Excretion 5.2 Flashcards

Question 1

Q

Define excretion

Answer

A

Excretion is the removal of metabolic waste from the body

Question 2

Q

What are the main 3 excretory products from the body?

Answer

A

The main excretory products are:

carbon dioxide fro respiration
nitrogenous waste like urea
other compounds like bile pigments

Question 3

Q

What are the 4 excretory organs?

Answer

A

Excretory organs:

lungs
liver
kidneys
skin

Question 4

Q

How are the lungs an excretory organ?

Answer

A

In the lungs carbon dioxide diffuses into the alveoli to be excreted as you breathe pout.

Question 5

Q

What is the path of carbon dioxide to reach the lungs?

Answer

A

Carbon dioxide passed from respiring cells into the bloodstream then transported as hydorgen carbonate ions to the lungs

Question 6

Q

how is the liver an excretory organ?

Answer

A

The liver has many metabolic processes and some of these substances produced will be passed into the bile for excretion with faeces.
It is also involved in converting amino acids to urea by deamination

Question 7

Q

How is urea made from deamination?

Answer

A

The nitrogen containing part of the amino acid is combined with carbon dioxide to make urea

Question 8

Q

How are the kidneys an excretory organ?

Answer

A

In the kidneys urea is removed from the blood to become past of urine.

Question 9

Q

How is urea transported?

Answer

A

Urea is transported in solution dissolved in the plasma

Question 10

Q

How is the skin an excretory organ?

Answer

A

The skin sweats and sweat contains urea, uric acid and ammonia which are all excretory products.

Question 11

Q

What things may sweat contain other than excretory products? Why?

Answer

A

Other than the excretory products of uric acid urea and ammonia the sweat also contains water ans salts, important in homeostasis maintaining temperature and water potential of the body

Question 12

Q

Why is excretion important?

Answer

A

Allowing the build up of metabolic products may be fatal as carbon dioxide and ammonia are toxic

Question 13

Q

Why is the build up of metabolic products an issue? What can they cause?

Answer

A

Metabolic products can interfere with cell processes by altering pH preventing normal metabolism or may act as inhibitors reducing the activity of essential enzymes

Question 14

Q

What happens to excess amino acids and why

Answer

A

The body cannot store excess amino acids but they contain almost as much energy as carbohydrates so it would be wasteful to simply excrete them. They get deaminated in the liver

Question 15

Q

Discuss deamination

Answer

A

Deamination is the process of removing he potentially toxic amino group fom the amino acid. It forms a soluble toxic ammonia and a keto acid
amino acid + oxygen —- keto acid + ammonia

Question 16

Q

How and why is urea formed after deamination?

Answer

A

Ammomnia is toxic so must be tuned into urea as urea is less soluble and less toxic and the urea can be excreted in the urine from the kidneys
ammonia + carbon dioxide — urea + water

Question 17

Q

Give the symbols for ammonia and urea

Answer

A

Ammonia = NH3 
Urea = (NH2)2CO

Question 18

Q

What happens to the keto acid produced in deamination?

Answer

A

The remaining keto acid can be used directly in respiration to release its energy or converted to carbohydrate or fat for storage

Question 19

Q

What is egestion?

Answer

A

Egestion is the elimination of faeces from the body and faeces is not metabolic products but remains of food

Question 20

Q

How is most of the CO2 in the body transported?

Answer

A

Most of CO2 in the body is transported as hydrocarbonate ions

Question 21

Q

What are the 2 processes to produce hydrogencarbonate ions?

Answer

A

CO2 + H2O — H2CO3 (carbonic acid)

H2CO3 — H+ + HCO3-

Question 22

Q

What is the chemical symbols for hydorgencarbonate ions and carbonic acid?

Answer

A

Hydrogencarbonate ions = HCO3-

Carbonic acid = H2CO3

Question 23

Q

How do you describe how carbonic acid becomes H+?

Answer

A

Carbonic acud disaociates into H+

Question 24

Q

Where does carbonic acid dissociate and what enzyme helps?

Answer

A

Carbonic acid dissociates in the red blood cells under the influence of carbonic anhydrase OR in the blood plasma

Question 25

Q

Describe what happens when hydrogen ions affect red blood cells?

Answer

A

Hydrogen ions affect the pH of cytoplasm is red blood cells:

H+ interact with bonds in haemoglobin changing its 3D shape
reduces haemoglobin’s affinity for oxygen
hydrogen ions combine with haemoglobin to make haemoglobinic acid

Question 26

Q

What can the carbon dioxide that does not form hydorgencarbonate ions do?

Answer

A

The carbon ndioxide that does not form hydogen carbonate ions combines directly with haemoglobinic acid to make carbaminohaemoglobin

Question 27

Q

What is another negative consequence of haemoglobinic acid and carbaminohaemoglobin?

Answer

A

Both haemoglobinic acid and carbaminohaemoglobin are unable to combine with oxygen as normal, reducing the oxygen transport further

Question 28

Q

What happens if the hydrogen ions are in the blood plasma?

Answer

A

Hydorgen ions an reduce blood plasma pH ands mainti g this pH is essential becuase changes could alter the structure of proteins in the blood that help transport a wide range of substances around the body.

Question 29

Q

How is hydrogen ions in the blood plasma combated?

Answer

A

There are proteins in the blood plasma to act as buffers to resist the changes in pH

Question 30

Q

If the change in pH is small what happens?

Answer

A

Id the pH change is amll then the hydrogen ions are detected in the respiraoty centre in the medukla oblongata. Breathing rate is inceased to remove carbon dioxide

Question 31

Q

What if the change in pH is large?

Answer

A

If blood pH drops below 7.35:

headaches, drowsiness, relestness, tremort and confusion,.
Heart rate increases and blood pressure changes (respiraptry acidosis)

Question 32

Q

What is respiratory acidoosis and what may cause it?

Answer

A

Respiratory acidosis is wher blodo pH drops below 7.35 and aucases rapid heart rate and blood pressure changes.
it is caused dby dieases or coindition affecrting the lungs or blockage of the airways

Question 33

Q

What are loiver cells called?

Answer

A

The liver cells are caled hepatocytes

Question 34

Q

What are the 2 sources of blood to the liver? vessels?

Answer

A

Hepatic artery brings oxygenated blood from the heart to the liver in order for ti to be able to aerobically respire
hepatic portal vein brings deoxygenated dirty blood from the digestive system. This blood is rich in the products of digestion and possibly toxic substances absorbed fro the intestine

Question 35

Q

What are the 4 vessels connected to the liver?

Answer

A

Vessels to the liver:

Hepatic artery (heart)
Hepatic portal vein (digestive system)
Hepatic vein (to vena cava
Bile duct

Question 36

Q

Discuss the bile duct

Answer

A

The bile duct carries bile from the liver to the gall bladder. Lots of bile canaliculi join together to form the bile duct.

Question 37

Q

What is bile and what does it do?

Answer

A

Bile is released from the gall bladder into the small intestine to aid digestion of fats.
Bile is a secretion from the liver, a prodcut of heamoglobin nbreakdown by kupffer cells, contains some excretory products like bilirubin (a bile pigments) which leaves the body with faeces

Question 38

Q

What is bilirubin and how does it leave the body?

Answer

A

Bilirubin is a bile pigment found in bile that gets egested with faeces

Question 39

Q

What are interlobular vessels?

Answer

A

Interlobular veseels run parallel and in between lobules. They are where the hepatic artery and hepatic portal vein split into smaller vessels.

Question 40

Q

What are intralobular vessels?

Answer

A

Intralobular vessels are branches of the hepatic vein at the centre of each lobule. The sinusoids empty into this vessel.

Question 41

Q

What are two structural things about hepatocytes?

Answer

A

Hepatocytes have a simple cuboidal shape and have microvilli on their surface

Question 42

Q

What is the cytoplasm of hepatocytes like and why

Answer

A

Hepatocytes have a dense cytoplasm and specialised in the number of organelles that it contains . This is because they have many metabolic functions

Question 43

Q

How is the liver divided?

Answer

A

The liver is divided into lobes which are further divided into lobules

Question 44

Q

Briefly discuss the journey of blood through sections of the liver

Answer

A

Interlobular vessels
blood from heaptic artery and portal vein mix
mixed blood passes along sinusoids
substances removed from blood by liver cells in sinusoids
kupffer cells break down and recycle old blood cells
blood reaches end of sinusoid
blood empties into the intralobular vessel
gets into hepatic vein then back to vena cava

Question 45

Q

What do Kupffer cells do?

Answer

A

Kupffer cells are specialised macrophages what move within the sinusoids. They breakdown and recycle old red blood cells

Question 46

Q

What do Kupffer cells produce as a product?

Answer

A

Kupffer cells breakdown of haemoglobin produces bilirubin, a bile pigment

Question 47

Q

What is a sinusoid?

Answer

A

A sinusoid is a special chamber lined with liver cells that the mixed hepatic artery blood and hepatic portal vein blood passes through.

Question 48

Q

What do the liver cells in the sinusoids do?

Answer

A

The liver cells remove substance from the blood and return different substances back to the blood.

Question 49

Q

When we say ‘mixed blood’ what does this mean?

Answer

A

Blood from hepatic artery and hepatic portal vein mixing together in the sinusoids

Question 50

Q

What shape are the lobules?

Answer

A

Lobules are cyclindrical

Question 51

Q

What are bile canaliculi?

Answer

A

Bile canaliculi are small vessels which join together to form the bile duct

Question 52

Q

List 6 functions of the liver

Answer

A

The functions of the liver:

control of blood glucose levels, amino acid levels and lipid levels
Synthesis of bile, plasma proteins, cholesterol and red blood cells in the fetus
strorage of vitamins A, D, B12, iron and glycogen
detoxification of alcohol and drugs
breakdown of hormones
destruction of red blood cells

Question 53

Q

Discuss the libvers storage of glycogen

Answer

A

The liver stores sugar in the form of glycogen. Approx 100-120 grams of glycogen making up 8% of liver weight
It forms granules in the cytoplasm of hepatocytes
The glycogen can be broken down to release glucose into blood as required

Question 54

Q

What are the 4 ways a toxin can be rendered harmless?

Answer

A

To render a toxin harmless you can ;

oxidation
reduction
methylation
combination with another molecule

Question 55

Q

What are two enzymes the liver contains for detoxification?

Answer

A

catalase

- cytochrome p450

Question 56

Q

What does catalse do?

Answer

A

Catalase converts hydrogen peroxide to oxygen and water. It has a very high turnover rate (number of hydrogen peroxide molecules it can render harmless in one second)

Question 57

Q

What does cytochrome p450 do?

Answer

A

Cytochrome p450 is a group of enzymes used to breaksdown drugs like cocaine and medicinal drugs

Question 58

Q

Where else is cytochrome p450 used and whats the problems?

Answer

A

Cytochromes are also used in metabolic reaction like electron transport and their metabolising drugs can affect their metabolic roles leading to the unwanted side effects of drugs

Question 59

Q

Discuss how alcohol is detoxified

Answer

A

Alcohol detoxification

ethanol broken down into ethanal by athanol dehydrogenase
NAD becomes reduced NAD from the 2 H released from ethanol
Ethanal becomes ethanoate by ethanal dehydorgenase
NAD becomes reducded NAD from the 2 H released from ethanal
Ethanoate becomes acetyl coenzyme A which goes to respiration

Question 60

Q

Why do we detoxifyu alcohol?

Answer

A

We detoxify alcohol as it contains chemical potenatil energy whicbh can be usd in respiration

Question 61

Q

Whats the problem with using NAD to detoxify alcohol?

Answer

A

NAD is also used to oxidise and breakdown faty acids
If liver detoxifies too much alcohol it uses up all the NAD leaving insufficient amounts for fatty acids
Fatty acids converted back to lipids and stored as fats in hepatocytes
liver becomes enlarged (fatty liver)
alcohol related hepatitis or cirrhosis

Question 62

Q

Which bit of amino acids make them toxic to store?

Answer

A

The amine group of amino acids makes them toxic to store

Question 63

Q

What are the two processes that make an amino acid into urea?

Answer

A

Amino acid— keto acid + ammonia = deamination

Ammonia + keto acid—- urea = ornithine cycle

Question 64

Q

What is the structure of amino acids?

Answer

A

Structure of amino acids
R
NH2 —C—-COOH
H

Answer 65

A

keto acid structure
R
C—COOH
=O

Answer 66

A

The ornithine cycle

Ammonia combines with carbon dioxide and ornithine to form citrulline and water is released
Citrulline converted to arginine by addition of ammonia, the ammonia becomes water
Arginine reconverted to ornithine by removal of urea and addition of water

Answer 67

A

Ornthine cycle

ammonia + carbon dioxide — urea + water

Answer 68

A

urea = CO(NH2)2

Answer 69

A

The structure of the kidney

capsule
cortex
medulla
pelvis
branch of renal vein and renal artery
ureter
nephron tubule in cortex and into medulla

Answer 70

A

The nephrons are tiny tubules
each nephron starts in the bowmans capsule in the cortex
remainder of nephron is coiled and passes down the cortex forms a loop in the medulla
back into the crotex
join s a collecting duct that goes into medualla

Answer 71

A

The glomeruslus is a knot of capillaries from where the renal artery has split into many different arterioles

Answer 72

A

The bowmans capsule is what surrounds the glomerulus

Answer 73

A

afferent arteriole, which is wider than efferent, enters gomerulus and splits off intoi a knot
blood leaves via the efferent arteriole which is narrower than the afferent

Answer 74

A

ultrafiltration pushes fluid from the blood into the bowmans capsule from the gomerulus

Answer 75

A

The filter is the barrier between the blood in the capillary and the lumen of the bowmans capsule

Answer 76

A

The barrier has 3 layers:

endotheloium of the capillary
basement membrane
podocytes

Answer 77

A

There are narrow gaps between the cells of the endothelium of the capillary wall.
The cells also contain fenestrations (pores)
These gaps allow blood plasma and substances dissolved to pass out of the capillary

Answer 78

A

The basement membrane consists of a mesh of cllagen fibres and gylcoproteins. This mesh acts as a filter to prevent the passage of molecules with a relative molecular mass greater than 69000. SO most proteins are held in the capillaries

Answer 79

A

Podocytes are epithelial cells of the bowman’s capsule
they have finger like projections called major processes
There are minor processes on major processes whihc hold the cells away from the endothelium of the capillary.
These ensure there are gaps between cells

Answer 80

A

Bowmans capsule and glomerulus
proximal convuluted tubule
loop of henle
distal convoluted tubule
collecting duct

Answer 81

A

Selective reabsorbtion occurs in the proximal convulted tubule

Answer 82

A

In the loop of henle reabosrbtion of water occurs

Answer 83

A

Reabosrbtion of water happens in the collecting duct and it will also get its permeabiloty altered in osmosregulation

Answer 84

A

Ultra filreation occurs in he glomeruslus and bowmans capsule

Answer 85

A

Seelctive reabosrbion poccurs in the proximal convoluted tubule

Answer 86

A

Reabsorbtion of water occurs in the loop and henle and collecting duct

Answer 87

A

Ultra filtration occurs in the bowmans capsule/ glomerulus

Answer 88

A

In the distal comnvoluted tubule active transport is used to adjust the concentraions of various mineral ions

Answer 89

A

Ukltrafiltration is th filtering odf blood at a molecular level.

Answer 90

A

Blood flows into the glomerulus through the afferent arteriole which is widest. The difference i dimatere ensures the blood in the capillaries of the glomerulus maintains a pressure hgoher than the pressure in the bowman’s capsule.
This presure differecne pushes fluid from the blood into the bowmans capsule

Answer 91

A

Th blood plasma is pushed into the bowmans capsule:

water
amino aicds
glucose
urea
inorganic mineral ions

Answer 92

A

Blood cells and proteins are left in the capillaries they are too big to be pushed out

Answer 93

A

urine has a higher concentration of solutes than found in the blood and tissue fluid

Answer 94

A

Proximal convoluted tubule lining cells:
- Microvilli increase surface area
• Membrane contains co-transporter proteins that transport glucose and amino acids with sodium ions in facilitated diffusion
-Opposite membrane of the cells close to capillaries is folded to increase surface area and has sodium potassium pumps
• Many mitochondria

Answer 95

A

Selective reabsorption:
• Sodium-Potassium pumps move sodium ions from the cells lining the PCT into the tissue fluid in capillary
• This reduced the concentration of sodium ions in the cytoplasm
• Sodium ions are transported into the cell, along with glucose or amino acids, by facilitated diffusion with a co transporter protein
• As the glucose and amino acid concentrations rise indies the cell, these substances diffuse out of the opposite side of the cell into the tissue fluid
• Tissue fluids substances diffuse into the blood and are carried away
• Reabsorption of salts, glucose and amino acids reduced the water potential in cells and increases it in the tubule fluid
• Water will enter cells of PCT and then into the blood too

Answer 96

A

If larger molecules like proteins have entered the tubule they can be reabsorbed by endocytosis

Answer 97

A

The loop of henle has a descending limb which is heading towards the medulla and an ascending limb which is heading towards the cortex

Answer 98

A

The arrangement of the loop of henle is known as a hairpin counter current multiplier system

Answer 99

A

The water potential in the tissue fluid of the medulla at the bottom of the loop of henle is the lowest

Answer 100

A

Reaborbtion of water from the loop of henle:

sodium and chloride ions are actively transported out of the top of the ascending limb into the tissue fluid
Water moves out of the descending limb by osmosis due to lower water potential of tissue fluid
This makes the fluid in the descending limb to become very concentrated so eventually at the start of the ascending limb sodium and chloride ions diffuse out into the medulla tissue fluid
lowers water potential in the medulla and solute concentration increases

Answer 101

A

The ascending limb is impermeable to water so water cannot leave it

Answer 102

A

The gradient of solute concentrations in the medulla allows for water to be continuously drawn out of the collecting duct despite the urine in the collecting duct getting more concentrated itself.
This is important as it means how much water is reabsorbed is solely dependent on permeability of collecting duct walls , not the ducts ability to lose water in the first place

Answer 103

A

It is to reduce the water potential of the medulla and create a solute gradient

Answer 104

A

As tubule fluid passes down the collecting duct water moves by osmosis out of the tubule fluid into the surrounding tissue fluid in the medulla. This water then enters the capillaries and is carried away

Answer 105

A

The amount of water reabsorbed depends on the permeability of the collecting duct walls

Answer 106

A

Osmoregulation is the control of the water potential in the body

Answer 107

A

increase in water potential of the blood
detected by osmoreceptors in the hypothalamus
less ADH released from posterior pitutitary
collecting duct walls become less permeable
less water is reabsorbed into the blood
more urine producded
decrease in water potential of the blood

Answer 108

A

decrease in water potential of the blood
osmoreceptors in the hypothalamus detetc it and shrink stimulating neurosecretory cells
more ADH is released from posterior pituitary
collecting duct walls become more permeable
more water is reabsorbed into the blood
less urine is produced
increase in water potential of the blood

Answer 109

A

Osmoreceptors are sensory receptors that detect water potential in the blood

Answer 110

A

When the water potential of the blood is very low the osmoreceptors shrinks and stimulate neurosecretory cells

Answer 111

A

Neurosecretory cells are neurones that produce and release ADH.

Answer 112

A

ADH is manufactured in the neurosecretory cell’s cell body in the hypothalamus.
ADH moves down the axon to the terminal bulb which lies in the posterior pituitary gland and stored in vesicles
When they are stimulated action potentials get carried down their axons and cause re;lease of ADH by exocytosis

Answer 113

A

Once ADH is released it enters the blood capillaries that run through the posterior pituitary and travels round the body acting on the cells of the collecting duct

Answer 114

A

On a cool day you need to conserve less water so the walls of the collecting duct become less permeable so a greater volume of urine is produced and less water reabsorbed

Answer 115

A

On a hot day the collecting duct walls are made more permeable so more water can be reabsorbed and a smaller volume of urine produced

Answer 116

A

Sources of water for the body:

food
drink
respiration

Answer 117

A

ADH is antidiuretic hormone which controls the permeability of the collecting duct walls

Answer 118

A

ADH binds to recptors on cell surface of collecting duct
sereies of enzyme controlled reactions
Aqua porins in vesicles fuse to the membrane of collecting duct
more water reabsorbed into the blood as the walls are more permeable to water
less urine

Answer 119

A

cell surface membrane invaginates to crate vesicles that remove the aquaporins
walls less permeable
less water reabsorbed
more dilute urine

Answer 120

A

Causes of kidney failure;

diabetes
heart disease
hypertension
infection

Answer 121

A

Assessing kidney function;

analyse urine (if we find proteins in the urine it indicates the filtration mechanism is damaged as proteins should be too big to get into fluid)
Estimate glomerular filtrate rate by seeing how much fluid passes into the nephron per minute

Answer 122

A

Normal = 90-120 cm3 min-1

Answer 123

A

chronic kidney disease = below 60 cm3min-1

Answer 124

A

kidney failure = below 15 cm3 min -1

Answer 125

A

Glomerular filtrate rate is the rate at which fluid enters the nephrons

Answer 126

A

When kidneys fail they can no longer regulate the levels of water and electrolytes in the body or remove waste products like urea from the blood which can lead to death

Answer 127

A

kidney failure treatments:

renal dialysis ( haemodialysis and peritoneal dialysis)
kidney transplant

Answer 128

A

Kidney transplants are where patients are given immunosuppeants to undergo major surgery to implant a new kidney

Answer 129

A

Kidney transplant:

freedom from renal dialysis which is time consuming
feel physically fitter
able to travel
improved self image

Answer 130

A

Kidney transplant;

immunosuppressants leave the patient vulnerable
major surgery and anesthetic
need for regular checks
risk of rejection
side effects of drugs like high blood pressure

Answer 131

A

This is where waste products, excess fluid and mineral ions are removed from the blood by passing it over a partially permeable dialysis membrane that allows exchange of substances between blood and dialysis fluid.

Answer 132

A

The dialysis fluid has the correct concentrations of mineral ions, urea and water that should be in the blood plasma

Answer 133

A

When they meet any excess substances in the blood diffuse into the dialysis fluid and any substances the blood has in n low concentrations diffuse into the blood from the dialysis fluid

Answer 134

A

Types of renal dialysis:

haemodialysis
peritoneal dialysis

Answer 135

A

Haemodialyis

performed in clinic 2-3 times pr week for hours
blood from artery passed into machine with dialysis membrane and fluid shaped like lots of capillaries
heparin added to avoid clotting
counter current blood- dialysis fluid to improve efficiency of exchange
any bubbles removed
back in through a vein

Answer 136

A

Peritoneal dialysis

carried out at home or work
they put a dialysis membrane in the abdominal membrane
permanent tube in abdomen
dialysis solution poured through the tube and fills the abdominal cavity (between organs and membrane)
solution rained after a few hours

Answer 137

A

Substances tested for in urine:

glucose
alcohol
recreational drugs
HCG in pregnancy testing
anabolic steroids

Answer 138

A

Urine analysis
Any metabolic product or other substances small enough can be passed down into urine. If they are not reabsorbed they can be detected in the urine if they have a relative molecular mass of less than 69000

Answer 139

A

Pregnancy tests

urine on test stick
HCG binds to mobile monoclonal antibodies attached to a blue bead
mobile antibodies move down the stick
if HCG is present it binds to fixed antibodies, holding the blue beads in place, forming a blue line
control blue line is also present

Answer 140

A

Monoclonal antibodies are specific to one complimentary molecule

Answer 141

A

HCG is human chorionic gonadotrophin.
It is a small glycoprotein that is found after an emrbyo is implanted into the uterine lining after as little as 6 days after conception

Answer 142

A

Anabolic steroid testing
These steroids increase protein synthesis in cells resulting in the build up of cell tissue especially in muscles.
They have a half life of 16 hours and remain in the blood for days
They are small and enter the nephron easily
Testing uses urine sample analysis using gs chromatography

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Excretion 5.2 Flashcards

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