of Sound Pinna collects sound waves and passes them to the eardrum The eardrum vibrates Vibration of the eardrum puts pressure on the ear bones Ear bones absorb the vibrations and amplify them Vibrations reach the stirrup and act like a piston to convert it to mechanical energy Mechanical energy is passed on to the cochlea via the oval and round windows As it moves through the cochlea it causes the hair cells to bend

  19. Transmission continued • Hair cells are varying heights and are in a jelly-like substance • Larger sound waves vibrate more hair cells • The more hair cells activated (bent) the louder the sound • The more frequent the sound waves the higher the pitch (frequency)

More Related