Homeostasis, pH, core body temperature + body fluids

Question 1

define homeostasis

Answer 1

the process whereby cells, tissues and organisms maintain the status quo
(the ability or tendency of a living organism, cell, or tissue to keep the conditions inside it the same despite any changes in the conditions around it, or maintaining a state of internal balance)

Question 2

what needs to be maintained constant in the internal environment

Answer 2

• temperature
• pH
• water (volume and pressure)
• gases: oxygen, CO2
• nutrients, glucose, amino acids, electrolytes
• waste products: ammonia, urea

Question 3

examples of homeostasis

Answer 3

• acid-base balance
• fluid balance
• control of body temperature

Question 4

four components of a homeostatic mechanism

Answer 4

• variable (temperature, cell volume, pH)
• sensor (monitors current value of variable)
• control centre (retains desired value of variable and compares to current value)
• effector (ability to change value of variable)

Question 5

positive feedback

Answer 5

• increases effect of stimulus
• e.g. blood clotting
• stops when initiator ceases

Question 6

negative feedback

Answer 6

• decreases effect of stimulus to return to normal level
• e.g. blood glucose regulation
• stops when effector ceases

Question 7

70 kg man water compartments

Answer 7

• 60% water - 42l
• 2/3 intracellular fluid - 28l
• 1/3 extracellular fluid - 14l
  - 11l interstitial fluid
  - 3l plasma

Question 8

circulating blood volume

Answer 8

5 litres (3l plasma + 2l red cells)

Question 9

what is interstitial fluid

Answer 9

fluid that surrounds cells but is outside the blood vessels

Question 10

how many litres of fluid is needed a day to maintain a helathy adult

Answer 10

2.5l

Question 11

compare total body water in males and females (lean and obese)

Answer 11

• 60% adult males (70% and 50%)
• 50% adult females (60% and 42%)
• 70% infants (80% and 60%)
• 50% elderly

Question 12

tonicity

Answer 12

• isotonic = same amount of water on both sides of plasma membrane
• hypotonic = more water outside cell
• hypertonic = more water inside cell

Question 13

what is osmolality

Answer 13

concentration of particles in solution expressed as mOsm/kg
- measurement of osmotic pressure

Question 14

what is osmolarity

Answer 14

concentration of particles in solution expressed as mOsm/l

Question 15

normal osmolality of body fluids

Answer 15

280-300 mOsm/kg

Question 16

body compartmetns where fluids accumulate

Answer 16

• intracellular
• extracellular (interstitial + blood plasma)

Question 17

what happens if there is not enough water (dehydration)

Answer 17

• plasma osmolality increases
• cells and tissues absorb water from interstitial space and plasma
• absorb water from each other e.g. RBCs lose water and shrink
• as tissues die, water absorbed from organs
• as organs die, water absorbed from brain, liver, kidney and heart

Question 18

what happens if there is too much water (water toxicity)

Answer 18

• osmotic pressure is high (osmolality decreases)
• cells absorb water and swell
• enzyme and proteins stop working
• cells keep swelling until they burst

Question 19

why do patients need isotonic solutions

Answer 19

• to avoid cells shrinking or bursting
• IV drips need physiological saline concentrations (0.9% NaCl)

Question 20

movement of water between compartments and cell membranes determined by

Answer 20

• hydrostatic forces created by pumping of heart
• osmotic pressures created by concentration of solute particles

Question 21

what is oedema

Answer 21

• fluid retention
• makes cells and tissues swell
• dangerous in the brain - can cause coma and death
• peripheral oedema commonly found in limbs

Question 22

process of oedema

Answer 22

• hydrostatic pressure > osmotic pressure so water doesnt move back into capillary and accumulate in interstitial space
  1. raised hydrostatic pressure in the capillary (vasodilation, congestion e.g. heart failure)
  2. decreased oncotic pressure in capillary (liver disease - low albumin)
  3. increased oncotic pressure in interstitial space (leakage of plasma proteins - albumin)
  4. impaired lymphathic drainage (lymphoedema)

Question 23

oncotic pressure (colloid-osmotic pressure)

Answer 23

osmotic pressure from the proteins (albumin) in blood vessels that causes fluid to be pulled back into the capillary

Question 24

2 major organs responsible for maintaining acid-base balance

Answer 24

• lungs - respiratory balance
• kidneys - metabolic balance

Question 25

what is pH

Answer 25

• free hydrogen ion concentration
• pH = -log[H+]

Question 26

important of acid-base balance for normal human physiology

Answer 26

• normal pH is 7.35-7.45 (blood in arteries more alkali than veins)
• normal cellular metabolism occurs within this range
• change in [H+] by factor of 2 causes pH change of 0.3
• acidosis occurs if blood pH < 7.35
• alkalosis occurs if blood pH > 7.45
• if **below 6.8 or above 8.0 **for a significant period of time then death is likely

Question 27

arterial blood gas (ABG)

Answer 27

analysis of pH and gases in an arterial blood sample

Question 28

metabolic acidosis

Answer 28

• increased production of metabolic acids like lactic acid
• inability to excrete acid via kidneys

Question 29

respiratory acidosis

Answer 29

• excessive buildup of carbon dioxide due to hypoventilation
• compensatory response to metabolic alkalosis

Question 30

acid damage

Answer 30

• gastric juice has pH 1-3.5
• goblet cells lining stomach wall secrete substances (mucus) to protect cells against acid
• regurgitation damages epithelial lining oesophagus and pharynx (oesophagitis, stricture)
• stomach losing protection can cause gastric ulceration and perforation

Question 31

pH buffering systems

Answer 31

• carbonic acid-bicarbonate buffer important in blood pH
• sodium phosphate buffering system regulate intracellular pH and transport systems
• calcium can raise pH
• antacids (aluminium hydroxide, magnesium hydroxide, calcium salts) neutralise acidic pH e.g. indigestion
  - aluminum hydroxide preferred as it’s milder, long- acting and insoluble

Question 32

core body temperature

Answer 32

• normal range is 36.5–37.5 °C
• fluctuates throughtout day - circadian rhythm
• enzymes lose activities at high temps
• insufficient energy to maintain metabolic processes at low temps

Question 33

how do we measure temperature

Answer 33

• infra-red skin thermometer
• tympanic thermometer
• temporal film
• oral/rectal/axillary thermometer
• traditional

Question 34

components of negative feedback loop in regulating temperature

Answer 34

stimulus
- low or high temperature

sensor
- skin
- hypothalamus

control centre
- hypothalamus

effector
- muscles
- blood vessels
- hairs on skin
- fat
- sweat glands

Question 35

mechanisms of reducing temperature

Answer 35

• vasodilation - arterioles dilate so more blood enters skin capillaries and heat is lost
• sweating - sudorific glands secrete sweat which removes heat when water changes state
• pilorelaxation - hairs flatten
• stretching out - larger surface area

Question 36

mechanisms of increasing temperature

Answer 36

• vasoconstriction - arterioles get smaller to reduce blood going to skin keeping core warm
• shivering - rapid contraction and relaxing of skeletal muscles, heat produced by respiration
• piloerection - hairs on skin stand up
• curling up - smaller surface area

Question 37

effects of core body temperature being out of normal range

Answer 37

• no vital signs < 28°C - unconciousness, dilated pupils, pulse undetectable, death appearance
• severe hypothermia 28.0- 32.0°C - shivering stops, muscles become rigid, very slow and weak pulse, drowsiness
• mild hypothermia 32.1-35°C - shivering, fatigue, slurred speech, confusion, forgetfulness, muscle stiffness
• normal 36.5-37.5°C - normal core body temperature
• fever >38°C - pale sweaty skin, cramps in stomach, arms and legs
• heat stroke > 40°C - flushed dry skin, hot to the touch, strong bounding pulse
• heat exhaustion >40°C - unconsciousness/fitting/seizures, confused/restless, exhaustion, headache, dizzy, uncomfortable

Question 38

mechanism of high temperature when infected

Answer 38

• toxins from bacteria and chemicals from immune system (interleukin-6) increase set point in hypothalamus to higher temperature
• initiates heat generation through shivering and increased metabolic rate so increased temperature is achieved
• above 38.5°C is fever (pyrexia)
• high temperature important as immune system works optimally