Homeostasis and the Kidney

Question 1

Define homeostasis

Answer 1

The maintenance of a constant internal environment within a living organism, irrespective of the external conditions

Question 2

Give 3 examples of homeostatic control

Answer 2

• Regulation of blood glucose levels
• Regulation of solute potential
• Regulation of core body temperature and pH

Question 3

Homeostasis uses ____________ _________ to return the body to the set point

Answer 3

Negative feedback

Question 4

Negative feedback uses a __________ which monitors the condition and provides input to the control ________ which evaluates the information and provides output to an _________ which makes a ________ designed to take away the deviation (return to the _____ ________)

Answer 4

Detector
Centre
Effector
Response
Set point

Question 5

Define negative feedback

Answer 5

A receptor detects any deviation from a set point. Information is sent to a control centre which coordinates a response to return levels back to the set point

Question 6

Give 2 examples of when the body uses positive feedback (an effector increases a change)

Answer 6

1. Oxytocin stimulates the contraction of the uterus at the end of pregnancy. The contractions stimulate the production of more oxytocin, which increases the stimulus
2. When the skin is cut, the first stage of clot formation is that platelets adhere to the cut surface. They secrete signalling molecules, which attract more platelets to the site

Question 7

Name 2 functions of the kidney

Answer 7

1. Nitrogenous excretion
2. Osmoregulation

Question 8

What are the 4 steps in nitrogenous excretion?

Answer 8

1. Amine group is removed from an amino acid
2. The removed amine group converted to ammonia
3. With the addition of CO2, urea is formed and transported in the blood plasma to kidneys
4. Urea is removed by the kidneys and excreted in the urine

Question 9

Define osmoregulation

Answer 9

The control of the water content and solute composition of body fluids

Question 10

Humans lose water by:

Answer 10

• Urination and egestion of faeces
• Sweating
• Exhalation

Question 11

What is the function of the ureter?

Answer 11

Convey urine to the bladder

Question 12

What is the function of the urethra?

Answer 12

Carries urine to outside for elimination

Question 13

What is the function of the sphincter?

Answer 13

A muscle that allows conscious control of urine release

Question 14

Define ultrafiltration

Answer 14

Filtration under pressure that separates small soluble molecules from the blood plasma

Question 15

Water and small soluble molecules are separated form the blood plasma to form filtrate in the Bowman’s capsule. To do this they are forced through:

Answer 15

• Pores in the glomerular capillary wall
• The basement membrane (acts as a molecular sieve)
• Filtered between the feet of the podocytes

Question 16

Describe ultrafiltration

Answer 16

• High hydrostatic pressure - efferent arteriole has a narrower lumen than afferent
• Due to this, high pressure fluid containing water and small molecules is forced out of blood in the capillaries through the pores in the capillary walls, and then through pores in the basement membrane
• Basement membrane acts as a molecular sieve, allowing small molecules to pass through but preventing large molecules from passing through
• The small soluble molecules are then filtered through the feet of the podocytes and glomerular filtrate is formed in the Bowman’s capsule

Question 17

Where does selective reabsorption occur?

Answer 17

Proximal convoluted tubule

Question 18

Define selective reabsorption

Answer 18

The process by which useful products such as glucose and salts are reabsorbed back into the blood as the filtrate flows along the nephron

Question 19

The filtrate at the end of the proximal convoluted tubule is ________ to blood plasma

Answer 19

Isotonic

Question 20

By what mechanism are glucose and amino acids selectively reabsorbed?

Answer 20

Secondary active transport using a co-transport mechanism with Na+

Question 21

By what mechanism are most of the mineral ions selectively reabsorbed?

Answer 21

Active transport/co-transport

Question 22

By what mechanism is most of the water selectively reabsorbed?

Answer 22

By osmosis down a water potential gradient

Question 23

By what mechanism are some of the filtered proteins and urea selectively reabsorbed?

Answer 23

Diffusion

Question 24

Name 4 adaptations of the structure of the proximal convoluted tubule in relation to selective reabsorption

Answer 24

• Large surface area (due to length and large number per kidney)
• Cuboidal epithelial cells with microvilli to provide large surface area and nasal channels
• Numerous mitochondria to provide ATP for active transport
• Tight junctions to prevent seepage of reabsorbed materials back into the filtrate, and close association with peritubular capillaries

Question 25

What is the function of the loop of Henle?

Answer 25

The loop of Henle concentrates Na+ in the tissue fluid of the medulla, causing an osmotic flow of water out of the collecting ducts and distal convoluted tubules
This water can then be reabsorbed into the blood stream via the capillaries of the vasa recta. Concentrates the irks and makes it hypertonic to the blood

Question 26

The descending limb is _____________ to water

Answer 26

Permeable

Question 27

The ascending limb is ______________ to water

Answer 27

Impermeable

Question 28

Describe the hair pin counter current multiplier effect

Answer 28

• Na+ and Cl- are actively transported out of the filtrate in the ascending limb into the tissue fluid of the medulla creating a lower water potential
• This means that water leaves the descending limb by osmosis down a water potential gradient and can then move by osmosis into the capillaries of the vasa recta
• The filtrate in the descending limb becomes more concentrated as it reaches the bottom of the loop of Henle due to the loss of water. Na+ and Cl- can also diffuse back into the filtrate near the bottom of the descending limb
• As the filtrate passes up the ascending limb it becomes more dilute due to loss of ions
• An osmotic gradient is maintained down to the bottom of the loop of Henle

Question 29

What happens in the collecting duct due to the loop of Henle creating a high Na+ concentration in the tissue fluid of the medulla?

Answer 29

Water leaves the permeable collecting ducts by osmosis to be reabsorbed into the capillaries

Question 30

What affects the permeability of collecting duct walls?

Answer 30

Antidiuretic hormone (ADH)

Question 31

How does ADH enable more concentrated urine to be formed?

Answer 31

• ADH makes the plasma membranes of the distal convoluted tubule cells and collecting duct cells more permeable to water
• ADH causes aquaporins to become incorporated in the plasma membranes, from within the cytosol
• Water is reabsorbed by osmosis from filtrate into the surrounding hypertonic tissue fluid and then the blood capillaries around the DCTs and collecting ducts
• The urine reaching the bottom of the collecting ducts has a concentration close to the concentration of the tissue fluid near the bottom of the loop which is hypertonic to general body fluids

Question 32

What detects changes in the water potential of the blood?

Answer 32

Osmoreceptors in the hypothalamus

Question 33

What is the coordinator in restoring the normal osmotic concentration?

Answer 33

Cells of the posterior lobe of the pituitary gland secrete more or less ADH

Question 34

What is the effector in restoring the normal osmotic concentration in the blood?

Answer 34

Cells of the distal convoluted tubules and collecting ducts become more or less permeable to water

Question 35

Describe what will happen if a person is dehydrated

Answer 35

• Osmoreceptors in the hypothalamus detect a decrease in the water potential of the blood.
• Nerve impulses are sent to the posterior pituitary gland that releases more ADH.
• ADH travels in the bloodstream to the nephrons where it affects the cells of the collecting duct
• More aquaporins in the plasma membrane of the collecting duct walls, making them more permeable to water
• Water therefore leaves the filtrate in the collecting duct by osmosis into the tissue fluid of the medulla.
• Water is then reabsorbed back into the bloodstream
• This results in a small volume of concentrated urine.

Question 36

Describe what happens if a person is well hydrated

Answer 36

• Osmoreceptors in the thalamus detect an increase in the water potential of the blood
• Nerve impulses are sent to the posterior pituitary gland which release less ADH
• Less aquaporins in the plasma membrane of the collecting duct so collecting duct walls become less permeable to water
• Less water will leave the filtrate back into the bloodstream, producing a large volume of dilute urine

Question 37

What form of nitrogenous waste do aquatic animals excrete and why?

Answer 37

Ammonia which is highly toxic.
It is very soluble in water and can diffuse quickly across the gills of fish into the water where it is diluted to a non-toxic level

Question 38

What form of nitrogenous waste to birds, reptiles and insects excrete and why?

Answer 38

Uric acid which is almost insoluble in water
They use a lot of energy to extreme this waste but very little water is needed so these animals can survive in dry environments

Question 39

What form of nitrogenous waste do mammals excrete and why?

Answer 39

Urea
This requires a lot of water but is less toxic than ammonia so body tissues can tolerate it in higher concentrations for short periods of time

Question 40

How do desert mammals survive with very little water?

Answer 40

Water is produced from the breakdown of food during respiration in the cells (metabolic water). They may live in underground burrows which are cooler to reduce water loss by evaporation.

Question 41

Why would desert animals have a longer than average loop of Henle?

Answer 41

The longer the loop of Henle, the more opportunity to pump ions into the medulla, further increasing the concentration in the medulla. This lower water potential in the medulla enhances water reabsorption from the descending limb and collecting duct, resulting in more concentrated urine

Question 42

Name 5 causes of kidney failure

Answer 42

• raised bood pressure
• impact/crushing injury
• auto-immune disease
• diabetes
• genetic condition

Question 43

Name 5 treatments for kidney failure

Answer 43

• medication to control blood potassium and calcium levels
• transplant
• dialysis
• reduce intake of protein in the diet to reduce urea formation
• use of drugs to reduce blood pressure

Question 44

What is dialysis?

Answer 44

The process of removing excess water, inorganic ions and urea from the blood in people whose kidneys can no longer perform these functions naturally

Question 45

Describe how dialysis works/adaptations

Answer 45

• The dialysate runs in counter-current flow next to the blood to be cleaned, this maintains a concentration gradient
• Blood and dialysate are separated by a selectively permeable membrane to prevent loss of plasma proteins
• Replacement with fresh dialysate further maintains a concentration gradient

Question 46

Why should the temperature of the dialysate be maintained at 37 degrees?

Answer 46

37 C is the internal body temperature. If blood cools down in dialysis machine then temperature shock may occur. Also increases the diffusion rate.

Question 47

What happens when someone gets a kidney transplant?

Answer 47

Functions of the failing kidneys are taken over by a single healthy kidney from a donor. It should function normally, cleaning and balancing the blood. However it may only last 9 years.
It may be rejected as antigens on the donor organ differ from antigens on the cells of the recipient. Immunosuppressants must be taken for the rest of their lives.