Ion and Water Balance

Question 1

What are the two main body fluids?

Answer 1

Inttracellular and extracellular

Question 2

What is intracellular fluid?

Answer 2

the fluid that exists
within cells

Question 3

What are the three types of extracellular fluid?

Answer 3

1. Blood plasma and lymph
2. Interstitial fluid : in the spaces
   between cells and tissues of the body.
3. Cerebrospinal Fluid

Question 4

What is osmosis?

Answer 4

Osmosis is the diffusion of water across a membrane in response to osmotic
pressure caused by an imbalance of molecules on either side of the membrane.

Question 5

What is osmoregulation?

Answer 5

Osmoregulation is the process of maintaining salt and water balance (osmotic balance) across membranes within the body

Question 6

Why is osmoregulation important?

Answer 6

Without a mechanism to regulate osmotic pressure, or when a disease damages this mechanism, there is a tendency to accumulate toxic waste and water, which can have dire consequences.

Question 7

What is a hypertonic solution? What happens when a cell is in a hypertonic environment?

Answer 7

High salt concentration. Water exits cell to balance it out. Tend to shrink.

Question 8

What is a hypotonic solution? What happens to cells when placed in this environment?

Answer 8

Higher salt concentration within cells, water enters cell to balance. Tend to swell.

Question 9

What is an isotonic solution?

Answer 9

Equal balance inside and outside of cell.

Question 10

What is an electrolyte?

Answer 10

Electrolyte is a solute that dissociates into ions when dissolved
in water.

Question 11

What is a non-electrolyte?

Answer 11

• A non-electrolyte, does not dissociate into ions during water
  dissolution.

Question 12

What are stenohaline organisms? What environments can they live in?

Answer 12

can tolerate only a relatively narrow range of salinity. Restricted to either fresh or saltwater and are incapable of osmoregulation in opposite environment.

Question 13

What are euryhaline organisms?

Answer 13

can tolerate a relatively wide range of salinity are referred to as euryhaline organisms. This is possible because some fish have evolved osmoregulatory mechanisms to survive in all kinds of aquatic environments.

Question 14

Is the diffusion of salt/ions across semi-permeable membranes facilitated or passive?

Answer 14

Active

Question 15

What is facilitated diffusion?

Answer 15

Facilitated diffusion requires protein-based channels for moving the solute.

Question 16

Why are salt/ions moved by facilitated diffusion?

Answer 16

If electrolyte ions could passively diffuse across membranes, it would be impossible to maintain specific concentrations of ions in each fluid compartment,

Question 17

What is active transport? What does it require?

Answer 17

Active transport requires energy in the form of ATP conversion, carrier proteins, or pumps in order to move ions against the concentration gradient

Question 18

Why do people die of dehydration when stranded in the ocean despite being surrounded by water?

Answer 18

Stranded in ocean, drinking salt water:
No matter how much they drink, they will get dehydrated as the body will try to remove as much water as possible to get the high salt concentration out of the body.

Question 19

What is the relationship between freshwater fish and their environment? What does this mean?

Answer 19

Hyperosmotic; inside of the body contains more salt than outside, thus water tends to enter the body more readily.

Question 20

What are the challenges of freshwater fish? What solutions do they have to manage this?

Answer 20

Challenges:
* Gaining too much water
* Losing too much salt
(because the environment is relatively hypotonic)
Solutions:
* Drink less or no water
* Osmoregulate:
* Excrete very dilute urine
* Actively transport salts back through the gills

Question 21

What is the relationship between saltwater fish and their environment? What does this mean?

Answer 21

Hyposmotic; more salt outside the body than inside, water tends to exit the fish.

Question 22

What are the challenges of saltwater fish? What solutions do they have to manage this?

Answer 22

Challenges:
* Losing too much water
* Too much salt in their system
Solutions:
* Drink seawater
* Osmoregulate:
* Excrete very concentrated urine
* Actively remove excess salts through gills

Question 23

What relationship do marine invertebrates have with their environments? How does this work? Provide an example.

Answer 23

• Most marine invertebrates, maybe isotonic with sea water (osmoconformers)
• Their body fluid concentrations conform to changes in seawater concentration
• Body fluid salt concentrations comparable to those of the environment
• Ex. Sharks have rectal glands that help with this

Question 24

Explain rectal glands in sharks. How is this conforming and not regulating?

Answer 24

glands that assist in excreting extra salt if needed (not there for osmoregulation, but to conform to the environment the shark is in)

Question 25

Explain the evolutionary timeline of osmoregulation.

Answer 25

1. Membrane channels and pumps
2. Malphigian tubes
3. Nephron
4. Kidneys

Question 26

What is a nephron?

Answer 26

The smallest functional unit of a kidney.

Question 27

List the components of a nephron.

Answer 27

Renal corpuscle
Proximal convoluted tubule (PCT)
Nephron loop
Distal convoluted tubule (DCT)
Collecting duct
Papillary duct

Question 28

What is contained in the renal carpuscle?

Answer 28

Glomerulus

Question 29

Where does the nephron interact with blood?

Answer 29

Renal carpuscle

Question 30

Does blood enter the nephron?

Answer 30

No, just water, ions and small molecules.

Question 31

What happens in the renal carpuscle?

Answer 31

Filtrate is produced.

Question 32

What happens in the proximal convoluted tubule?

Answer 32

Reabsorption of water, ions and organic nutrients.

Question 33

What are the two parts of the nephron loop?

Answer 33

Descending thin limb, thick ascending limb

Question 34

What happens in the descending thin limb of the nephron loop?

Answer 34

Further reabsorption of water.

Question 35

What happens in the thick ascending limb of the nephron loop?

Answer 35

Reabsorption of Na+ and Cl-

Question 36

What happens in the distal convoluted tubule of the nephron?

Answer 36

Secretion of ions, acids, drugs, toxins
Variable reabsorption of water, sodium ions, calcium ions under hormonal control

Question 37

What happens in the collecting duct of the nephron?

Answer 37

Variable reabsorption of water, reabsorption or secretion of Na+, K+, H+, bicarbonate ions

Question 38

What happens in the papillary duct of the nephron?

Answer 38

Delivery of urine to minor calyx

Question 39

Label this image.

Answer 39

I. PCT
II. Renal carpuscle
III. Nephron loop
IV. DTL
V. TAL
VI. DCT
VII. Collecting duct
VIII. Papillary duct

Question 40

Explain glomerular filtration.

Answer 40

Blood pressure forces water and solutes across the wall of the glomerular capillaries into the
capsular space. Filtration is based on size; small molecules pass through filtration membrane.

Question 41

How are the osmotic solutions of freshwater fish dealt with in the nephron? (i.e., actively reabosrbing salts & reabsorbing less water)

Answer 41

Solutions:
Actively reabsorb salts:
* Through gills
* Through PCT, DCT and Collecting duct
Reabsorbing less water due
to:
* Large glomerulus
* Absence of loop of Henle
* Short Intermediate segment
* Collecting duct less permeable to
water

Question 42

How is salt reabsorbed into the body?

Answer 42

[ion] increases in the renal tubule and water leaves the body to decrease
[ion] in the renal tubule (production of dilute urine)

Question 43

How are osmotic solutions in saltwater fish met in the nephron? (i.e., actively eliminate salts and reabsorb more water)

Answer 43

Actively eliminate salts:
* Through PCT and Collecting duct
Reabsorbing more water due to:
* Small or no glomerulus
* Short PCT and lack of DCT
* Collecting Duct is permeable to water

Question 44

How is water reabsorbed in the body?

Answer 44

[salt] increase in the body and water moves from renal tubule to decrease
[salt] in the body (production of concentrated urine)

Question 45

What are the challenges insects face for osmosis?

Answer 45

Losing too much water, dessication

Question 46

How do insects resolve their osmotic challenges?

Answer 46

• Salts and water from diet and
  drinking
• Actively balance salts and water
  in the Malpighian tubules and in
  the hindgut/midgut
• Reabsorb further water and salts
  in the rectum

Question 47

What osmotic challenges do mammals face?

Answer 47

• Losing too much water
• Dessication

Question 48

What osmotic solutions do mammals possess?

Answer 48

Solutions:
* Salts and water from diet and
drinking
* Actively balance salts and water
in the kidneys
* Countercurrent flow of blood
around the nephron ensures ion
and water balance

Question 49

What osmotic solutions are present in mammals at the nephron level?

Answer 49

• Water reabsorbed in the descending part of the loop of Henle (or nephron loop), DCT and
  Collecting duct

Question 50

Explain the additional example of osmotic solutions on land in the marine iguana.

Answer 50

Spends a lot of time wading in salt water and risks losing too much water and gaining too much salt. The mechanisms of the nephron are not enough to protect against this. Instead, has salt nasal glands that release excess salt.

Question 51

What is the function of the human excretory system? What are some examples?

Answer 51

Remove waste. Ex. sweat through skin, CO2 through lungs, toxins through urine

Question 52

What parts make up the human excretory system?

Answer 52

kidneys, ureter, bladder, urethra

Question 53

What is the function of the renal artery?

Answer 53

supply blood to the kidneys

Question 54

What are ureters?

Answer 54

ureters are urine-bearing tubes that exit the kidney and empty into the urinary bladder.

Question 55

How does the body know when to urinate?

Answer 55

The bladder contains sensory nerves, stretch receptors that signal when it needs to be emptied

Question 56

Where do The arteries, veins, and nerves that supply the kidney enter and exit?

Answer 56

Renal hilum

Question 57

What are the names of the three layers surrounding the kidney?

Answer 57

Renal fascia - tough connective tissue
Perirenal fat capsule - anchors kidneys in place
Renal capsule

Question 58

What are the three inner regions of the kidney?

Answer 58

Outer cortex
Medulla
Renal pelvis

Question 59

What does the kidney do?

Answer 59

Excess water, electrolytes, and wastes are transported to the kidneys and excreted, helping to maintain osmotic balance

Question 60

What is the function of the renal pelvis?

Answer 60

renal pelvis collects the urine and leads to the ureter

Question 61

Where are the nephrons located?

Answer 61

In the renal cortex.

Question 62

What do nephrons do?

Answer 62

nephrons remove wastes, concentrate them, and form urine that is collected in the bladder.

Question 63

What are the three principal functions of the nephrons?

Answer 63

filtration, reabsorption, secretion

Question 64

What are the three main parts of the nephron?

Answer 64

renal corpuscle, a renal tubule, and the associated capillary network,

Question 65

What is the filtrate like once it has made it to the DCT?

Answer 65

By the time the filtrate reaches the DCT, most of the urine and solutes have been reabsorbed. If the body requires additional water, all of it can be reabsorbed at this point

Question 66

Where does tubular reabsorption occur in the nephron?

Answer 66

In the PCT.

Question 67

What are the ascending and descending loops in the loop of Henle each permeable to?

Answer 67

acending loop only permeable to sodium and chloride , descending only permeable to water,

Question 68

Use this image to countercurrent multiplication.

Answer 68

The loop of Henle acts as a countercurrent multiplier that uses energy to create concentration gradients. The descending limb is water permeable. Water flows from the filtrate to the interstitial fluid, so osmolality inside the limb increases as it descends into the renal medulla. At the bottom, the osmolality is higher inside the loop than in the interstitial fluid. Thus, as filtrate enters the ascending limb, Na+ and Cl- ions exit through ion channels present in the cell membrane. Further up, Na+ is actively transported out of the filtrate and Cl- follows.