b-stickerkerr"N9785970458112-0001-000785970458112-0001-0005970458112-0001-000e outer environment is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).outer environment is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).ter environment is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).r environment is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).environment is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).vironment is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).ronment is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).nment is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception). is per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).s per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception).per-cieved by complicated systems named analyzers. The analyzer as a sensory system consists of the peripheral part (sensory receptors), intermediate part (neural pathways), and central part (the brain involved in sensory perception). general senses. The special senses are olfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.eneral senses. The special senses are olfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.eral senses. The special senses are olfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.enses. The special senses are olfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ses. The special senses are olfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.s. The special senses are olfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.re olfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves. olfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.lfaction, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.action, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.tion, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.on, vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves., vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.vision, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.sion, taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves., taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.taste, hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves. hearing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.earing and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ring and vestibu-lar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ar function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves. function. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.unction. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ction. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ion. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves. Afferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.fferent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.erent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ent information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.information is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.formation is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.rmation is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ion is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.n is encoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ncoded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.oded by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ed by highly specialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ecialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ialized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.lized sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ed sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves. sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.b>sense organs (organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.organa sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.gana sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.na sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves. sensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ensoria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.soria) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.) and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.i>and transmitted to the brain in cranial nerves I, II, VII, VIII, IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.IX and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves. and X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.nd X. The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.The general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.e general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.general senses include touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.clude touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ude touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.e touch, pressure, vibration, pain, thermal sensation and proprioception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ception (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ption (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ion (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.n (perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.(perception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.erception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ception of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.ption of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves. of posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.f posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.posture and movement). Stimuli from the external and internal environment activate a diverse range of receptors in the skin, viscera, muscles, tendons and joints. Afferent impulses from the trunk and limbs are conveyed to the spinal cord in spinal nerves whilst those from the head are carried to the brain in cranial nerves.lassors of sense organs are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.s of sense organs are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.of sense organs are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. sense organs are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ense organs are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.se organs are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. organs are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.rgans are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ans are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.are subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.e subdivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ivided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ided into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ed into neurosensitive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.tive receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ve receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. receptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.eceptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.eptors and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.rs and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. and senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.nd senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. senso-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.so-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.-epithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.pithelial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.elial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ial receptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ceptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ptors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ors. Neurosensory cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ry cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. cells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ells are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.s are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.are neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.e neurons which accept sensitive signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ve signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. signals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ignals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.nals by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ls by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. by the dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.he dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. dendrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.endrites, provide them to nervous impulses and transfer in CNS by the axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.he axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. axons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.xons. They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.They are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ey are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. are a part of the photoreceptor system and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.tem and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.m and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.and olfactory organ. Sensory epithelial cells are specialized cells which recognize sensitive signals; transmission of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ssion of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ion of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.n of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.of nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. nervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.ervous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.vous impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.us impulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.pulses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.lses from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ.es from them in the CNS is carried out due to their connections with dendrites of neurons. They are a part of the vestibu-locochlear apparatus and taste organ. the eyeball (bulbus oculi) and accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.he eyeball (bulbus oculi) and accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. eyeball (bulbus oculi) and accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.eball (bulbus oculi) and accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.all (bulbus oculi) and accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.l (bulbus oculi) and accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.i>accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.accessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.cessory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ssory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ory visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.y visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.visual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.sual structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. structures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.tructures (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.res (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.s (structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.(structurae oculi ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ac-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.-cessoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.essoriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.soriae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ae). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.). Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.>Accessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ccessory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.essory visual structures include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. include the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.nclude the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.lude the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.de the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. the eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.he eyelids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.elids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ids, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.s, eyebrow, conjunctiva, extra-ocular muscles, lacrimal apparatus, and structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.structures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ructures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ctures of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. of the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.f the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.the orbit (periorbita, fascial sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.al sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. sheath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.heath of the eyeball, ret-robulbar fat, orbital septum and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.and fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.d fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.fasciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.sciae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.iae). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.e). The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.. The eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.e eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.eye is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.e is a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. a sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. sensory organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.ry organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images. organ whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.rgan whose lens focuses rays of light originating in the external environment onto photosensitive cells of the retina. The intensity, location, and wavelengths of the transmitted light are partially processed by the retina, and the assembled information is sent via the optic nerve for further processing and interpretation by the visual cortex of the brain as three-dimensional color images.rays of light originating in the external environment onto photosensitive cells of the retina. 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