homeostasis

Question 1

homeostasis

Answer 1

process of keeping the environment inside fairly constant despite fluctuations in external environment.
- Body needs optimal temp, pH, oxygen, glucose, etc.
- Makes us independent of external environment.
- There is a dynamic equilibrium, input and output need to be balanced
- Nervous and endocrine system are the main sensory and controlling body systems
› Operate through feedback systems

Question 2

feedback system

Answer 2

responds to stimulus, response alters original stimulus

• Stimulus: change in environment that causes system to operate
• Receptor: detects change
• Modulator: control centre responsible for processing information from receptor and for sending information to effector
• Effector: carries out a response counteracting/enhancing the effect of the stimulus
• Response: original stimulus has been changed. Feedback achieved
• Homeostatic mechanisms controlled by nervous and endocrine systems. Both detect changes, endocrine is slower.

Question 3

negative feedback

Answer 3

response reduces or eliminates the stimulus that caused feedback loop.
- AKA steady state system: return body back to steady state
- Dynamic equilibrium = fluctuation
- Point around which it fluctuates = set point
- Tolerance limits = upper and lower limits around which levels fluctuate
› If rise/fall exceeds tolerance limits, dysfunctions occur

Question 4

positive feedback

Answer 4

no role in homeostasis. Response to stimulus reinforces and intensifies the stimulus results in a greater response
- Childbirth:
› Labour initiated by secretion of oxytocin
› Oxytocin creates uterine contractions; contractions push baby’s head against cervix
› Stimulation of cervix sends impulses to brain which secretes more oxytocin.
› Increased oxytocin increasingly intensifies contractions
› Once baby delivered and cervix no longer stretched, positive feedback stops
- Blood clotting is another example
- Can be dangerous if you have a high fever:
› small rise in temp is good when fighting fever, but when body temp exceeds 42ºC, positive feedback loop occurs
› raised body temp increases metabolic rate which makes more heat, so temp increases.

Question 5

thermoregulation

Answer 5

• Set point is 36.8ºC: optimal temp for cellular activities
• Heat gain = heat loss
• Heat gain: heat from metabolism, heat from surroundings by conduction/radiation
• Heat loss: radiation, convection, conduction to surroundings, evaporation of water from skin and lungs, warm air breathed out, warm urine and faeces excreted

Question 6

heat production

Answer 6

• Food we eat contains energy in chemical bonds
  › Energy released when oxidised
  › 60% of energy used for heat production
• Metabolic rate: rate at which energy is released by breakdown of food
• Factors effecting metabolic rate
  › Exercise
  › Body temp
  › Stress: stimulation of sympathetic nerves releases noradrenaline from nerve endings: increasing metabolic activity of cells

Question 7

thermoreceptors

Answer 7

• Peripheral thermoreceptors: detect temp change in external environment, and send info to hypothalamus (skin and mucous membrane)
• Central thermoreceptors: detect temp of internal environment (hypothalamus, spinal cord, abdominal organs)
• Cold receptors: stimulated by temp lower than normal
• Heat receptors: detect temp higher than normal

Question 8

skin and thermoregulation

Answer 8

• Large SA and location of skin makes it essential. Heat can be lost by:
  › Conduction: transfer by direct contact
  › Convection: transfer by movement of liquid/gas
  › Radiation: transfer by infrared radiation
  › Evaporation: liquid forming gas, absorbs heat energy

Question 9

blood vessels and heat loss

Answer 9

• Blood vessels in dermis carry heat to skin from body core
  › Diameter controlled by autonomic nerves
• Vasodilation: moves blood to skin and rate of heat loss increases
• Vasoconstriction: less blood to skin, heat loss rate decreases

Question 10

sweating and heat loss

Answer 10

• When heat must be lost and arterioles are already dilated, sweating occurs
• Sweating: active secretion of fluid by sweat glands and periodic contractions of cells surrounding sweat glands to pump sweat to skin surface
• Stimulated by sympathetic nerves
• Sweat: water and dissolved substances (salt, urea, lactic acid, potassium ions)
• Evaporation of sweat has a cooling effect
  › Heat removed from skin as sweat vaporises cooling skin which cools blood in skin
  › Also, water evaporated by lungs and respiratory passages

Question 11

shivering and heat gain

Answer 11

• Shivering due to increased skeletal muscle tone producing rhythmic muscle tremors
  › Energy produced by muscles is released as heat

Question 12

preventing body temp from falling

Answer 12

• Cold receptors send messages to hypothalamus
• Hypothalamus sends impulses to initiate warming processes
  › Stimulates sympathetic nerves that cause skin arterioles to constrict. Cooler skin, less heat lost from body surfaces
  › Stimulates adrenal medulla by sympathetic nerves to secrete adrenaline and noradrenaline in blood: increases cellular metabolism
  › Stimulates parts of brain that cause shivering. Under primal control of hypothalamus, conscious input from cerebral cortex can suppress urge to shiver
  › Anterior lobe secretes TSH. Increased metabolic rate which increase bod temp. slower and long lasting.
  › Reduce SA of body, remove layers, move closer to heat source (consciously aware of cold conditions)
  › Piloerection

Question 13

preventing body temp from rising

Answer 13

• Vasodilation: greater heat loss by radiation and convection
• Sweating: cooling effect in dry environment
  › Humid: sweat cant evaporate so it doesn’t absorb heat from body
  › Less thyroxine: decrease in metabolic rate
  › Removing layers, reducing physical activity

Question 14

control of thermoregulation

Answer 14

• Hypothalamus is modulator
  › Receives impulses from peripheral thermoreceptors through negative feedback loop, including autonomic nervous system, thermoregulation mechanisms are maintained

Question 15

temperature tolerance

Answer 15

• Heat stroke: body temp rises and regulating mechanisms cease. Fatal if brain cells effected (42-45ºC)
• Heat exhaustion: results from extreme sweating and vasodilation to lose heat
  › Loss of water reduces volume of blood plasma
  › vasodilation reduces resistance to blood flow
  › low BP and output of blood from heart decreases
  › body temp is almost normal
• Hypothermia: temp falls below 33ºC
  › Metabolic rate is so low that heat production is unable to replace heat lost and temp continues to fall
  › Death below 32ºC

Question 16

glucose regulation

Answer 16

• Sugar in blood in form of glucose
• Blood sugar = amount of glucose in blood
- Glucose is a source of energy
• Source of glucose is food:
- Carbohydrates broken down to glucose and then absorbed by blood through walls of small intestine
- After a meal BGL rise sharply
- Homeostatic mechanisms reduce BGL by storing excess glucose ready for when BGL drops

Question 17

glucose and glycogen

Answer 17

• Glucose is stored as glycogen
  › Glycogen: molecule made of long chains of glucose molecules
• Body can store 500g of glycogen (100g in liver, remainder in skeletal muscles)
• Excess glucose to glycogen
• Not enough glucose, glycogen to glucose

Question 18

role of liver

Answer 18

• Largest gland
• Converts glucose to glycogen or glycogen to glucose
• Liver’s blood supply comes mostly through the hepatic portal vein.
  › Brings blood from stomach, spleen, pancreas, small and large intestine
  › Liver has first chance to absorb nutrients from digested food
• Glucose absorbed by villi in small intestine
  › Hepatic portal vein brings glucose to liver
• Glucose can:
  › Removed from blood by liver to provide energy for liver functioning
  › Removed by liver/muscles and converted to glycogen for storing
  › Continue to circulate in blood, for other body cells to use as a source of energy
  › Be converted into fat for long term storage if it is in excess of that required to maintain both normal blood sugar and tissue glycogen levels
• Glycogenesis: when glucose molecules are chemically joined in long chains to make glycogen (stimulated by insulin)
  › Glycogen stored in liver is available for conversion to maintain BGL and provide energy for liver functioning
  › Glycogen in muscles provide glucose for muscle activity
• Glycogenolysis: when glycogen is broken down into glucose
  › Stimulate by glucagon
  › Glycogen is short term energy supply (6 hours). If more energy is required, body uses energy reserves stored in fat
• Gluconeogenesis: conversion of fats or proteins into glucose

Question 19

role of pancreas

Answer 19

• Clusters of hormone secreting cells (islets of Langerhans)
• Insulin causes a decrease in BGL:
  › Accelerates transport of glucose from blood into body cells (especially skeletal muscle)
  › Accelerates conversion of glucose into glycogen in liver and skeletal muscles (glycogenesis)
  › Stimulation of glucose to protein (protein synthesis)
  › Stimulating conversion of glucose into fats in adipose tissue or fats storage tissue (lipogenesis)
• BGL regulated by negative feedback loop
• As BGL rises, chemoreceptors in beta cells stimulate those cells to secret insulin
  › As BGL decrease the cells are no longer stimulated and production reduced
• Glucagon causes an increase in BGL:
  › Stimulate glycogenolysis in liver
  › Stimulates gluconeogenesis: production of sugar molecules from fats and amino acids in liver. Involves lipolysis
  › Have a mild stimulating effect on protein breakdown
• When BGL rises, chemoreceptors in alpha cells stimulate secretion of glucagon.
  › As BGL rises, cells no longer stimulated, and production reduced

Question 20

role of adrenal glands

Answer 20

• Glucocorticoids secreted by adrenal cortex
• Secretion of adrenaline/noradrenaline by adrenal medulla
• Adrenal cortex:
  › Stimulated to secrete hormones by ACTH from AL of pituitary gland
  › Cortisol secreted
  › Glucocorticoids regulate carbohydrate metabolism by ensuring enough energy is provided to cells
  › Stimulate conversion of glycogen to glucose in glycogenolysis.
  › Also increases rate at which AA are removed by cells (mainly muscle) and transported to the liver
• Some AA to glucose by liver during gluconeogenesis if glycogen and fat are low
  › Promote metabolism of fatty acids from adipose tissue, allowing muscle cells to shift from using to glucose to FA for much of their metabolic energy
• Adrenal medulla:
  › Synthesis of adrenaline and noradrenaline make same effects as sympathetic nervous system
  › Effect is increase of BGL: adrenaline elevates BGL through glycogenolysis and counteracts effects of insulin
• Stimulates production of lactic acid from glycogen in muscle cells, can be used by liver to manufacture glucose

Question 21

blood glucose homeostasis

Answer 21

• 4-6 millimoles/L

- 5mmol/L = 90mg/100ml

Question 22

osmoregulation

Answer 22

• Water makes up large portion of human body
- 75% infants
- 50% females
- 60% males
- 45% old age
• Fluid inside cell: intracellular fluid/cytosol
• Fluid outside cell: extracellular:
- Blood plasma located within blood vessels (intravascular)
- Fluid between cells (interstitial, intercellular, tissue)
- Fluid in specific body regions (transcellular)
› Brain, spinal cord, eyes, joints, surrounding heart
• Different body fluids aren’t isolated from one another. Continuous exchange of materials between them
• If imbalance in osmotic concentration (conc of solutes) does occur, osmosis normally restores balance
- Osmotic pressure: tendency of a solution to take in water
› Greater difference in osmotic conc, the greater the osmotic pressure
› Osmosis tends to occur

Question 23

maintaining fluid balance

Answer 23

-	Fluid gain = fluid loss
›	Keeps composition of body fluid constant
-	Water intake:
›	Food
›	Metabolic water (by-product)
›	Drink
-	Water loss:
›	Lungs
›	Skin
›	Kidneys (urine)
›	Alimentary canal (faeces)

Question 24

excretion

Answer 24

• Removal of waste products of metabolism from the body
  › Toxic, so harmful if it accumulates
• Lungs excrete water (vapour) and carbon dioxide
• Sweat glands: secret water containing by-products of metabolism
• Alimentary canal: passes out bile pigments that entered small intestine with bile
  › Bile pigments are breakdown products of Hgb from RBC
  › Bulk of faeces is undigested food (not excretory producst as it isn’t produced by cells)
• Kidneys: principle excretory organ
  › Maintain constant conc of materials in body fluids
  › Maintain waste in urea

Question 25

kidneys

Answer 25

• Only place where water loss can be regulated for osmoregulation
  › Sweat glands regulated by thermoregulation
• Regulated to achieve a constant conc of dissolved substances in body fluids
• Reddish brown, abdomen, wither side of vertebral column, 11cm lon, due to presence of liver: right is usually lower
• Embedded in and held in position by a mass of fatty tissue
• Ureter leaves each kidney, to bladder, to urethra
• Each kidney has ~1.2 million nephrons
  › Nephrons: functional unit, carry out role in excretion and water regulation
  › 1. Blood enters glomerulus under high pressure
  › 2. Filtration: high BP forces water and small dissolved molecules out of blood and into capsule. Large molecules stay in blood
  › 3. Filtrate collected by glomerular capsule
  › 4. Reabsorption: filtrate passes PCT, LOH, DCT, CD. Water and other useful substances reabsorbed into peritubular capillaries
  › 5. Secretion: some materials that need to be removed from body are secreted into kidney tubule from peritubular capillaries
  › 6. Urine: water and dissolved substances make up urine. Carried by collecting ducts to ureter to bladder

Question 26

controlling water levels

Answer 26

• As water is lost, plasma becomes more concentrated and has higher osmotic pressure.
  › Water moves from interstitial fluid to plasm by osmosis
  › Interstitial fluid more concentrated and water diffuses out of cells
  › cells start to shrink from dehydration
• osmoreceptors in hypothalamus detect increase in osmotic pressure

Question 27

kidneys and ADH

Answer 27

• Dehydrated = urine is less volume and concentrated
• Reabsorption of water occurring at PCT and LOH is osmosis
• Reabsorption at DCT and CD is active reabsorption controlled by ADH
• When ADH conc is high tubules are very permeable to water
  › Water able to leave tubule and re-enter peritubular capillaries
  › Outward flow of water from filtrate reduces volume and increases conc of remaining materials
• When ADH conc is lower: tubules not very permeable
  › Little water reabsorbed into plasma
  › Filtrate remains fairly dilute and volume not reduced

Question 28

kidneys and aldosterone

Answer 28

• Aldosterone helps osmoregulation
• Salt-retaining hormone
• Secreted by adrenal cortex in response to:
  › Low sodium in blood
  › Low blood volume and pressure
  › High potassium in blood
• Acts on DCT and CD to increase sodium reabsorbed and amount of potassium secreted in urine
• Uses active transport using a sodium potassium pump
  › Every 3 sodium, 2 potassium secreted
  › Net movement into blood and subsequent transport of water into blood via osmosis
  › So aldosterone has a role in osmoregulation

Question 29

thirst response

Answer 29

• Osmoreceptors able to stimulate thirst centre in hypothalamus promoting person to drink water
  › Fluid absorbed across wall of alimentary canal into blood decreasing osmotic pressure
  › Excess fluid in interstitial fluid is collected by lymph system

Question 30

water intoxication

Answer 30

• Body fluids become diluted and cells take in extra water by osmosis
• Person loses water and salt through sweating and replaces loss with water
• Light-headedness, headache, vomiting

Question 31

dehydration

Answer 31

• Water loss exceeds intake

- Severe thirst, low BP, dizziness, headache

Question 32

gas regulation

Answer 32

• Cells need a continuous supply of oxygen and removal of carbon dioxide
• Respiratory system takes in oxygen and removes carbon dioxide, respiratory system transports them

Question 33

control of breathing

Answer 33

• Muscles that cause air to move in and out are:
  › Diaphragm: separates thorax from abdomen
  › Intercostal muscles: muscles between ribs
• Skeletal muscles require stimulation from nerve impulses to contract
• Phrenic nerve: stimulates diaphragm
• Intercostal nerve: stimulates intercostal muscle
  › Spinal nerves have their origin in the spinal cord at the level of the neck and thorax
• Nerve impulses controlled by respiratory centre in the medulla oblongata. 2 regions:
  › Controls expiration
  › Controls inspiration
  › To coordinate breathing, messages need to pass between neurons of these regions

Question 34

chemicals effecting breathing

Answer 34

• Conc of CO2, O2 affect breathing rate and depth
• Conc of CO2 in blood plasma affects H+ conc
• These 3 factors affect breathing

Question 35

chemoreceptors

Answer 35

• Peripheral chemoreceptors: groups of cells within walls of aorta and carotid arteries
  › Sensitive to changes of the 3 factors
  › Carotid and aortic bodies
• Central chemoreceptors: medulla oblongata sensitive to changes in CO2 and H+ conc in cerebrospinal fluid
  › When stimulated send impulse to area of respiratory centre that regulates breathing

Question 36

O2 conc

Answer 36

• As O2 is consumed by cells, its levels decrease in the blood
  › If O2 drops below normal while other factors are constant, breathing increases
• Conc has to fall to very low levels before it has a major stimulatory effect
  › Under normal circumstances, O2 plays a little roles regulation of breathing
• Large decrease in O2 stimulates peripheral chemoreceptors and nerve impulses are sent to respiratory centre
  › Stimulates transmission of messages to diaphragm and intercostal muscles so breathing rate and depth increases

Question 37

CO2 conc

Answer 37

• Small increase in CO2 conc is enough to cause an increase in breathing rate and depth
• Increase in CO2 conc increases H+ conc
  › Increase in both stimulates central and peripheral to transmit impulses to respiratory centre to increase breathing rate and depth
• Chemoreceptor more sensitive to change in CO2 conc are the ones in medulla oblongata
  › Responsible for 70-80% of response form high CO2 conc
  › Takes several minutes
• Immediate increase in breathing rate that follows an increase in CO2 produced by stimulation of aortic and carotid bodies

Question 38

H+ conc

Answer 38

• As H+ conc increases, pH decreases
• Decrease in pH stimulates peripheral chemoreceptors to transmit impulses to respiratory centre
  › Increase breathing rate and depth

Question 39

voluntary control of breathing

holding our breath

Answer 39

• Voluntary control of breathing:
- Voluntary control comes via connection from cerebral cortex to descending tracts in spinal cord
› Bypasses respiratory centre
- Protective device: enables us to prevent irritating gases and water from entering lungs
• Holding our breath:
- Cant stop breathing forever
- Build of CO2 in plasma stimulates the inspiratory centre to send impulses to inspiratory muscles
› Forced to breathe

Question 40

hyperventilation

exercise and breathing

Answer 40

• Hyperventilation:
- Rapid deep breathing
› Provides more O2 and removes more CO2 than needed
› Voluntarily or stimulated by stress
› Usually corrects itself. Reduction in CO2 means chemoreceptors aren’t being stimulated, reduces breathing rate and depth until normal
• Exercise and breathing:
- More O2 required and more CO2 produced
- Respiratory centre increases breathing rate and depth
- Influenced by 3 factors (O2 to a lesser extent)