Search for Antidiuretic Hormone

System Interactions in Animals Tools Finish System Interactions in Animals The human body is made of many different organ systems. Each system performs unique functions for the body, but the systems also interact with each other to perform more complex functions. Major Organ Systems Body Systems In humans, cells, tissues, and organs group together to form organ systems. These systems each perform different functions for the human body. The major organ systems and their functions in humans include: The Nervous System — The nervous systems consists of two parts. The central nervous system consists of the brain and spinal cord, while the peripheral nervous system consists of nerves that connect the central nervous system to other parts of the body. The brain plays an important role in interpreting the information picked up by the sensory system. It helps in producing a precise response to the stimuli. It also controls bodily functions such as movements, thoughts, speech, and memory. The brain also controls many processes related to homeostasis in the body. The spinal cord connects to the brain through the brainstem. From the brainstem, the spinal cord extends to all the major nerves in the body. The spinal cord is the origin of spinal nerves that branch out to various body parts. These nerves help in receiving and transmitting signals from various body parts. The spinal cord helps in reflex actions of the body The smallest unit of the nervous system is the nerve cell, or neuron. Neurons communicate with each other and with other cells by producing and releasing electrochemical signals known as nerve impulses. Neurons consist of the cell body, the dendrites, and the axon. The cell body consists of a nucleus and cytoplasm. Dendrites are specialized branch-like structures that help in conducting impulses to and from the various body parts. Axons are long, slender extensions of the neuron. Each neuron possesses just a single axon. Its function is to carry the impulses away from the cell body to other neurons. The Circulatory System — The circulatory (or cardiovascular) system is composed of the heart, arteries, veins, and capillaries. The circulatory system is responsible for transporting blood to and from the lungs so that gas exchange can take place. As the circulatory system pumps blood throughout the body, dissolved nutrients and wastes are also delivered to their destinations. The heart is a muscular organ roughly the size of an adult human's closed fist. It is present behind the breastbone, slightly to the left. It consists of four chambers: right atrium, left atrium, right ventricle, and left ventricle. The heart receives deoxygenated blood from the body and pumps this blood to the lugs, where it is oxygenated. The oxygen-rich blood reenters the heart and is then pumped back through the body. The circulatory system is responsible for transporting blood to and from the lungs so that gas exchange can take place. As the circulatory system pumps blood throughout the body, dissolved nutrients and wastes are also delivered to their destinations. Blood circulation takes place through blood vessels. Blood vessels are tubular structures that form a network within the body and transport blood to each tissue. There are three major types of blood vessels: veins, arteries, and capillaries. Veins carry deoxygenated blood from the body to the heart, except for pulmonary veins, which carry oxygenated blood from the lungs to the heart. Arteries carry oxygenated blood from the heart to different organs, except for the pulmonary artery, which carries deoxygenated blood from the heart to the lungs. The arteries branch out to form capillaries. These capillaries are thin-walled vessels through which nutrients and wastes are exchanged with cells. The Respiratory System — The main structures of the respiratory system are the trachea (windpipe), the lungs, and the diaphragm. When the diaphragm contracts, it creates a vacuum in the lungs that causes them to fill with air. During this inhalation, oxygen diffuses into the circulatory system while carbon dioxide diffuses out into the air that will be exhaled. The trachea branches out into two primary bronchi. Each bronchus is further divided into numerous secondary bronchi. These secondary bronchi further branch into tertiary bronchi. Finally, each tertiary bronchus branches into numerous bronchioles. Each bronchiole terminates into a tiny, sac-like structure known as an alveolus. The walls of each alveolus are thin and contain numerous blood capillaries. The process of gaseous exchange occurs in these alveoli. The diaphragm is a dome-shaped muscle situated at the lower end of the rib cage. It separates the abdominal cavity from the chest cavity. During inhalation, the diaphragm contracts, and the chest cavity enlarges, creating a vacuum that allows air to be drawn in. This causes the alveoli in the lungs to expand with air. During this process, oxygen diffuses into the circulatory system while carbon dioxide diffuses out into the air that will be exhaled. On the other hand, expansion of the diaphragm causes exhalation of air containing carbon dioxide. The Digestive System — The digestive system consists of the mouth, stomach, small intestine, large intestine, and anus. It is responsible for taking in food, digesting it to extract energy and nutrients that cells can use to function, and expelling the remaining waste material. Mechanical and chemical digestion takes place in the mouth and stomach, while absorption of nutrients and water takes place in the intestines. The digestive system begins at the mouth, where food is taken in, and ends at the anus, where waste is expelled. The food taken into the mouth breaks into pieces by the grinding action of the teeth. Carbohydrate digestion starts in the mouth with the breakdown of carbohydrates into simple sugars with the help of salivary enzymes. The chewed food, known as a bolus, enters the stomach through the esophagus. The bolus mixes with acids and enzymes released by the stomach. Protein digestion starts in the stomach as proteins are broken down into peptides. This partially digested food is known as chyme. Chyme enters the small intestine and mixes with bile, a substance secreted by the liver, along with enzymes secreted by the pancreas. The digestion of fats starts in the small intestine as bile and pancreatic enzymes break down fats into fatty acids. The surface of the small intestine consists of hair-like projections known as villi. These villi help in absorbing nutrients from the digested food. The digested food enters the large intestine, or colon, where water and salts are reabsorbed. Any undigested food is expelled out of the body as waste. The Skeletal System — The skeletal system is made up of over 200 bones. It protects the body's internal organs, provides support for the body and gives it shape, and works with the muscular system to move the body. In addition, bones can store calcium and produce red and white blood cells. The Muscular System — The muscular system includes more than 650 tough, elastic pieces of tissue. The primary function of any muscle tissue is movement. This includes the movement of blood through the arteries, the movement of food through the digestive tract, and the movement of arms and legs through space. Skeletal muscles relax and contract to move the bones of the skeletal system. The Excretory System — The excretory system removes excess water, dangerous substances, and wastes from the body. The excretory system also plays an important role in maintaining body equilibrium, or homeostasis. The human excretory system includes the lungs, sweat glands in the skin, and the urinary system (such as the kidneys and the bladder). The body uses oxygen for metabolic processes. Oxygen metabolism results in the production of carbon dioxide, which is a waste matter. The lungs expel carbon dioxide through the mouth and nose. The liver converts toxic metabolic wastes, such as ammonia, into less harmful susbtances. Ammonia is converted to urea, which is then excreted in the urine. The skin also expels urea and small amounts of ammonia through sweat. The skin is embedded with sweat glands. These glands secrete sweat, a solution of water, salt, and wastes. The sweat rises to the skin's surface, where it evaporates. The skin maintains homeostasis by producing sweat in hot environments. Sweat production cools and prevents excessive heating of the body. Each kidney contains about a million tiny structures called nephrons, which filter the blood and collect waste products, such as urea, salts, and excess water that go on to become urine. The Endocrine System — The endocrine system is involved with the control of body processes such as fluid balance, growth, and sexual development. The endocrine system controls these processes through hormones, which are produced by endocrine glands. Some endocrine glands include the pituitary gland, thyroid gland, parathyroid gland, adrenal glands, thymus gland, ovaries in females, and testes in males. The Immune System — The immune system is a network of cells, tissues, and organs that defends the body against foreign invaders. The immune system uses antibodies and specialized cells, such as T-cells, to defend the body from microorganisms that cause disease. The Reproductive System — The reproductive system includes structures, such as the uterus and fallopian tubes in females and the penis and testes in males, that allow humans to produce new offspring. The reproductive system also controls certain hormones in the human body that regulate the development of sexual characteristics and determine when the body is able to reproduce. The Integumentary System — The integumentary system is made up of a person's skin, hair, and nails. The skin acts as a barrier to the outside world by keeping moisture in the body and foreign substances out of the body. Nerves in the skin act as an interface with the outside world, helping to regulate important aspects of homeostasis, such as body temperature. Interacting Organ Systems The organ systems work together to perform complex bodily functions. The functions of regulation, nutrient absorption, defense, and reproduction are only possible because of the interaction of multiple body systems. Regulation All living organisms must maintain homeostasis, a stable internal environment. Organisms maintain homeostasis by monitoring internal conditions and making adjustments to the body systems as necessary. For example, as body temperature increases, skin receptors and receptors in a region of the brain called the hypothalamus sense the change. The change triggers the nervous system to send signals to the integumentary and circulatory systems. These signals cause the skin to sweat and blood vessels close to the surface of the skin to dilate, actions which dispel heat to decrease body temperature. Both the nervous system and the endocrine system are typically involved in the maintenance of homeostasis. The nervous system receives and processes stimuli, and then it sends signals to body structures to coordinate a response. The endocrine system helps regulate the response through the release of hormones, which travel through the circulatory system to their site of action. For example, the endocrine system regulates the level of sugar in the blood by the release of the hormones insulin, which stimulates uptake of glucose by cells, and glucagon, which stimulates the release of glucose by the liver. The nervous and endocrine systems interact with the excretory system in the process of osmoregulation, the homeostatic regulation of water and fluid balance in the body. The excretory system expels excess water, salts, and waste products. The excretion of excessive amounts of water can be harmful to the body because it reduces blood pressure. If the nervous system detects a decrease in blood pressure, it stimulates the endocrine system to release antidiuretic hormone. This hormone decreases the amount of water released by the kidneys to ensure appropriate blood pressure. Appropriate levels of carbon dioxide in the blood are also maintained by homeostatic mechanisms that involve several organ systems. Excess carbon dioxide, a byproduct of cellular respiration, can be harmful to an organism. As blood circulates throughout the body, it picks up carbon dioxide waste from cells and transports it to the lungs, where it is exhaled while fresh oxygen is inhaled. If the concentration of carbon dioxide in the blood increases above a certain threshold, the nervous system directs the lungs to increase their respiration rate to remove the excess carbon dioxide, which ensures that the levels of carbon dioxide in the blood are maintained at appropriate levels. In this way, the circulatory, respiratory, and nervous systems work together to limit the level of carbon dioxide in the blood. Nutrient Absorption To absorb nutrients from food, the nervous, digestive, muscular, excretory, and circulatory systems all interact. The nervous system controls the intake of food and regulates the muscular action of chewing, which mechanically breaks down food. As food travels through the stomach and intestines, the digestive system structures release enzymes to stimulate its chemical breakdown. At the same time, the muscular action, called peristalsis, of the muscles in the wall of the stomach help churn the food and push it through the digestive tract. In the intestines, nutrients from food travel across the surfaces of the villi. The nutrients are then picked up by the blood, and the circulatory system transports the nutrients throughout the cells of the body. The endocrine system releases hormones, such as insulin, that control the rate at which certain body cells use nutrients. Any excess minerals, such as calcium, in the blood are deposited in and stored by the skeletal system. Waste products produced by the use of nutrients, as well as the leftover solid waste from the digestion of food, exit the body through the excretory system. Throughout the process of nutrient absorption, the nervous system controls the muscles involved in digestion, circulation, and excretion. Defense Several body systems interact to defend the body from external threats. The body's first line of defense is the integumentary system, which provide a physical barrier that prevents pathogens from entering the body. The skin of the integumentary system also contains receptors for pain, temperature, and pressure. If an unpleasant stimulus is encountered, these receptors send signals to the central nervous system. In response, the central nervous system sends commands to the muscles to move the body part away from the stimulus. In this way, the integumentary, nervous, and muscular systems interact to prevent damage to the body. In the event of a break in the skin, the nervous, immune, lymphatic, and circulatory systems work together to repair the wound and protect the body from pathogens. When the skin is broken, specialized blood cells called platelets form a clot to stop the bleeding. These platelets also release chemicals that travel through the circulatory system and recruit cells, like immune system cells, to repair the wound. These immune cells, or white blood cells, are transported by the circulatory and lymphatic systems to the site of the wound, where they identify and destroy potentially pathogenic cells to prevent an infection. Some lymphocytes, white blood cells produced by the lymphatic system, also produce antibodies to neutralize specific pathogens. All of the white blood cells involved in the body's response were originally produced in the bone marrow of the skeletal system. If an infection does occur

Updated 182d ago

Negative and Positive Feedback Loops Control hormone levelsNegative feedback loopHormone release stops in response to decrease in stimulus- Stimulus (eating) raises blood glucose levels- Pancreas releases insulin in response to elevated blood glucose- Blood glucose decreases as it is used by the body or stored in the liver - Insulin release stops as blood glucose levels normalize Positive feedback loop As long as stimulus is present, action of hormone continues- Infant nursing at mother’s breast→stimulates hypothalamus→stimulates posterior pituitary- Oxytocin released→stimulates milk production and ejection from mammary glands- Milk release continues as long as infant continues to nurse The Major Endocrine OrgansThe major endocrine organs of the body include: the pituitary, pineal, thyroid, parathyroid, thymus, and adrenal glands, pancreas, and gonads (ovaries and testes)Endocrine glands - Ductless - Release hormones - Directly into target tissues - Into bloodstream to be carried to target tissuesHormones(Greek word hormone – to set into motion) Pituitary Gland and Hypothalamus o The pituitary gland is approximately the size of a pea. o It hangs by a stalk from the inferior surface of the hypothalamus of the brain, where it is snugly surrounded by the sella turcica of the sphenoid bone. o It has two functional lobes – the anterior pituitary (glandular tissue) and the posterior pituitary (nervous tissue). o The anterior pituitary gland controls the activity of so many other endocrine glands (“master endocrine gland”) o The release of each of its hormones is controlled by releasing hormones and inhibiting hormones produced by the hypothalamus. o The hypothalamus also makes two additional hormones, oxytocinand antidiuretic hormone, which are transported along the axons of the hypothalamic nuerosecretory cells to the posterior pituitary for storage. They are later released into the blood in response to nerve impulses from the hypothalamus. Oxytocin o Is released in significant amounts only during childbirth and nursing. o It stimulates powerful contractions of the uterine muscle during sexual relations, during labor, and during breastfeeding. o It also causes milk ejection (let-down reflex) in a nursing woman. Antidiuretic Hormone (ADH) o ADH is a chemical that inhibits or prevents urine production. o ADH causes the kidneys to reabsorb more water from the forming urine; as a result, urine volume decreases, and blood volume increases. o In larger amounts, ADH also increases blood pressure by causing constriction of the arterioles (small arteries). For this reason, it is sometimes referred to as vasopressin. Anterior Pituitary HormonesThe anterior pituitary produces several hormones that affect many body organs. Growth Hormone (GH) o Its major effects are directed to the growth of skeletal muscles and long bones of the body o At the same time, it causes fats to be broken down and used for energy while it spares glucose, helping to maintain blood sugar homeostasis. ProlactinIts only known target in humans is the breast.After childbirth, it stimulates and maintains milk production by the mother’s breasts.Gonadotropic Hormones (FSH and LH) o Regulate the hormonal activity of the gonads (ovaries and testes) o In women, the FSH stimulates follicle development in the ovaries. o In men, FSH stimulates sperm production by the testes. o LH triggers ovulation of an egg from the ovary and causes the ruptured follicle to produce progesterone and some estrogen. o LH stimulates testosterone production by the interstitial cells of the testes. Pineal Gland The pineal gland is a small, cone-shaped gland that hangs from the roof of the third ventricle of the brain. Melatonin o The only hormone secreted from pineal gland in substantial amounts o Believed to be a “sleep trigger” that plays an important role in establishing the body’s sleep-wake cycle. o The level of melatonin rises and falls during the course of the day and night. o The peak level occurs at night and makes us drowsy o The lowest level occurs during daylight around noon. Thyroid Gland • The thyroid gland is located at the base of the throat, just inferior to the Adam’s apple. • It is a fairly large gland consisting of two lobes joined by a central mass, or isthmus. • The thyroid gland makes two hormones, one called thyroid hormone, the other called calcitonin. Thyroid Hormone o Referred to as body’s major metabolic hormone o Contains two active iodine-containing hormones, thyroxine (T4)and thriiodothyronine (T3) o Most triiodothyronine is formed at the target tissues by conversion of thyronine to triiodothyronine o Thyroid hormone controls the rate at which glucose is “burned”, or oxidized, and converted to body heat and chemical energy (ATP). o Thyroid hormone is also important for normal tissue growth and development, especially in the reproductive and nervous systems. Homeostatic Imbalance ➢ Without iodine, functional thyroid hormones cannot be made. ➢ The source of iodine is our diet (seafoods) ➢ Goiter is an enlargement of the thyroid gland that results when the diet is deficient in iodine. Hyposecretion of thyroxine may indicate problems other than iodine deficiency. If it occurs in early childhood, the result is cretinism. ▪ Results in dwarfism and mental retardation (if discovered early, hormone replacement will prevent mental impairment) Hypothyroidism occurring in adults results in myxedema ▪ Characterized by both physical and mental sluggishness (no mental impairment) ▪ Other signs are puffiness of the face, fatigue, poor muscle tone, low body temperature, obesity, and dry skin (Oral thyroxine is prescribed to treat this condition) ➢ Hyperthyroidism generally results from a tumor of the thyroid gland. ➢ Extreme overproduction of thyroxine results in a high basal metabolic rate, intolerance of heat, rapid heartbeat, weight loss, nervous and agitated behavior, and a general inability to relax. Graves’ disease o A form of hyperthyroidism o The thyroid gland enlarges, the eyes bulge (exophthalmos) Calcitonin ➢ Second important hormone product of the thyroid gland ➢ Decreases the blood calcium ion level by causing calcium to be deposited in the bones Parathyroid Glands ➢ The parathyroid glands are tiny masses of glandular tissue most often on the posterior surface of the thyroid gland. ➢ Parathyroid hormone (PTH) is the most important regulator of calcium ion homeostasis of the blood. ➢ Although the skeleton is the major PTH target, PTH also stimulates the kidneys and intestine to absorb more calcium ions. Homeostatic Imbalance o If blood calcium ion level falls too low, neurons become extremely irritable and overactive. They deliver impulses to the muscles so rapidly that the muscles go into uncontrollable spasms (tetany), which may be fatal. o Severe hyperparathyroidism causes massive bone destruction. The bones become very fragile, and spontaneous fractures begin to occur. Thymus o Is located in the upper thorax, posterior to the sternum. o Large in infants and children, it decreases in size throughout adulthood. o By old age, it is composed mostly of fibrous connective tissue and fat. o The thymus produces a hormone called thymosin and others that appear to be essential for normal development of a special group of white blood cells (T lymphocytes) and the immune response. Adrenal Glands o The two adrenal glands curve over the top of the kidneys like triangular hats. o It is structurally and functionally two endocrine organs in one. • it has parts made of glandular (cortex) and neural tissue (medulla) • The central medulla region is enclosed by the adrenal cortex, which contains three separate layers of cells. Hormones of the Adrenal CortexThe adrenal cortex produces three major groups of steroid hormones, collectively called corticosteroids: 1. Mineralocorticoids (aldosterone) ➢ Are produced by the outermost adrenal cortex cell layer. ➢ Are important in regulating the mineral (salt) content of the blood, particularly the concentrations of sodium and potassium ions. ➢ These hormones target the kidney tubules(Distal Convulating Kidney Tubles) that selectively reabsorb the minerals or allow them to be flushed out of the body in urine. ➢ When the blood level of aldosterone rises, the kidney tubule cell reabsorb increasing amounts of sodium ions and secrete more potassium ions into the urine. ➢ When sodium is reabsorbed, water follows. Thus, the mineralocorticoids help regulate both water and electrolyte balance in body fluids. 2. Glucocorticoids (Cortisone and Cortisol) ➢ Glucocorticoids promote normal cell metabolism and help the body to resist long-term stressors, primarily by increasing the blood glucose level. ➢ When blood levels of glucocorticoids are high, fats and even proteins are broken down by body cells and converted to glucose, which is released to the blood. ➢ For this reason, glucocorticoids are said to be hyperglycemic hormones. ➢ Glucocorticoids also seem to control the more unpleasant effects of inflammation by decreasing edema, and they reduce pain by inhibiting the pain-causing prostaglandins. ➢ Because of their anti-inflammatory properties, glucocorticoids are often prescribed as drugs to suppress inflammation for patients with rheumatoid arthritis. ➢ Glucocorticoids are released from the adrenal cortex in response to a rising blood level of ACTH (Adrenocorticotropic hormone). 3. Sex Hormones ➢ In both men and women, the adrenal cortex produces both male and female sex hormones throughout life in relatively small amounts. ➢ The bulk of the sex hormones produced by the innermost cortex layer are androgens (male sex hormones), but some estrogens (female sex hormones) are also formed. Homeostatic Imbalance1. Addisson’s disease (hyposecretion of all the adrenal cortex hormones) ✓ Bronze tone of the skin (suntan) ✓ Na (sodium) and water are lost from the body ✓ Muscles become weak and shock is a possibility ✓ Hypoglycemia (↓ glucocorticoids) ✓ Suppression of the immune system 2. Hyperaldosteronism (hyperactivity of the outermost cortical area) ✓ Excessive water and sodium ions retention ✓ High blood pressure ✓ Edema ✓ Low potassium ions level (hypokalemia) 3. Cushing’s Syndrome (Excessive glucocorticoids) ✓ Swollen “moon face” and “Buffalo hump” ✓ High blood pressure and hyperglycemia (steroid diabetes) ✓ Weakening of the bones (as protein is withdrawn to be converted to glucose) ✓ Severe depression of the immune system 4. Hypersecretion of the sex hormones leads to masculinization, regardless of sex. Hormones of the Adrenal Medulla ➢ When the medulla is stimulated by sympathetic nervous system neurons, its cells release two similar hormones, epinephrine(adrenaline) and norepinephrine (noradrenaline), into the bloodstream. ➢ Collectively, these hormones are called catecholamines. ➢ The catecholamines of the adrenal medulla prepare the body to cope with short-term stressful situations and cause the so-called alarm stage of the stress response. ➢ Glucocorticoids, by contrast, are produced by the adrenal cortex and are important when coping with prolonged or continuing stressors, such as dealing with the death of a family member or having a major operation (resistance stage). Pancreatic Islets ➢ The pancreas, located close to the stomach in the abdominal cavity, is a mixed gland. ➢ The pancreatic islets, also called the islets of Langerhans, are little masses of endocrine (hormone-producing) tissue of the pancreas. ➢ The exocrine, or acinar, part of the pancreas acts as part of the digestive system. ➢ Two important hormones produced by the islet cells are insulin and glucagon. Insulin ➢ Hormone released by the beta cells of the islets in response to a high level of blood glucose. ➢ Acts on all body cells, increasing their ability to import glucose across their plasma membranes. ➢ Insulin also speeds up these “use it” or “store it” activities. ➢ Because insulin sweeps the glucose out of the blood, its effect is said to be hypoglycemic. ➢ Without it, essentially no glucose can get into the cells to be used. Glucagon ➢ Acts as an antagonist of insulin ➢ Released by the alpha cells of the islets in response to a low blood glucose levels. ➢ Its action is basically hyperglycemic. ➢ Its primary target is the liver, which it stimulates to break down stored glycogen to glucose and to release the glucose into the blood. Gonads ➢ The female and male gonads produce sex cells. ➢ They also produce sex hormones that are identical to those produced by adrenal cortex cells. ➢ The major differences from the adrenal sex hormone production are the source and relative amounts of hormones produced. Hormones of the OvariesBesides producing female sex cells (ova, or eggs), ovaries produce two groups of steroid hormones, estrogens and progesterone. 1. Estrogen (Steroid Hormone) ➢ Responsible for the development of sex characteristics in women (primarily growth and maturation of the reproductive organs) and the appearance of secondary sex characteristics at puberty. ➢ Acting with progesterone, estrogens promote breast development and cyclic changes in the uterine lining (the menstrual cycle) 2. Progesterone (Steroid Hormone) ➢ Acts with estrogen to bring about the menstrual cycle. ➢ During pregnancy, it quiets the muscles of the uterus so that an implanted embryo will not be aborted and helps prepare breast tissue for lactation. Hormones of the TestesIn addition to male sex cells, or sperm, the testes also produce male sex hormones, or androgens, of which testosterone is the most important. 3. Testosterone ➢ Promotes the growth and maturation of the reproductive system organs to prepare the young man for reproduction. ➢ It also causes the male’s secondary sex characteristics to appear and stimulates the male sex drive. ➢ It is necessary for continuous production of sperm. ➢ Testosterone production is specifically stimulated by LH. Other Hormone-Producing Tissues and OrgansPlacenta ➢ During very early pregnancy, a hormone called human chorionic gonadotropin (hCG) is produced by the developing embryo and then by the fetal parts of the placenta. ➢ hCG stimulates the ovaries to continue producing estrogen and progesterone so that the lining of the uterus is not sloughed off in menses. ➢ In the third month, the placenta assumes the job of the ovaries of producing estrogen and progesterone, and the ovaries become inactive for the rest of the pregnancy. ➢ The high estrogen and progesterone blood levels maintain the lining of the uterus and prepare the breasts for producing milk. ➢ Human placental lactogen (hPL) works cooperatively with estrogen and progesterone in preparing the breasts for lactation. ➢ Relaxin, another placental hormone, causes the mother’s pelvic ligaments and the pubic symphysis to relax and become more flexible, which eases birth passage. Developmental Aspects of the Endocrine System ➢ In late middle age, the efficiency of the ovaries begins to decline, causing menopause. o Reproductive organs begin to atrophy o Ability to bear children ends o Problems associated with estrogen deficiency begin to occur (arteriosclerosis, osteoporosis, decreased skin elasticity, “hot flashes”) ➢ No such dramatic changes seem to happen in men. ➢ Elderly persons are less able to resist stress and infection. ➢ Exposure to pesticides, industrial chemicals, dioxin, and pother soil and water pollutants diminishes endocrine function, which may explain the higher cancer rates among older adults in certain areas of the country. ➢ All older people have some decline in insulin production, and type 2 diabetes mellitus is most common in this age group. BLOOD ➢ It is the only fluid tissue in the body. ➢ A homogenous liquid that has both solid and liquid components. ➢ Taste, Odor, 5x thicker than water ➢ Classified as a connective tissue ❖Living cells = formed elements ❖Non-living matrix = plasma (90% water) Components •Formed elements (blood cells)are suspended in plasma •The collagen and elastin fibers typical of other connective tissues are absent from blood; instead, dissolved proteins become visible as fibrin strands during blood clotting •If a sample of blood is separated, the plasma rises to the top, and the formed elements, being heavier, fall to the bottom. •Most of the erythrocytes (RBCs) settle at the bottom of the tube •There is a thin, whitish layer called the buffy coat at the junction between the erythrocytes and the plasma containing leukocytes (WBCs) and platelets Physical Characteristics and Volume • Color range ➢ Oxygen-rich blood is scarlet red ➢ Oxygen-poor blood is dull red • pH must remain between 7.35–7.45 • Slightly alkaline • Blood temperature is slightly higher than body temperature • 5-6 Liters or about 6 quarts /body Functions and Composition of Blood 1. Transport of gases, nutrients and waste products 2. Transport of processed molecules 3. Transport of regulatory molecules 4. Regulation of pH and osmosis 5. Maintenance of body temp 6. Protection against foreign substances 7. Clot formation Plasma • The liquid part of the blood; 90 percent water • Over 100 different substances are dissolved in this straw-colored fluid: ➢ nutrients ➢ electrolytes ➢ respiratory gases ➢ hormones ➢ plasma proteins; and ➢ various wastes and products of cell metabolism • Plasma proteins are the most abundant solutes in plasma (albumin and clotting proteins) • Plasma helps to distribute body heat, a by-product of cellular metabolism, evenly throughout the body. Formed Elements Erythrocytes (RBCs) • Function primarily to ferry oxygen to all cells of the body. • RBCs differ from other blood cells because they are anucleate (no nucleus) • Contain very few organelles (RBCs circulating in the blood are literally “bags” of hemoglobin molecules ) •Very efficient oxygen transporters (they lack mitochondria and make ATP by anaerobic mechanisms) • Their small size and peculiar shape provide a large surface area relative to their volume, making them suited for gas exchange • RBCs outnumber WBCs by about 1,000 to 1 and are the major factor contributing to blood viscosity. • There are normally about 5 million cells per cubic millimeter of blood. • The more hemoglobin molecules the RBCs contain, the more oxygen they will be able to carry. • A single RBC contains about 250 million hemoglobin molecules, each capable of binding 4 molecules of oxygen. • Normal hemoglobin count is 12-18 grams of hemoglobin per 100 ml of blood • Men: 13-18g/ml Women: 12-16 g/ml Homeostatic Imbalance Anemia • a decrease in the oxygen-carrying ability of the blood, whatever the reason is. • May be the result of (1) a lower-than-normal number of RBCs or (2) abnormal or deficient hemoglobin content in the RBCs. Polycythemia Vera • An excessive or abnormal increase in the number of erythrocytes; may result from bone marrow cancer or a normal physiologic response to living at high altitudes, where the air is thinner and less oxygen is available (secondary polycythemia) Formed Elements Leukocytes (WBCs) • Are far less numerous than RBCs • They are crucial to body defense • On average, there are 4,800 to 10,800 WBCs/mm3 of blood • WBCs contain nuclei and the usual organelles, which makes them the only complete cells in the blood. • WBCs are able to slip into and out of the blood vessels – a process called diapedesis • WBCs can locate areas of tissue damage and infection in the body by responding to certain chemicals that diffuse from the damaged cells (positive chemostaxis) • Whenever WBCs mobilize for action, the body speeds up their production, and as many as twice the normal number of WBCs may appear in the blood within a few hours. • A total WBC count above 11,000 cells/mm3 is referred to as leukocytosis. • The opposite condition, leukopenia, is an abnormally low WBC count (commonly caused by certain drugs, such as corticosteroids and anti-cancer agents) • WBCs are classified into two major groups – granulocytes and agranulocytes – depending on whether or not they contain visible granules in their cytoplasm. Granulocytes Neutrophils ➢ Are the most numerous WBCs. ➢ Neutrophils are avid phagocytes at sites of acute infection. Eosinophils ➢ Their number increases rapidly during infections by parasitic worms ingected in food such as raw fish or entering through the skin. Basophils ➢ The rarest of the WBCs, have large histamine-containing granules. Histamine ➢ is an inflammatory chemical that makes blood vessels leaky and attracts other WBCs to the inflamed site Agranulocytes Lymphocytes ➢ Have a large, dark purple nucleus that occupies most of the cell volume. ➢ Lymphocytes tend to take up residence in lymphatic tissues, such as the tonsils, where they play an important role in the immune response. ➢ They are the second most numerous leukocytes in the blood Monocytes ➢ Are the largest of the WBCs. ➢ When they migrate into the tissues, they change into macrophages. ➢ Macrophages are important in fighting chronic infections, such as tuberculosis, and in activating lymphocytes Platelets ➢ They are fragments of bizarre multinucleate cells called megakaryocytes, which pinch off thousands of anucleate platelet “pieces” that quickly seal themselves off from the surrounding fluids. ➢ Normal adult has 150,000 to 450,000 per cubic millimeter of blood ➢ Platelets are needed for the clotting process that stops blood loss from broken blood vessels. ➢ Average lifespan is 9 to 12 days Hematopoiesis • Occurs in red bone marrow, or myeloid tissue. • In adults, this tissue is found chiefly in the axial skeleton, pectoral andpelvic girdles, and proximal epiphyses of the humerus and femur. • On average, the red marrow turns out an ounce of new bloodcontaining 100 billion new cells every day. • All the formed elements arise from a common stem cell, thehemocytoblast, which resides in red bone marrow. • Once a cell is committed to a specific blood pathway, it cannotchange. • The hemocytoblast forms two types of descendants – the lymphoidstem cell, which produces lymphocytes, and the myeloid stem cell,which can produce other classes of formed elements. Formation of RBCs • Because they are anucleate, RBCs are unable to synthesizeproteins, grow, or divide. • As they age, RBCs become rigid and begin to fall apart in 100 to 120 days. • Their remains are eliminated by phagocytes in the spleen, liver, and other body tissues. • RBC components are salvaged. Iron is bound to protein as ferritin, and the balance of the heme group is degraded to bilirubin, which is then secreted into the intestine by liver cells where it becomes a brown pigment called stercobilin that leaves the body in feces. • Globin is broken down to amino acids which are released into the circulation.The rate of erythrocyte production is controlled by a hormone called erythropoietin (from the kidneys) • Erythropoietin targets the bone marrow prodding it into “high gear” to turn out more RBCs. • An overabundance of erythrocytes, or an excessive amount of oxygen in the bloodstream, depresses erythropoietin release and RBC production. • However, RBC production is controlled not by the relative number of RBCs in the blood, but by the ability of the available RBCs to transport enough oxygen to meet the body’s demands Formation of WBCs and Platelets • The formation of leukocytes and platelets is stimulated by hormones • These colony stimulating factors (CSFs) and interleukins not only prompt red bone marrow to turn out leukocytes, but also enhance the ability of mature leukocytes to protect the body. • The hormone thrombopoietin accelerates the production of platelets from megakaryocytes, but little is know about how process is regulated. • When bone marrow problems or disease condition is suspected, bone marrow biopsy is done. Hemostasis If a blood vessel wall breaks, a series of reactions starts the process of hemostasis (stopping the bleeding). Phases of Hemostasis 1. Vascular spasms occur. 2. Platelet plug forms. 3. Coagulation events occur. Human Blood Groups • An antigen is a substance that the body recognizes as foreign; it stimulates the immune system to mount a defense against it. • The “recognizers” are antibodies present in plasma that attach to RBCs bearing surface antigens different from those on the patient’s RBCs. ABO and Rh Blood Types The blood group system recognizes four blood types: • Type A, B, AB, and O • They are distinguished from each other in part by their antigens and antibodies. • Specific antibodies are found in the serum based on the type of antigen on the surface of the RBC ABO and Rh Blood Types BLOOD TYPE Can Accept From Can Donate To A A, O A, AB B B, O B, AB AB A, B, AB, O AB O O O, A, B, AB The Rh Factor Rh-Positive Rh-Negative Contains the Rh antigen -No Rh antigen -Will make antibodies if given Rh-positive blood -Agglutination can occur if given Rh-positive blood Summary • Blood is responsible for transporting oxygen, fluids, hormones, and antibodies and for eliminating waste materials. • The major components of blood include the formed elements and plasma. • RBCs transport oxygen and carbon dioxide; WBCs destroy foreign invaders. • WBCs include granulocytes and agranulocytes. • Plasma is the liquid portion of unclotted blood. Serum is the liquid portion of clotted blood • Hemostasis includes four stages: blood vessel spasm, platelet plug formation, blood clotting, and fibrinolysis. • ABO and Rh types are determined by the antigen found on the RBCs

Updated 335d ago

Results for "Antidiuretic Hormone"

Flashcards