* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Senses presentation
Development of the nervous system wikipedia , lookup
Neuroregeneration wikipedia , lookup
Neuromuscular junction wikipedia , lookup
Psychophysics wikipedia , lookup
Axon guidance wikipedia , lookup
Synaptogenesis wikipedia , lookup
Sensory cue wikipedia , lookup
Embodied cognitive science wikipedia , lookup
Endocannabinoid system wikipedia , lookup
Microneurography wikipedia , lookup
Time perception wikipedia , lookup
Signal transduction wikipedia , lookup
Optogenetics wikipedia , lookup
Olfactory bulb wikipedia , lookup
Neural correlates of consciousness wikipedia , lookup
Sensory substitution wikipedia , lookup
Evoked potential wikipedia , lookup
Molecular neuroscience wikipedia , lookup
Proprioception wikipedia , lookup
Clinical neurochemistry wikipedia , lookup
Feature detection (nervous system) wikipedia , lookup
Channelrhodopsin wikipedia , lookup
Sensation • Senses: Means by which brain receives information about environment and body – General: Distributed over large part of body • Somatic: Touch, pressure, temperature, proprioception, pain • Visceral: Internal organs and consist mostly of pain and pressure – Special senses: Smell, taste, sight, hearing, balance • Sensation or perception: Conscious awareness of stimuli received by sensory receptors Sensation • Sensation or perception is the conscious awareness of stimuli received by receptor. • Receptors transduce (change) different forms of energy into nerve impulses • Nerve impulses are conducted to the brain – Stimulus must initiate and action potential in the cerebral cortex – The brain interprets these impulses as sound or sight even though the impulses themselves are identical in nature. • The cerebral cortex screens the information and ignores most of what it receives – subconscious • Our senses act as energy filters that perceive a narrow range of energy. Sensation Requires: • A stimulus • Activation of a receptor, • Conduction of an action potential to a specific region of the CNS • Translation or interpretation of the signal. • Sensation or awareness of a stimuli occurs in the cerebral cortex. General Properties of Receptors • A receptor is any structure specialized to detect a stimulus. • All receptors are transducers, changing stimulus energy into nerve energy. • Sensory receptors transmit four kinds of information: – Modality refers to the type of stimulus or sensation it produces (vision, hearing, taste, etc.). – Location is also indicated by which nerve fibers are firing. • Sensory projection is the ability of the brain to identify the site of stimulation. – Intensity of stimulous – Duration is encoded in the way nerve fibers change their firing frequencies over time. • Tonic vs Phasic receptor adaptation. Classification of Receptors Types of Sensory Receptors • Classification by Stimulus Modality – Mechanoreceptors: Compression, bending, stretching of cells – Chemoreceptors: Smell and taste – Thermoreceptors: Temperature – Photoreceptors: Light as vision – Nociceptors: Pain • Classification by Origin of Stimuli – Exteroreceptors: Associated with skin – Visceroreceptors: Associated with organs – Proprioceptors: Associated with joints, tendons Sensory Nerve Endings • Unencapsulated Nerve Endings – Free nerve endings: Cold receptors and warm – Merkel’s disk: Light touch, superficial pressure – Hair follicle receptor: Light touch, bending of hair Sensory Nerve Endings in Skin Encapsulated Nerve Endings •Pacinian corpuscle: Deep cutaneous pressure, vibration and proprioception •Meissner’s corpuscle: Twopoint discrimination •Ruffini’s end organ: Continuous touch or pressure •Muscle spindle: Proprioception as to muscle stretch and control of muscle tone •Golgi tendon organ: Important in muscle contraction and tendon stretch proprioception Two-Point Discrimination Muscle Spindle and Golgi Tendon Organ Responses of Sensory Receptors • Receptor: Interaction of stimulus with sensory receptor produces a local potential – Primary: Have axons that conduct action potential in response to receptor potential – Secondary: Have no axons and receptor potentials produced do not result in action potentials but cause release of neurotransmitters • Accommodation or adaptation: Decreased sensitivity to a continued stimulus • Proprioceptors – Tonic: Example is know where little finger is without looking – Phasic: Example is you know where hand is as it moves Sensory Nerve Tracts • Transmit action potentials from periphery to brain • Each pathway involved with specific modalities • First half of word indicates origin, second half indicates termination Spinothalamic System • Conveys cutaneous sensory information to brain • Unable to localize source of stimulus • Divisions – Lateral for pain and temperature – Anterior for light touch, pressure, tickle, itch Dorsal-Column/ Medial-Lemniscal System • Carries sensations of – Two-point discrimination – Proprioception – Pressure – Vibration • Tracts – Fasciculus gracilis – Fasciculus cuneatus Spinocerebellar System • Carry proprioceptive information to cerebellum • Actual movements can be monitored and compared to cerebral information representing intended movement • Tracts – Posterior – Anterior Sensory Areas of Cerebral Cortex Somatic Sensory Cortex Pain • Types – Referred: Sensation in one region of body that is not source of stimulus – Phantom: Occurs in people who have appendage amputated or structure removed as tooth – Chronic: Not a response to immediate direct tissue injury Special Senses • • • • Olfaction Taste Visual system Hearing and balance Olfaction • Sense of smell – Olfactory epithelium • 10-20 million neurons • Bipolar neurons project through cribiform plate. – Olfactory hairs • 10 – 20 Cilia per neuron. • Embedded in a mucous layer • Only neurons exposed to external environment • Replaced every 60 days. Olfactory Physiology • Process of Olfaction 1. Airborne chemicals are dissolved in the fluid covering the olfactory epithelium. • 2. 3. 4. 5. 6. Chemicals must be volatile and water soluble. Odor molecule binds with a specific receptor G-protein coupled membrane receptor) a second messenger is produced, Sodium channels are opened in the membrane. The cell is depolarized creating an axon potential. Olfactory Discrimination We can discriminate between ~10,000 different odors. There are between 7-50 primary classes of odors A characteristic fingerprint of the odor is used to identify the odor. Olfactory receptors adapt quickly Some odors can stimulate nociceptors in the trigeminal nerve. Olfactory Neuronal Pathways and the Cortex 1. 2. 3. 4. 5. Olfactory neurons project to the olfactory bulb. Mitral cells project to the olfactory cortex. Lateral olfactory area: conscious perception of smell Medial olfactory area: visceral and emotional reactions Intermediate olfactory area merges information from medial and lateral areas and projects back to olfactory bulb to modulate neuronal activity there. Clinical Considerations of Olfaction • Anosmia – inability to smell (1.2% of the population) • Ability to smell decreases with age. • 98-99% of people can smell banana, rose and cloves. • 35% of the population cannot smell androstenone (body odor). Papillae and Taste Buds •Taste results from the action of chemicals on the taste buds found on papillae. • ~10,000 taste buds •Papillae Types •Circumvallate •Fungiform •Foliate •Filiform •Taste Bud Structure •Supporting cells - Form an exterior supporting capsule •Gustatory or taste cells contain gustatory villi or hairs with surface receptors and are replaced every 7 to 10 days. Physiology of Taste •Process of Taste •Molecules are dissolved in saliva. •Substance enters taste pore and attaches to chemoreceptor molecule •Depolarization of the taste cell. •Taste cells have no axons but release neurotransmitter •Neurotransmitter stimulates action potential in cells associated with the gustatory cells. Four Primary Taste Sensations Exist: 1. 2. 3. 4. 5. Salty • lateral anterior of tongue • The presence of Na+ is detected Sweet • tip of the tongue • most organic molecules (particularly sugars) are sweet. Sour • posterior lateral portion of the tongue • H+ are detected • all acids taste sour. Bitter • most posterior central portion of the tongue • most sensitive • protective function - most poisons are bitter Umami (Glutamate) may also be considered. Actions of Major Tastants Neuronal Pathways for Taste Visual System Anatomy of the Eye • • Fibrous tunic: Outer – Sclera: White outer layer, maintains shape, protects internal structures, provides muscle attachment point, continuous with cornea – Cornea: Avascular, transparent, allows light to enter eye and bends and refracts light Vascular tunic: Middle – Iris: Controls light entering pupil; smooth muscle – Ciliary muscles: Control lens shape; smooth muscle • • • Retina: Inner – Contains neurons sensitive to light – Macula lutea or fovea centralis: Area of greatest visual acuity – Optic disc: Blind spot Compartments – Anterior: Aqueous humor – Posterior: Vitreous humor Lens – Held by suspensory ligaments attached to ciliary muscles – Transparent, biconvex Compartments of the Eye •Posterior Compartment •Vitreous Humor •Anterior Compartment •Anterior Chamber •Posterior Chamber • Aqueous Humor •Produced by ciliary processes Functions of the Complete Eye • • • • Eye functions like a camera Iris allows light into eye Lens, cornea, humors focus light onto retina Light striking retina is converted into action potentials relayed to brain Light • Visible light: Portion of electromagnetic spectrum detected by human eye – The visible spectrum ranges form ~400 to 700 nm • Refraction: Bending of light – Divergence: Light striking a concave surface – Convergence: Light striking a convex surface – The cornea, aqueous humor, lens and vitreous humor all refract light. •Focal point: Point where light rays converge and cross •The more spherical the lens the more the light is bent. •Reflection: light rays bounce off a non transparent object Focus and Accommodation • • Focusing system of the eye creates a clear image on the retina. Emmetropia: Normal resting • • condition of lens Far vision: 20 feet + from eye. Near vision: Closer than 20 feet – Accommodation • Occurs via changes in the shape of the lens. – Pupil constriction • Depth of focus • – Convergence The inverted image on the retina is detected by photoreceptors and passed via action potentials to the visual cortex. The Retina • • Pigmented retina – Single layer of pigmented cells (RPE) Sensory retina – Three layers • Photoreceptor • Bipolar cell • Ganglion cell – Three layers separated by plexiform layers • Sensitivity vs. visual acuity. • Photoreceptors – Rods: Noncolor vision – Cones: Color vision Sensory Receptor Cells • Photoreceptors – Bipolar cells that detect light. – Types: • Rods – noncolor, low illumination. • Cones – color vision, bright light. – Outer segment is made of ~700 folded membranes (discs) that contain photopigments. – Rhodopsin • Opsin • Retinal (Vitamin A derivative) • Coupled to a G protein Rhodopsin Cycle Note: Light and Dark adaptation occur through the production or breakdown of rhodopsin. 1. Retinal in inactive cis configuration is attached inside opsion. 2. Light causes opsin to change shape causing activation of the G-protein. Na+ channels open and the cell hyperpolarizes. 3. Trans-retinal detaches from opsin. 4. Trans-retinal is converted to cis-retinal via ATP. 5. Cis-retinal reattaches to opsin in the dark configuration and the cell depolarizes. Rod Cell Hyperpolarization Visual Pathways Eye Disorders • • • • • Myopia: Nearsightedness – Focal point too near lens, image focused in front of retina Hyperopia: Farsightedness – Image focused behind retina Presbyopia – Degeneration of accommodation, corrected by reading glasses Astigmatism: Cornea or lens not uniformly curved Strabismus: Lack of parallelism of light paths through eyes • • • • • Retinal detachment – Can result in complete blindness Glaucoma – Increased intraocular pressure by aqueous humor buildup Cataract – Clouding of lens Macular degeneration – Common in older people, loss in acute vision Diabetes – Dysfunction of peripheral circulation Inner Ear • Labyrinth – Bony • Cochlea: Hearing • Vestibule: Balance • Semicircular canals: Balance • – Membranous -Lymphs – Endolymph • In membranous labyrinth – Perilymph • Space between membranous and bony labyrinth Structure of Cochlea Hair Cell with 50-60 linked cilia Auditory Function • Vibrations produce sound waves – Volume or loudness : Function of wave amplitude – Pitch: Function of wave frequency – Timbre: Resonance quality or overtones of sound Effect of Sound Waves on Cochlear Structures CNS Pathways for Hearing Balance • Static – Evaluates position of head relative to gravity – Detects linear acceleration and deceleration – Utricle and saccule • Maculae: Consist of hairs embedded in gelatinous mass containing otoliths • Kinetic – Evaluates movements of head – 3 semicircular canals • Ampulla – Crista ampullaris – Cupula: endolymph moves when head moves Structure of the Macula Vestibule in Maintaining Balance Semicircular Canals CNS Pathways for Balance Ear Disorders • Tinnitus – Ringing, clicking, whistling in ear due to disorders in middle or inner ear • Motion sickness – Dysfunctions caused by stimulation of semicircular canals during motion • Otitis Media – Infections in the middle ear • Earache – Results from otitis media, dental abscesses, TMJ pain Effects of Aging on the Special Senses • • • • Slight loss in ability to detect odors Decreased sense of taste Lenses of eyes lose flexibility Development of cataracts, macular degeneration, glaucoma, diabetic retinopathy • Decline in visual acuity and color perception