Sodium, Potassium, Chloride

Question 1

What are the bodies fluid compartments?

Answer 1

intracellular fluid (ICF) and extracellular fluid (ECF)
* ICF: 65% in cells
* intravascular fluid part of ECF: 5-8% in blood vessels
* interstitial fluid part of ECF: 25% between cells
* transcellular fluid part of ECF: 1-2% in epithilial lined spaces

Question 2

What is the primary function of Na+, K+, Cl-?

Answer 2

maintain electrochemical charge or gradients (electrolytic & osmotic control) and exist primarly as free ions and only bind weakly to other molecules

Question 3

relative concentrations of Na+, K+ and Cl- inside vs. outside the cell?

Answer 3

• Na+ Outside Cell = 135-148 mmol/L
• Na+ Inside Cell = 12 mmol/L
• Cl- Outside Cell = 98-108 mmol/L
• Cl- Inside Cell = 2 mmol/L
• K+ Outside Cell = 3.8-5.5 mmol/L
• K+ Inside Cell = 150 mmol/L

Question 4

Why is the charge of a cell so negative?

Answer 4

due to the presence of ANIONIC molecules (nucleic acids, proteins)
* must maintain osmotic balance by pumping IN cations (K+)

Question 5

How is lectrolyte distribution and balance in the body controlled?

Answer 5

• movement of ions
• selective permeability of membrane

Question 6

What is the most ubiquitous pump for electrolyte balance?

Answer 6

Na+-K+-ATPase pump which is responsible for 20-40% of BMR
* 3Na+ out, 2K+ in
* Pump creates electrochemical gradient across cell membranes

Question 7

Describe the electrical and chemical gradients of the Na+/K+ ATPase

Answer 7

• Electrical: Outflow of more Na+ than inflow of K+ so cytoplasm stays more negatively charged and is used to create AP
• chemical: ↑ extracellular [Na+] vs cytoplasm lets Na+ flow down the gradient into the cytoplasm via transmembrane proteins (ie. SGLT-1, SMVT) which drives many transport processes

Question 8

What is the Na/K ATPase important for?

Answer 8

• maintains ionic homeostasis
• regulates cell volume
• forms basis for water soluble absorption

Question 9

Describe the Na/K pump

Answer 9

transmembrane protein and functional units is heterodimer with two 𝝰- and β- subunits, but different isoforms exist so relative proportion of each varies among tissues.
* molecular basis is Mg2+ dependant
* Characterized by the transient phosphorylation of ATPase protein during the transport cycle

Question 10

Descrive the process of how Na/K ATPase works

Answer 10

1. transporter picks up 3Na+ inside cell
2. ATP binds phosphorylating 𝝰-subunit and changing conformation to release Na+ outside of cell
3. transporter picks up 2 K+ outside of cell
4. phosphate group on 𝝰-subunit is hydrolyzed triggering release of K+ inside cell
5. Cycle repeats

Question 11

What does active absorption of Na+ act as a co-transporter?

Answer 11

primary mechanism for passively absorbing Cl-, amino acids, glucose, water through co-transport
* allow for active transport of molecules against the concentration gradient, they build up in the cell & then asymmetric channels on the basolateral side enable passive diffusion & ABSORPTION into circulation

Question 12

Describe the benefit of the asymmetric distribution of channels and pumps on elongated cells?

Answer 12

Asymmetric distribution of channels/PUMPS (basolateral vs luminal membrane) causes Na+ to be pumped OUT of the cell & K+ IN, Na+ actively pumped OUT into interstitial space (into plasma), generates gradient from luminal side intracellularly

Question 13

Intestine absorption of Na+, Cl-, K+ and water

Answer 13

• Na+: 95-100% absorbed from luminal side via diffusion by ion channels or facilitated diffusion which is assisted by the Na/K pump on basolateral.
• Cl-: co-transported with Na+ or enters via paracellular space
• K+: 85-90% absorbed via passive diffusion in colon or H/K pump
• water: absorption is passive along osmotic gradient by nutrient absorption

Question 14

How might Na+ facilitate transport of AAs into the cell?

Answer 14

The Na+ binding to the AA transporter increases its affinity for the AA (Na+ going down its gradient) which then binds and the complex causes a conformation change that brings both molecules in and the Na+ is pumped back out by Na/K ATPase

Question 15

What are the main sources of K+?

Answer 15

> 90% ICF and ~2% ECF, K+ can usually look after itself
* intestinal absorption from dietary K+
* Loss from muscle with activity
* renal reabsorption

Question 16

What influences transcellular distribution of K+?

Answer 16

• insulin
• pH
• catecholamines
• osmolarity
• K+ concentration

Question 17

When does muscle take up excess K+ from ECF?

Answer 17

• after a meal driven by insulin
• during exercise driven by catacholamines

Question 18

What is the resting membrane potential of the cell and how is it maintained?

Answer 18

the resting potential is generally -70Mv but may very on tissue with the different Na/K pump isoforms
1. High K+ in cell so chemical forces act on it to leave
2. K+ more permeable to get OUT than Na+ to get IN so overall -ve charge occurs
3. -ve charge inside slows K+ leaving and greater force for Na+ to get IN
4. steady state with -ve charge occurs for passive movement assisted by Na/K-ATPase

Question 19

What are the steps of an action potential?

Answer 19

1. stimulus occurs
2. depolarization: incoming propagating current (-50mV) opens all voltage gated Na+ channels from outside so Na+ rushes IN against concentration gradient (-ve inside) & PD drops
3. repolarization: Only milli secs later voltage gated K+ channel on inside open to let K+ out (slower) (against now +ve PD), meanwhile Na+ ions cease influx & outside channels close again.
4. re-establish steady state: K+ voltage gated channels close again after delay
   (over shoot), Na,K-PUMP takes over.

Question 20

What maintains the membrane potential?

Answer 20

Na/K-ATPase pump
* critical for nerve impulse transmission, muscle contraction & cardiac function

Question 21

What major biological functions require the AP process?

Answer 21

Muscle, nerve & endocrine cells have “excitable” membranes
* Tension, transmission, secretory functions result from the ability to generate & propagate action potentials; dependent on [K+] gradients

Question 22

Why do excitable membranes depend on [K+] gradients?

Answer 22

Modulations in [K+] can cause electro-physical disturbances & cells cannot maintain normal resting membrane potential
* hyperkalemia
* hypokalemia

Question 23

Describe hyperkalemia

Answer 23

membrane depolarizes (5mmol/L) and cannot repolarize
* Resting membrane potential is closer to the action potential threshold so cells become more excitable
* extracellular K+ higher than normal and K+ does not leak out as fast as it normally would by diffusion (diffusion out slows) & more K+ is retained inside the cell than normal so resting membrane potential is shifted up (closer to threshold) & cell will reach action potentials with smaller graded potentials (over-responsive to smaller signals)

Question 24

Describe hypokalemia

Answer 24

membrane hyperpolarizes
* Resting membrane potential is farther from the action potential threshold so cells get less excitable
* As extracellular K+ decreases, the concentration gradient increases so greater diffusion pressure & so more K+ diffuses out than normal and intracellular becomes more negative than normal so normal signal would not reach threshold & AP not reached (less responsive to signal)

Question 25

What is the result of hyperkalemia?

Answer 25

• muscle weakness
• arrhythmias
• 8 mmol/L can cause complete cardiac arrest

Question 26

What is the result of hypokalemia?

Answer 26

• muscle weakness
• decreased smooth muscle contractility
• severe cases <3.5 mmol/L paralysis, alkalosis

Question 27

What factors contribute to water/fluid balance?

Answer 27

water input (2.5L/day) and output (2.5L/day)
* input: absoroption across GI & production by cellular metabolism
* output: excretion in urine and feces &loss through sweat and respiration

Question 28

What controls osmotic homeostasis and fluid balance?

Answer 28

Na+ and kidneys
* ion transport effects fluid balance effects osmotic homeostasis

Question 29

What is normal osmotic pressure?

Answer 29

300 mOsm in & out of cells (intracellular, interstitial, plasma)
* cells remain same volume (osmotic equilibrium)

Question 30

What happens with drinking large amounts of pure water?

Answer 30

↓ [solutes] ↓ ([osmotic])
if uncorrected, water will flow into cells where the osmotic concentration is higher so kidneys quickly excrete water to compensate which increases urine volume of low osmolarity.

Question 31

What happens with consuming large quantity of salt nuts and no water?

Answer 31

↑ plasma [osmotic]
If uncorrected, cell volume may shrink so kidneys respond by quickly modifying [urine] to excrete more solutes in a decreased volume of urine

Question 32

How does the kidney compensate for changes in fluid?

Answer 32

By controlling the rate of water excretion via changes in the rate of water reabsorption

Question 33

What are the main compartments of the kidney?

Answer 33

• cortex: composed of glomerulus, Bowmans capsule, juxtaglomarular apparatus, convoluted tubules
• medulla: composed of collecting ducts and loops of henle

Question 34

Function of the kidney renal tubules

Answer 34

passive water re-absorption, couples to active re- absorption of solutes (including Na+, K+ & Cl-).

Question 35

How does solute transport vary depending on the segment of kidney tubules?

Answer 35

• Proximal & Distal tubules have Na,K-ATPase PUMPS that drive an osmotic gradient to re-absorb water.
• Descending limb of Henle is impermeable to ions (no pumps) & draws out water only.
• Ascending limb of Henle has Na,K PUMPS, & draws solute (re-absorbs) out from the tubular fluid.

Question 36

What is the system of the loop of henle?

Answer 36

Countercurrent Multiplier System
Generates differential osmotic gradient from the anatomical arrangement of loop of henle, which is in turn used along the length of the collecting duct to control the rate of water re-absorption from urine and allows for efficient disposal of excess solutes and water
* Allows kidneys to dilute urine to 1/6 the osmolarity of plasma or concentrate it up to 4x that of plasma so excrete urine of highly variable osmolarity (50-1200 mOsm/L)

Question 37

What is osmolarity?

Answer 37

the concentration of a solution expressed as the total number of solute particles per liter.

Question 38

Where is osmolarity typically high and low in the kidney tubules?

Answer 38

• the bottom of the loop of henle is typically ↑ osmolarity, being salty concentrated in NaCl+urea since water drawn out
• distal tubule is often ↓ osmolarity with solutes being reabsorbed

Question 39

What is the functional unit of the kidney?

Answer 39

the nephron
Each kidney is made up of about a million nephron filtering units which include a filter, called the glomerulus, and a tubule.

Question 40

What is the two step

Answer 40

1. the glomerulus filters your blood
2. the tubule returns needed substances to your blood and removes wastes.

Question 41

What is filtered into the glomerulus?

Answer 41

*100% filtered
Includes *water, *salts, *bicarbonate, *glucose, *amino acids, creatinine, urea

*are reabsorbed in the proximal tubule

Question 42

How does the filtrate move through the nephron?

Answer 42

• 100% filtered into glomerulus
• up to 65% solutes can be reabsorbed in proximal tubule
• water is drawn out in the descending limb
• solutes reabsorbed in the ascending limb
• about 10% of filtrate left in the distal tubule
• more reabsorption of solutes occurs in the collecting duct
• 0.5-5% of filtrate remains

Question 43

What are some major hormones involved in osmotic homeostasis?

Answer 43

• Aldosterone (from adrenal cortex)
• anit-diuretic hormone (ADH) (from posterior pituitary gland)
• Angiotensin II (Ang II)
• Atrial natriuretic peptide (ANP)
• Vitamin D3 (calcitriol)
• parathyroid hormone (PTH)

Question 44

What is the role of aldosterone and ADH?

Answer 44

Both act on distal convoluted tubule and collecting ducts
* aldosterone: conserves water via reabsorption of Na+ (water follows salt) using Na/K exchange channels (K+ excreted, Na+ retained)
* ADH: controls rate/amount of water renal reabsorption via aquaporin-2

Question 45

What stimulates the release of aldosterone and ADH?

Answer 45

↓BP or severely dehydrated
* Body limits urine output to conserve/retain water releasing aldosterone (adrenal cortex) & ADH (posterior pituitary gland).

Question 46

What system is aldosterone a part of?

Answer 46

renin-angiotensin system (vasoconstriction causes ⇧BP)
* plays a crucial role in the regulation of renal, cardiac, and vascular physiology, and its activation is central to many common pathologic conditions including hypertension, heart failure, and renal disease

Question 47

How does ADH stimulate re-absorption of water?

Answer 47

1. ADH binds to receptor
2. G-coupled protein receptor activated and PKA stimualtes Aquaporin-2 expression on apical membrane
3. water floods into cell via channels
4. water rapidly exits cell via aquaporin-3 channels in basolateral membrane
5. water flows into blood

Question 48

Where is ADH high/low?

Answer 48

• left: no water being reabsorbed so low
• right: lots of water being reabsorbed so high

Question 49

How does aldosterone conserve water?

Answer 49

Via reabsorption of Na+
* Aldosterone secretion results in extra Na+ channels in apical membrane & Na/K pumps in basolateral membrane so influx of Na into cells + active pumping of Na into plasma (Cl- follows) retains both salt & water
* Also stimulates thirst & ADH release & a potent vasoconstrictor

Question 50

Physiological response of with a salt deficit

Answer 50

Na+ imbalance - Increased salt appetite and thirst
* ↑ aldosterone: more Na+ reabsorbed (less excreted)
* ↑ADH: more water reabsorbed (less excreted)

Question 51

Physiological response with excess water loss

Answer 51

fluid imbalance
* ↑ADH: more water reabsorbed (less excreted)

Question 52

What are pressure receptors?

DRAW!

Answer 52

Special pressure sensors called baroreceptors (or venoatrial stretch receptors) located in the right atrium of the heart detect increases in the volume and pressure of blood returned to the heart. These receptors transmit information along the vagus nerve to the CNS.

Question 53

What do low pressure receptors do?

Answer 53

In the atria and pulmonary vein (associated with ↑ renal sympathetic activity) detect/ correct for hypovolemia (body loses fluid) and restore circulating volume and BP (low to high)

Question 54

What do high pressure receptors do?

Answer 54

In the aortic arch & carotid sinus (associated with ↓ renal sympathetic activity) detect/ correct for hypervolemia (fluid overload) and restores circulating volume and BP (high to low)

Question 55

Main kidney functions

Answer 55

• sodium balance
• potassium excretion
• acid excretion
• calcium/ phospate balance
• erythropoesis

Question 56

What is the kidneys responce to chronic kidney disease (CKD) and how can it be treated?

Answer 56

Question 57

What are cases with excessive retention of Na+ and Cl-?

Answer 57

• Large amounts of sea water and/or fast infusion of saline
• Hypersecretion of Aldosterone
• congestive heart failure
• renal failure
• Hypernatremia (serum [Na+] >145 mmol/L)

Question 58

What does large amounts of sea water/ saline cause?

Answer 58

excessive retention of Na+ and Cl-
* body compensates and symptoms include hypernatremia → secretion of ANPs more Na+ excretion, hypervolemia, acute hypertension

Question 59

Result of hypersecretion of aldosterone on electrolyte balance

Answer 59

excessive retention of Na+ and Cl-
* i.e. Cushing’s syndrome, ↓K+, ↑blood pH, ↑BP

Question 60

Result of congestive heart failure on electrolyte balance

Answer 60

excessive retention of Na+ and Cl-
* ↓BP causes baroreceptors to think body needs volum so ↑Na+
* often includes renal failure to control Na+ reabsorption

Question 61

Hypernatremia on electrolyte balance

Answer 61

Excessive retention of Na+ and Cl-
A hyperosmolar condition due to a ↓ in total body water relative to Na+
* usually due to water deficiency so osmotic shift of water out of cells resulting in ↓ in intracellular water & brain volume

Question 62

Cases with deficiency of Na+ and Cl-

Answer 62

• hyponatremia
• underlying medical conditions
• drinking too much water in endurance sports
• ↑ renal loss/↓ reabsorption of Na+
• non-renal losses via GI

Question 63

Result of hyponatremia on electrolyte balance

Answer 63

excess of water relative to solute (relative ratio)

Question 64

Result of drinking to much water during endurance sport on electrolyte balance

Answer 64

deficiency in Na+ and Cl- via dilution
* Body water levels rise, cells begin to swell
* Neurologic problems due to osmotic shift of water into brain cells

Question 65

What causes ↑ renal loss/↓ reabsorption of Na+?

Answer 65

• diuretics
• diabetes (glucose = presence of excess osmotic solutes)
• renal disease
• ↓ aldosterone secretion/activity

Question 66

What are non-renal losses of Na+ and Cl-?

Answer 66

losses via GI such as vomiting and diarrhea

Question 67

Fill the table

Answer 67

Question 68

Symptoms associated with fluid volume

Answer 68

affects BP & CNS function

Question 69

Serum [K+] in hypokalemia

Answer 69

< 3.5 mmol/L

Question 70

hypokalemia causes and symptoms

Answer 70

• causes: most commonly due to ↑ K+ excretion, but also inadequate intake or extra- to intracellular shift or combination
• symptoms: usually related to muscular or cardiac function (membranes hyperpolarize)

Question 71

Serum [K+] in hypokalemia

Answer 71

greater than 5.5 mmol/L

Question 72

Causes and symptons of hyperkalemia

Answer 72

• causes: usually a combination of excessive intake, ↓ excretion or shift from intracellular to extracellular (i.e. low GFR +↑ intake of K+ foods)
• symptoms: usually related to muscular or cardiac function – weakness/fatigue most common, but can lead to sudden death from cardiac arrhythmias (membranes hypopolarize)

Question 73

Describe excessive dietary intake causing hyperkalemia

Answer 73

• Eating disorders or unusual diets (↑K+ foods, i.e. bananas, oranges, dried fruits, fruit juices, nuts, vegetables with ↓Na+)
• heart healthy diets (↓Na+/↑K+)
• ↑K+ in herbal supplements, sports drinks, salt substitutes or drugs

Question 74

Describe why decreased excretion of K+ in hyperkalemia might occur

Answer 74

• Renal insufficiency or failure
• Drugs (i.e. K+ sparing diuretics, NSAIDs, ACE inhibitors, trimethoprim – antibiotic that antagonizes Na+ channels in distal tubules)

Question 75

Describe what causes the intracellular to extracellular shift in hyperkalemia

Answer 75

• diabetes mellitus
• beta-blocker therapy
• metabolic acidosis (diabetic ketoacidosis)
• catabolic states

Question 76

Describe inadequate dietary intake causing hypokalemia

Answer 76

• eating disorders
• starvation
• pica
• alcoholism
• dental/swallowing problems
• low K+ TPN

Question 77

Describe why increased excretion of K+ in hypokalemia might occur

Answer 77

• mineralocorticoid excess (i.e. Cushing syndrome, hyperaldosteronism, steroid therapy)
• hyperreninism
• osmotic diuresis (hyperglycemia)
• GI losses (i.e. vomiting & diarrhea causing hypovolemia sp body tries to retain Na+),
• hypomagnesemia
• drugs (i.e. diuretics, methylxanthines)
• genetic & renal disorders

Question 78

Describe what causes the extracellular to intracellular shift in hyperkalemia

Answer 78

• alkalosis (metabolic or respiratory- increasing pH/loss of H ions)
• insulin or glucose administration
• refeeding
• hypothermia

Question 79

Fill in the chart

Answer 79

Question 80

Symptoms associated with muscular function

Answer 80

nerve transmission, muscle contraction

Question 81

What is the result of sweat on electrolyte balance?

Answer 81

losing water & electrolytes
* Causes hypovolemia + a loss of sodium + insensible & obligate urine losses
* Replacing with water only dilutes the bodies Na+ further causing hypoosmolarity

Question 82

What are the AIs of Na+ and Cl-?

Answer 82

Question 83

Na+ and Cl- AIs for pregnancy and lactation

Answer 83

AI does not change despite tissue building & plasma volume of fetus & added NaCl in milk
* Na+: 1.5 g/d
* Cl-: 2.3 g/d

Question 84

Salt AIs for adults

Answer 84

3.8 g/day (note that salt is 40% Na)
* Na+: 1.5 g/d
* Cl-: 2.3 g/d

Question 85

Upper limit of Na+ and Cl-

Answer 85

• Na+ = 2.3 g
• Cl- = 3.6 g
• = 6 g/day of Salt (NaCl)

Question 86

How much sodium is associated with higher BP?

Answer 86

Na+ intake of 2.3 g/d is associated with higher blood pressure (vs 1.2 g/d)

Question 87

How are Na+ and Cl- typically consumed?

Answer 87

Consumed mainly as NaCl which naturally low in fruits & veggies & higher in meats, but especially prevalent in process foods:
* ~10% of intake naturally occurring in food
* ~15% added at table
* ~75% from food processing

Question 88

What is the daily average intake of NaCl?

Answer 88

Daily average intake is highly variable (estimated by assessing salt intake or urinary excretion)
* =2-5 g of Na (US) so 5-13 g NaCl
* US median intake of Na from foods (not incl. salt added at table) is 2.3 g/d (women) & 4 g/d (men)

Question 89

What is the recommended minimum intake of Na+ and Cl-?

Answer 89

We are physiologically better able to handle low salt intake
* 500 mg Na
* 750 mg Cl

Question 90

Aside from NaCl, how else is Na added to food products?

Answer 90

• monosodium glutamate (MSG)
• sodium citrate
• sodium nitrite
• sodium saccharin
• baking soda (sodium bicarbonate)
• sodium benzoate
• hydrolyzed vegetable protein (HVP).

Question 91

How does NaCl differ between 1/2 cup of fresh veggies vs. canned veggies?

Answer 91

• Fresh <0.04 g
• Canned >0.2 g

Question 92

sources high in sodium and chloride

Answer 92

Question 93

Where is sodium used in the food industry?

Answer 93

• Color Developer: Promotes development of color in meats & sauerkraut
• Fermentation Controller: Keeps organic action in check in cheeses, sauerkraut, baked goods
• Binder: Holds meat together as it cooks
• Texture Aid: Allows dough to expand & not tear
• Preservative: Binds water, makes it unavailable to bacteria

Question 94

What contribute to ↑ Na+ intake?

Answer 94

• convenience foods
• ready-to-eat meals
• canned foods
• eating out frequently

Question 95

How to reduce Na+ intake

Answer 95

• minimize processed foods
• choose fresh foods
• Read labels to compare foods and select reduced sodium option

Question 96

Difference between salt and sodium

Answer 96

Not interchangeable
* 1 g of salt contains 0.4 g Na+

Question 97

Tips to reduce sodium intake

Answer 97

• Use herbs & spices to flavour foods
• Avoid adding salt to your food when eating
• Limit use of condiments
• Buy fresh or frozen vegetables
• Rinse canned foods (i.e. beans) to remove excess salt
• Choose breakfast cereals that are lower in sodium
• Buy low or reduced sodium versions or no salt added

Question 98

What are the AIs for K+?

Answer 98

Question 99

What is associated with >4.7 g/d of K+?

Answer 99

associated with ↓ risk of stroke, hypertension, osteoporosis & kidney stones

Question 100

Why is AI higher for lactation?

Answer 100

Needs higher due to extra K secreted in breast milk
* 5.1 g/d

Question 101

How is K+ typically consumed?

Answer 101

K+ widely available in fruits, vegetables but dietary intake varies widely depending on dietary habits

Question 102

What is the average intake of K+?

Answer 102

• Median consumption (NHANES III) = 2.2 g/d (F) & 3.3 g/d (M)
• Only 10% of men & < 1% of women meet AI

Question 103

What is the UL for K+?

Answer 103

No UL
* may consume as much as 11 g/d without any consequences (kidney very good at excretion)
* 18 g may cause problems … No cases of hypokalemia reported from food but supplemental potassium should only be provided under medical supervision

Question 104

Reccomended minimum intake of K+?

Answer 104

2 g/d

Question 105

Food sources of potassium

Answer 105

High in fresh fruits & vegetables!!!
* Particularly leafy green & root veg, vine fruit, also some in beans, peas, tree fruits
* Also milk/yogurt, meats

Question 106

How can potassium be used as a salt substitute?

Answer 106

Can ↑ K+ intake, providing 0.4 - 2.8 g K/tsp
* 100% KCl
* mixtures, 65% NaCl, 25% KCl, 10% MgSO4

Question 107

What does processing do to the sodium and potassium content of foods?

Answer 107

As foods become more processed K+ is lost Na+ is gained