Homeostasis and metabolism

Question 1

What is autocrine communication? What is paracrine communication?

Answer 1

A chemical is released from a cell into the extracellular fluid and then acts upon the very cell that secreted it.
Chemical messengers involved in the communication between cells, released into extracellular fluid travels short distances. e.g. ACh at neuromuscular junction

Question 2

What is endocrine communication? What is exocrine communication?

Answer 2

Hormones produced and secreted, communication between cells travel further long distance, systemic effects.
Secretion into ducts then into organ

Question 3

Organs involved in endocrine communication and hormones produced by each ?

Answer 3

Hypothalamus e.g. dopamine
Pituitary- anterior pituitary hormones= FSH, LH and TSH, posterior pituitary hormones= oxytocin, ADH/ vasopressin
Thyroid, parathyroid, adrenals, pancreas, ovaries and testes.

Question 4

Key differences between endocrine and paracrine communication?

Answer 4

Hormones travel in blood in endocrine- only in extracellular fluid in paracrine messengers. Endocrine= affects more things and travels further than paracrine.

Question 5

E.g.s of positive feedback loop? E.g.s of negative feedback loop?

Answer 5

Clotting cascade and oxytocin release during childbirth.
Blood sugar regulation, temperature regulation, blood pressure regulation, thyroid regulation
If too much thyroxine in blood, stimulates pituitary gland to stop producing TSH

Question 6

Problems with feedback?

Answer 6

Can get primary hypothyroidism- thyroid produces too little thyroxine- TSH levels in blood keep increasing.
Can get primary hyperthyroidism- too much thyroxine, TSH falls but thyroxine rises.

Question 7

What does primary and secondary mean in relation to feedback issues?

Answer 7

Primary= issues with endocrine gland, secondary= issue with pituitary or hypothalamus

Question 8

Three hormone types? Classified according to what?

Answer 8

Peptide, steroid and amino- acid derivative

Structure

Question 9

What is the structure of peptide hormones? How are they made and what do they bind to? Receptor binding induces what? E.g.s?

Answer 9

From short chain amino acids– small proteins, some have carb portions. Are large hydrophilic charged molecules that cannot diffuse across a membrane
To receptors on membranes- are pre-made and stored in cell then released and dissolved in blood
Signal transduction cascade
Insulin, TSH and ADH

Question 10

Steroid hormones made from what? Solubility? Targets what? How made and transported? Response speed? E.g.s?

Answer 10

From cholesterol. Lipid soluble. Requires transport proteins in blood and targets intracellular receptor. Made by cell and diffuses out- binds to receptor inside cell.
Slow response as directly affects DNA e.g. testosterone, oestrogen and cortisol

Question 11

Amino acid hormones made from what? Acts in same way as what other hormone type? Examples?

Answer 11

Tyrosine. Peptide hormone.

Adrenaline, thyroid hormones thyroxine (T4) and triiodothyronine (T3)

Question 12

Predominant electrolyte in intracellular fluid? Predominant in extracellular fluid?

Answer 12

Potassium

Sodium, chloride, bicarbonate and Ca2+ ions- especially in heart and muscle

Question 13

Where is interstitial fluid found? What is plasma?

Answer 13

Surrounding the cells but does not circulate. Circulates as the extracellular component of blood- interstitial= also extracellular component.

Question 14

What is transcellular fluid? % of body weight is made of water? % of extracellular and intracellular fluid?

Answer 14

Makes up the CSF, digestive juices and mucus etc.
42L (60%)
Intra= 40% and extra= 20%

Question 15

What are insensible water loss examples? What is osmolality? What is osmolarity?

Answer 15

Sweat, breath, vomiting and faeces.
Measure of number of dissolved particles per kg of fluid
Measure of number of dissolved per L of fluid

Question 16

What is osmotic pressure? What is oncotic pressure?

Answer 16

Pressure applied to a solution by a pure solvent required to prevent inward osmosis through a semipermeable membrane.
Form of osmotic pressure exerted by protein that tends to pull fluid into its solution- water from interstitial fluid into plasma

Question 17

What is hydrostatic pressure?

Answer 17

Pressure difference between capillary blood plasma and interstitial fluid- water and solutes move from plasma into interstitial fluid.

Question 18

What happens when water is lost from ECF? Change detected by what? What is released?

Answer 18

Increase in solutes/ increase in osmolality
Osmoreceptors in hypothalamus
ADH from posterior pituitary to increase absorption in collecting ducts- more aquaporins in cell membrane

Question 19

What else does ADH do?

Answer 19

Constricts the arterioles in the peripheral circulation which reduces the flow of blood to the extremities and this increases blood supply to core of body.

Question 20

What happens when there is a decrease in water in ECF? Decreased renal blood flow leads to release of what?

Answer 20

Decrease in effective circulating volume– decrease in renal blood flow.
Renin from juxtaglomerular kidney cells in kidneys.

Question 21

Renin converts angiotensinogen into what? Angiotensin I turned into what using what enzyme?

Answer 21

Angiotensin I

Angiotensin II using ACE enzyme- found on luminal surface of capillary of capillary endothelial cells of lungs

Question 22

Angiotensin II stimulates the secretion of what hormone? This is produced where and does what? What does blood pressure do?

Answer 22

Aldosterone and ADH
From adrenal cortex- more aquaporins so more Na+ and H2O reabsorption.
Increases because arterioles constrict.

Question 23

What cells in walls of ascending loop of Henle are stimulated by high osmolarity? They stimulate what? How is sensation of thirst created?

Answer 23

Macula densa cells
Juxtaglomerular apparatus to release renin into bloodstream
Angiotensin II acts on hypothalamus to cause sensation of thirst.

Question 24

3 types of dehydration? Causes?

Answer 24

Hypotonic- electrolyte loss, hypertonic- water loss and isotonic- equal loss of water and electrolytes.
Water deprivation, diarrhoea, vomiting, burns, heavy sweating, diabetes insipidus, diabetes mellitus and drugs

Question 25

Consequences of dehydration? Consequences of water excess?

Answer 25

Thirst, dry mouth, inelastic skin, sunken eyes, raised haematocrit, weight loss, confusion, hypotension
Hyponatraemia, cerebral over-perfusion– headaches, confusion and convulsions

Question 26

What is serous effusion? What is oedema?

Answer 26

Excess water in a body cavity

Excess water in the intercellular tissue space

Question 27

Types of oedema?

Answer 27

Inflammatory- proteins leak out, venous- increased venous pressure/ obstruction due to thrombus, lymphatic- obstructions and hypoalbuminaemic- lower oncotic pressure.

Question 28

Why does pleural effusion happen and consist of?

Answer 28

Disruption of balance between hydrostatic and oncotic forces in visceral and parietal pleural vessels
Different fluids can enter pleural cavity

Question 29

What is transudate? What is exudate?

Answer 29

Fluid pushed through capillary due to high pressure within capillary
Fluid that leaks around the cells of the capillaries caused by inflammation and increased permeability of pleural capillaries to proteins.
Capillaries= within visceral and parietal pleurae.

Question 30

Protein level in exudates compared to transudates?

Answer 30

Exudates= high protein level compared to transudates.

Question 31

Consequences of hypernatraemia?

Answer 31

Cerebral intracellular dehydration- dehydrates brain as H2) leaves ICF to become ECF

Question 32

Consequences of hyponatraemia? Potassium excretion controlled by what hormone?

Answer 32

Intracellular over hydration- hypotension since H2O goes intracellular
Aldosterone as it controls the Na/K pump

Question 33

Consequences of hyperkalaemia?

Answer 33

Risk of MI- messes with resting potential generated in heart for heart contraction

Question 34

Consequences of hypokalaemia?

Answer 34

Weakness and cardiac dysrhythmia- abnormal heart beat

Question 35

Causes of hypercalcaemia? Can lead to?

Answer 35

Primary hyperparathyroidism (too much parathyroid hormone so calcium leached from bones), skeletal metastases, vitamin D toxicity and TB
Metastatic calcification and kidney stones

Question 36

Causes of hypocalcaemia? Can lead to what?

Answer 36

Vitamin D deficiency, magnesium deficiency, renal disease, parathyroidectomy, intestinal malabsorption.
Tetany- spasms of voice box, hands and feet

Question 37

All lipids in cell membranes have what feature? Functions of cell membrane? What hormone type binds to receptors?

Answer 37

They are amphipathic
Selective barrier, barrier to outside environment and compartmentalise cells
Peptide hormones

Question 38

Cell membranes have molecules on them for what? Types of junctions between cells?

Answer 38

Intercellular adhesion and acts as an insulator i.e. myelin sheath
Occluding, anchoring and communicating

Question 39

Features of occluding junctions? What filament type is involved in anchoring junctions?

Answer 39

Helps seal cells together in epithelial sheet to prevent leakage of molecules between them
Actin filaments- adherent junction joins actin bundle in one cell to a similar bundle in another cell= helps keep cells together.

Question 40

What filament type enables cell to cell adhesion through desmosomes? What 2 things resist shearing forces and join intermediate filaments in one cell to those in a neighbour?

Answer 40

Intermediate filaments

Cell surface adhesion proteins and intracellular keratin cytoskeletal filaments

Question 41

What junction type enables cell to matrix adhesion? What do hemidesmosomes do? What do communicating gap junctions allow the passage of?

Answer 41

Focal adherent junctions
They anchor intermediate filaments in a cell to the basal lamina.
Small water-soluble ions and molecules.

Question 42

What is endocytosis? Occurs in what cell types?

Answer 42

Energetic process to engulf molecules into a cell- portion of membrane is invaginated to form a membrane bound vesicle= endosome.
Neutrophils and macrophages

Question 43

What is pinocytosis? Where does receptor mediated endocytosis occur? How does this work?

Answer 43

Bringing in dissolved solutes.
Specific, found in depressed areas (coated pits)- allows cell to get molecules it needs.
Ligands bind to receptor- ligand released into cytosol

Question 44

What is exocytosis?

Answer 44

Vesicle from Golgi apparatus, fuse with plasma cell membrane- waste expulsion/ enzyme/ hormone is secreted.

Question 45

What is facilitated diffusion? What things do receptors do?

Answer 45

Solutes move from region of high concentration to region of low concentration through protein channels without carrier proteins. e.g. glucose.
Open a channel, activate an intracellular enzyme, induce second messenger (peptide hormone binds to receptor) and migrate nucleus to receptor-ligand complex.

Question 46

Example of an enzyme linked receptor? What are ion channel linked receptor involved in?

Answer 46

Tyrosine kinase- transfers a phosphate group from ATP to a protein in a cell thus acting like an on/ off switch
In rapid signalling events found in electrically active cells like neurons i.e. ligand gated ion channels

Question 47

What do G-protein coupled receptors do?

Answer 47

Sense molecules outside the cell and activate inside signal transduction pathways to ultimately illicit a cellular response.

Question 48

Energy giving most energy per gram? What is the basal metabolic rate?

Answer 48

Lipid- 9kcal/g
Amount of energy needed to keep the body alive in the rest state= 1kcal/kg body mass/hr (24kcal/kg/day), an adult requires approx 0.8g/kg ideal body weight protein per day

Question 49

Factors that increase BMR? Factors that decrease BMR?

Answer 49

High BMI, hyperthyroidism, low ambient temperature, fever/ infection, pregnancy and exercise
Age, gender(female have lower,) starvation and hypothyroidism

Question 50

What is the daily energy expenditure(DEE)?

Answer 50

Energy needed to support our BMR and our physical activity and energy required to process food we eat.

Question 51

Mass of excess energy stored as triglycerides? Mass of excess energy stored as glycogen? Stored as protein? Carbs account for what % of ATP production at rest? Lipids account for what %? When are proteins often used for?

Answer 51

15kg
200g in liver and 150g in muscle 
6kg 
30%
70%
Longer periods of starvation