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April 22, 2014 – Hearing and equilibrium II 1. 2. 3. 4. 5. Review of the mechanics of hearing. Maintaining equilibrium in mammals. Equilibrium in other animals Sensory deprivation and hallucinations. Cell-to-cell signalling – Hormones!!! Detects sound frequency transmits signal to the auditory nerve Vestibular canal Cochlear duct Tectorial membrane Hair cells Axons of sensory neurons Tympanic canal Hearing- Mammals (con’t) • Two Components of Sound Wave: There are two main components of the sound wave that are detected and used by the auditory system: 1. Volume- Amplitude wave) (height of 2. Pitch- Frequency (no. of waves per unit time) Hearing- Mammals (con’t) 1. Amplitude larger amplitude= louder sound -larger amplitude results in stronger pressure on the hair cells, thereby causing more action potentials (more neurotransmitters released) 2. Pitch - basilar membrane varies in thickness and flexibility -base= narrow and stiff; stimulated by higher pitch -tip (apex)= wider and more flexible; stimulated by lower pitch Equilibrium balance and body position/orientation Equilibrium- Mammals Organs to detect body position and maintain balance located in inner ear 1.) Utricle and Saccule (2 parts of same organ) -located next to oval window -detect which direction is up and detect body position and acceleration 2.) Semicircular Canals (3 canals in total) -next to utricle -detect angular movements Semicircular Canals 1. Utricle and saccule contain clusters of hair cells embedded in a gel called a cupula. 2. Cupula contains otoliths. 3. Cupula (with otoliths) is heavier than the endolymph (fluid) in the utricle and saccule, so gravity is pulling the cupula down on to the hairs of the hair cells. 4. Changes in angle of body (i.e. changes in position of head) change the force on the hair cells. - causes stimulation of some cells that weren’t stimulated before - causes some to increase/decrease their signals Equilibrium- Mammals Semicircular Canals 3 canals (“loops”) - one for each plane: - side-to-side - front and back - up and down Same mechanism of stimulation as for utricle and saccule (cupula with otoliths, hair cells, etc.) Semicircular Canals Equilibrium- Aquatic Organisms Lateral Line System 1. Fish: lateral line on both sides of body series of mechanoreceptors called neuromasts on body just under the epidermis Small openings (pores) in epidermis allow for water to enter into lateral line canals Equilibrium- Lateral Line (con’t) Lateral Line System Water stimulates clusters of hair cells in the neuromasts by bending the cupula (gelatinous cap over the hair cells) Stimulation causes release of neurotransmitters, sending signals through sensory nerves to brain Equilibrium- Invertebrates Most invertebrates have sensory “organ” called statocysts Parts of statocyst: -layer of ciliated receptor cells surrounding an open chamber -inside chamber are grains of dense material called statoliths 2. Pathway: a. Gravity causes statoliths to settle downward b. Once reach bottom of chamber, stimulating cilia of receptor cells c. Stimulated cells release neurotransmitters, stimulating connecting sensory nerve fibers Sensory deprivation and hallucination • Degradation of vision and hearing is associated with visual and auditory hallucinations. • Thought to be associated with hyperactivity or visual and auditory brain regions that received degraded input from sensory organs. • Distinctly different in character from drug-induced and psychotic hallucinations • Charles Bonnett syndrome. • Link to Oliver Sacks’ TED talk. Introduction to chemical signals in animals – Major categories Endocrine cells may be organized into glands Autocrine signals Paracrine signals Endocrine signals act on the same cell that secretes them. diffuse locally and act on neighboring cells. are hormones carried between cells by blood or other body fluids. Introduction to chemical signals in animals – Major categories Neurotransmitters Neural signals diffuse a short distance between neurons. Neuroendocrine signals Pheromones are released from neurons but are carried by blood or other body fluids and act on distant cells. are released into the environment and act on a different individual. Endocrine systems are regulated by negative feedback Endocrine pathway Neuroendocrine pathway Stimulus Neuroendocrine-to-endocrine pathway Stimulus Stimulus Endocrine cell Endocrine signal Effector cell Response Sensor cell Sensor cell Neural signal Neural signal CNS CNS Neuroendocrine signal Effector cell Response Neuroendocrine signal Endocrine cell Endocrine signal Effector cell Response Figure 47-3-1 Hypothalamus Growth-hormone-releasing hormone: stimulates release of GH from pituitary gland Corticotropin-releasing hormone (CRH): stimulates release of ACTH from pituitary gland Thyroid-releasing hormone: stimulates release of TSH from thyroid gland Gonadotropin-releasing hormone: stimulates release of FSH and LH from pituitary gland Antidiuretic hormone (ADH): promotes reabsorption of H2O by kidneys Oxytocin: induces labor and milk release from mammary glands in females Polypeptides Amino acid derivatives Steroids Figure 47-3-2 Polypeptides Amino acid derivatives Steroids Thyroid gland Thyroxine: increases metabolic rate and heart rate; promotes growth Adrenal glands Epinephrine: produces many effects related to short-term stress response Cortisol: produces many effects related to short-term and long-term stress responses Aldosterone: increases reabsorption of Na+ by kidneys Kidneys Erythropoietin (EPO): increases synthesis of red blood cells Vitamin D: decreases blood Ca2+ Testes (in males) Testosterone: regulates development and maintenance of secondary sex characteristics in males; other effects Figure 47-3-3 Polypeptides Amino acid derivatives Steroids Pituitary gland Growth hormone (GH): stimulates growth Adrenocorticotropic hormone (ACTH): stimulates adrenal glands to secrete glucocorticoids Thyroid-stimulating hormone (TSH): stimulates thyroid gland to secrete thyroxine Follicle-stimulating hormone (FSH) and luteinizing hormone (LH): involved in production of sex hormones; regulate menstrual cycle in females Prolactin: stimulates mammary gland growth and milk production in females Figure 47-3-4 Polypeptides Amino acid derivatives Steroids Parathyroid glands Parathyroid hormone (PTH): increases blood Ca2+ Pancreas (islets of Langerhans) Insulin: decreases blood glucose Glucagon: increases blood glucose Ovaries (in females) Estradiol: regulates development and maintenance of secondary sex characteristics in females; other effects Progesterone: prepares uterus for pregnancy Chemical characteristics of hormones – major classes Peptides and Polypeptides Secretin Amino Acid Derivatives Steroids Cortisol Epinephrine Receptor Receptor Not lipid soluble; bind to receptors on surface of target cell Target cell Most not lipid soluble; bind to receptors on surface of target cell Lipid soluble; bind to receptors inside target cell Receptor Hormone Transport and Action on Target Hydrophobic messengers pass into cell (and sometimes the nucleus) where they bind with transcription factors which affect gene expression. Hydrophilic hormones bind to a receptor on the cell membrane which causes several reactions known as a signal transduction pathway. This can affect the properties of enzymes/proteins, etc. or it may affect gene expression. This picture shows a hormone traveling through the cell membrane and binding with a transcription factor. Which of the following statements are true? A) This is a membrane soluble (hydrophobic) hormone that alters gene transcription. B) This is a membrane soluble (hydrophobic) hormone that alters immediate enzyme activity and cell processes. C) This is a membrane insoluble (hydrophilic) hormone that alters gene transcription. D) This is a membrane insoluble (hydrophilic) hormone that alters immediate enzyme activity and cell processes. Barry Bonds was accused of using a steriod ‘the cream’ to increase his athletic performance. He supposedly applied this to his skin. What does this tell you about the nature of this hormone? A. B. C. D. The hormone was membrane insoluble. The hormone was membrane soluble. The hormone initiated a signal transduction pathway. A and C