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A day at the sauna 3 of 40 How does the body react to change?
Saving energy? 4 of 40 Sayid has decided to save energy by staying in bed all day. How much of his energy do you think this will save? Surprisingly, the answer is only about 30%. The other 70% keeps his body temperature at 37 C, and the solutions around his cells at just the right concentration.
What is homeostasis? 5 of 40 The body uses so much energy, even during sleep, because it must maintain a constant internal environment. This process of keeping things the same is called homeostasis. A series of automatic control systems ensures that the body maintains a constant temperature, and steady levels of water, ions and blood sugar. Homeostasis allows the body s cells to work at their optimum.
Keeping comfortable 6 of 40
The organs of homeostasis 7 of 40
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Why control temperature? 9 of 40 Environmental temperature is constantly changing. One minute it can be very hot, the next very cold. Despite this, the body must be kept at a constant temperature of 37 C. Why? This is the optimum temperature for the body s enzymes. Even slight changes in body temperature can have a lifethreatening effect on health. If body temperature falls too low, reactions become too slow for cells to survive: too high, and the body s enzymes are at risk of denaturing.
What is core body temperature? 10 of 40 The vital organs located deep within the body, such as the heart, liver and kidneys, are maintained at 37 C. This is the core body temperature. Skin temperature at the body's extremities, such as the fingers and toes, is usually lower than the core body temperature. On a warm day, skin temperature may be just 1 C lower than the core body temperature, but on a very cold day it could be up to 9 C lower.
Finding the right balance 11 of 40 Core temperature is maintained by balancing heat gain and heat loss. How can heat be gained? movement and exercise shivering vasoconstriction wearing extra clothing. How can heat be lost? sweating vasodilation removing extra clothing.
Too hot or too cold? 12 of 40
Finding the right balance 13 of 40
How is temperature controlled? 14 of 40 Body temperature is monitored and controlled by temperature receptors in the skin and brain. hypothalamus These receptors detect changes in the temperature of blood flowing through those areas. The thermoregulatory centre in the brain is called the hypothalamus. If body temperature deviates from 37 C, the hypothalamus and skin receptors send out electrical signals that trigger actions or behaviours that increase or decrease heat loss.
What s in skin? 15 of 40
Why do we shiver? 16 of 40 When core body temperature drops, muscles begin to twitch. This rapid and contraction and relaxation of the muscles is called shivering. Shivering generates heat, which raises body temperature. Goose bumps involuntarily appear when a person becomes cold. Goosebumps are caused by the tiny muscles at the base of body hairs pulling the hairs erect. The upright hairs trap an insulating layer of air, which helps reduce heat loss.
Vasoconstriction and warming up 17 of 40 Why do people go pale when they are cold? When core body temperature falls, blood vessels in the skin get narrower. This is called vasoconstriction. Vasoconstriction is caused by contraction of the muscular wall of the blood vessels. This reduces the volume of blood flowing near the skin surface, and reduces the amount of heat lost from the body.
Vasodilation and cooling down 18 of 40 Why do people turn red when they are hot? When core body temperature rises, blood vessels in the skin get wider. This is called vasodilation. Vasodilation allows a larger volume of blood to flow near the skin surface, transferring heat to the environment. This cools the body down. Additional cooling occurs with the production of sweat from sweat glands. As the sweat evaporates it transfers heat away from the body.
Responding to change 19 of 40
Temperature control in newborns 20 of 40 Sayid has a baby sister. Samira was born premature and is too young to control her temperature. An incubator helps to control her temperature, using negative feedback. The air around Samira is kept at 32 C. Why is it not keep at 37 C?
How do incubators work? 21 of 40
Negative feedback in the body 22 of 40
Thermoregulation: true or false? 23 of 40
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Why is water important? 25 of 40 The human body is about 60-70% water. Water molecules and ions constantly move in and out of cells, and are essential for all life processes. Dehydration (loss of too much water from the body) damages cells. How is water gained and lost? Water is produced by the body during respiration, and absorbed from food and drink. Water is lost from the body in exhaled air, sweat, urine and faeces.
Dehydration and its causes 26 of 40 Just a 1% decrease in body weight due to water loss is enough to cause mild dehydration. Mild dehydration can cause dizziness, a dry mouth and concentrated urine. Severe dehydration can cause death. What causes dehydration? heavy sweating low water intake eating salty food breathing dry air caffeine and alcohol diarrhoea.
Controlling water levels 27 of 40
How do the kidneys work? 28 of 40
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What is blood glucose? 30 of 40 Glucose is a type of sugar used by the body to provide energy. Sometimes there is too much glucose in the blood, and sometimes there is not enough. What affects the level of blood glucose? Eating causes blood glucose levels to rise. Vigorous exercise causes blood glucose levels to fall. How does the body regulate blood glucose levels?
Controlling blood glucose 31 of 40 Between meals, blood glucose levels are topped up from stored deposits in the liver and muscles. After a meal, blood glucose rises but quickly returns to normal. Where does the excess go? Why not leave it in the blood? Excess glucose makes the blood plasma and tissue fluid around cells too concentrated. This can severely damage cells, for example, causing crenation in red blood cells. However, low blood sugar levels can be equally as dangerous, as it can make cells swell up and burst. This is called lysis.
The pancreas and blood glucose 32 of 40 Blood glucose levels are monitored and controlled by the pancreas. The pancreas produces and releases different hormones depending on the blood glucose level. pancreas Insulin is released when blood glucose levels are high the liver stores excess glucose as glycogen. Glucagon is released when blood glucose levels are low the liver converts stored glycogen into glucose and releases it into the blood.
Maintaining safe glucose levels 33 of 40
Maintaining safe glucose levels 34 of 40
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Glossary (1/3) 36 of 40 ADH The hormone released from the pituitary gland that acts on kidneys and blood vessels to maintain the body s water balance. dehydration The loss of too much water from the body. homeostasis The constant regulation of the body's internal environment. hyperthermia Dangerously high body temperature. hypothalamus The part of the brain that helps to regulate the body's internal environment. hypothermia Dangerously low body temperature. glucose The main source of energy for the body.
Glossary (2/3) 37 of 40 glucoregulation The homeostatic control of the body s blood sugar level. glycogen A storage form of glucose, found in the liver and muscles. insulin A hormone involved in the control of blood sugar, and which is reduced or absent in people with diabetes. kidney The bean-shaped organ that filters the blood and produces urine. negative feedback A stabilizing mechanism that slows down or reverses a stimulus.
Glossary (3/3) 38 of 40 osmoregulation The homeostatic control of the body s water and ion balance. pancreas The organ that secretes the hormone insulin. thermoregulation The homeostatic control of the body s temperature. vasoconstriction The narrowing of the blood vessels in the skin in order to reduce heat loss. vasodilation The widening of the blood vessels in the skin in order to increase heat loss.
Anagrams 39 of 40
Multiple-choice quiz 40 of 40