Renal

Question 1

How does the R kidney positioning differ from the L?

Answer 1

The R kidney is located slightly lower d/t displacement by the liver.

Question 2

What are the three major functions of the kidney?

Answer 2

1. Filtration
2. Reabsorption
3. Secretion

(4.Excretion)

Question 3

Differentiate between hydrostatic and oncotic pressures.

Answer 3

Hydrostatic pressure refers to the pushing of fluids against the vessel walls from within the vasculature and within the interstitial space.

Osmotic pressure refers to the pulling force exerted on the vessel walls from within the vasculature and within the interstitial space

Question 4

What is thirst triggered by?

Answer 4

Increased concentration of extracellular fluid (increased osmolality)
Decreased circulating blood volume

Question 5

The amount of fluid excreted in the urine is controlled primarily by which hormones?

Answer 5

ADH
Aldosterone
Natriuretic Peptides (ANP and BNP)

Question 6

Where is ADH synthesized and released?

Answer 6

Synthesized in the hypothalmus

Released by the posterior pituitary gland

Question 7

What factors increase the release of ADH?

Answer 7

• Increased osmolality of the extracellular fluid
• Decreased circulating fluid volume
• Pain
• Nausea
• Physiologic/psychologic stressors

Question 8

How does ADH impact the concentration of filtrate in the collecting duct (and DCT)?

Answer 8

ADH stimulates the epithelial cells in the collecting duct to produce aquaporins causing water to be reabsorbed from the filtrate to the capillaries.

This happens via osmosis d/t the increased concentration of solutes (increased osmolality) in the capillary vs. the decreased concentration (hypotonic solution) present in the renal tubules.

Question 9

Where is aldosterone synthesized and released from?

Answer 9

Adrenal cortex

Question 10

What are the main stimuli for aldosterone release? (2)

Answer 10

1. Angiotensin II (AII)- from RAAS, activated by decreased circulating blood volume
2. Increased concentration of K ions in the plasma

Question 11

How does aldosterone impact the concentration of the filtrate in the collecting duct? (3)

Answer 11

1. Stimulates the Na-K pump
2. Opens Na channels (increased Na in the blood pulls water into the vascular=increased blood volume)
3. Open K channels (K moves into filtrate)

Question 12

What hormones opposed the action of aldosterone?

Answer 12

ANP

BNP

Question 13

When are ANP and BNP release?

Answer 13

ANP is released with the atrial cells are overstretched signaling an excess of volume.
BNP is released by the ventricles when EDV is elevated indicating an excess of volume (HF)

Question 14

How do natriuretic peptides oppose the action of aldosterone?

Answer 14

ANP opposes AII. Promote fluid excretion by nautriuresis (moving Na into the urine so that water follows=decreased blood volume)

Question 15

How many nephrons are there per kidney?

Answer 15

One million

Question 16

Traces the flow of filtrate through the kidney.

Answer 16

Glomerulus to PCT to LoH to DCT to collecting duct

Question 17

What are the general functions of the glomerulus?

Answer 17

The capillary net that filters plasma, making ultrafiltrate that is called tubular fluid once it enters the PCT

Question 18

What are the general functions of the PCT?

Answer 18

Has cuboidal epithelial cells with brush border villus membrane to increase surface area and is the main site of reabsorption of water, lytes and nutrients (isotonic filtrate)

Question 19

What is the general function of the thin descending Loop of Henle?

Answer 19

Impermeable to solutes but permeable to water. Concentrates fluid as well as diffuses water out. (hypertonic filtrate)

Question 20

What is the general function of the thick ascending Loop of Henle?

Answer 20

Impermeable to water but has NaK2Cl active transporters that reabsorb more solutes and dilute the tubular fluid. (Hypotonic) Sets up and maintains interstitial concentration gradient

Question 21

What is the general function of the DCT?

Answer 21

Electrolyte modifications. Sense concentraiton of Na and Cl via villi and signals juxtaglomerular cells via PGE to release renin. Aldosterone acts on late distal tubule principle cells.

Question 22

What is the general function of the collecting ducts?

Answer 22

Site of free water reabsorption through water channels ( aquaporins)controlled by ADH.
Important to acid-base balance; allow H secretion and bicarb secretion when necessary

Question 23

What are the functions of the kidney?(5)

Answer 23

1. Remove toxins/waste from the body
2. Maintain proper H2O and electrolyte balance of blood (excrete H20 and lytes, secrete renin)
3. Maintain proper pH of blood (usually excrete H and create bicarb)
4. Secrete EPO
5. Activate vit D (vital to Ca absorption)

Question 24

What is filtration?

Answer 24

The movement of substances out of the blood into the filtrate. Glomerulus into the PCT.

Question 25

What is reabsorption?

Answer 25

The return of substances from filtrate now present in the tubular fluid back into the blood.

Question 26

What is secretion?

Answer 26

The movement of substances out of peritubular blood via kidney tubule cells in tubular fluid.

Question 27

What is the vasa recta?

Answer 27

Capillaries located around the LoH; absorb interstitial fluid without excessive removal of interstitial solute.

Question 28

What is the renal corpuscle?

Answer 28

Glomerulus and Bowman’s space

Question 29

What is the kidney’s release of renin stimulated by (RAAS stimulation)?

Answer 29

Decreased BP
Decreased fluid volume
Increased B1-Sympathetic

Question 30

What is the RAAS inhibited by?

Answer 30

Increased BP
Increased fluid volume
Decreased B1-Sympathetic
ANP

Question 31

What are the steps of the RAAS?

Answer 31

In response to decreased BP or volume renin is released by the kidneys.
Renin acts on the liver which release Angiotensinogen that is cleaved by the renin resulting in Angiotensin I which is converted via the lungs by ACE to Angiotensin II which stimulates the adrenal cortex to release Aldosterone. Aldosterone acts on the distal portion of the nephron to increase Na K ATP pumps to increased the reabsorption of Na and H2O=increased blood volume and BP

Question 32

In addition to stimulated the release of Aldosterone what does Angiotensin II do?

Answer 32

Causes vasoconstriction

Question 33

How are the capillaries of the glomerulus different from other capillary networks in the body?

Answer 33

Glomerular capillaries branch from and drain into arterioles

Question 34

Why is there no oncotic pressure in Bowman’s space?

Answer 34

This area should be protein free which is indicative of decreased oncotic pressure

Question 35

Why is the NFP in the efferent arteriole=0?

Answer 35

No filtration happens here.

Question 36

What is the purpose of the podocytes?

Answer 36

Surround the fenestrated epithelium and are negatively charged, so they provide a barrier to movement of negatively charged ions

Question 37

What do mesangial cells do?

Answer 37

Provide structural support for glomerular capillaries, secrete matrix proteins, phagocytose and regulate GFR

Question 38

How do mesangial cells regulate GFR?

Answer 38

SMC:Contraction and relaxation which alters the available surface are for filtration and affects GFR

Question 39

How does each nephron regulate its own GFR?

Answer 39

Tubuloglomerular feedback

Question 40

What is the regulatory structure that controls tubuloglomerular feedback?

Answer 40

Juxtaglomerular apparatus

1. Glomerulus
2. Macula densa
3. Juxtaglomerular cells

Question 41

What does the macula densa do?

Answer 41

Located near the end of the ascending LoH in the DCT. Senses changes in the amount of NaCl. Increased NaCl inhibits renin release and a decreased load promotes renin release (decreased amount of tubular fluid moving by)

Question 42

What do the juxtaglomerular cells do?

Answer 42

Surround afferent arteriole. Produce and release renin

Question 43

How is bicarbonate reabsorbed?

Answer 43

Bicarb is converted to CO2 and H20 via carbonic anhydrase in the PCT. Carbonic anhydrase is then used to the catalyze the reverse reaction creating H and bicarb; bicarb is reabsorbed back into the blood via the Na HCO3 transporter and H is excreted in the urine

Question 44

What does decreased reabsorption cause?

Answer 44

Dilution of urine and overall increase in fluid volume

Question 45

How is sympathetic nerve activity related to the ‘fight or flight’ response in the kidneys?

Answer 45

Diverts blood from kidneys and GI tract. Increases fluid reabsorption to shut of ability to make urine (Na and H2O reabsorbed)

Question 46

What affect does in an increase in pressure sensed by baroreceptors in the afferent arteriole cause?

Answer 46

Inhibits renin release

Question 47

What are the 2 mechanisms of regulation of RBF and GFR?

Answer 47

1. Autoregulation- myogenic mechanisms and tubuloglomerular feedback
2. Neural regulation
3. Hormonal regulation- RAAS, ADH, Natriuretic peptides

Question 48

How do osmotic diuretics work?

Answer 48

Increase osmolality of the filtrate causing more water to remain in the tubule which is excreted as urine

Question 49

How do ACE inhibitors cause diuresis?

Answer 49

Inhibit AII and Aldosterone. Inhibits reabsorption of Na which keeps more water in the filtrate to be excreted

Question 50

How do loop diuretics work?

Answer 50

Block the Na K 2Cl pumps on the ascending loop to keep solutes in the urine

Question 51

How do thiazide-like diuretics work?

Answer 51

Block Na Cl co-transporter in the DCT blocking Na reaborption

Question 52

How do aldosterone blocking agents work?

Answer 52

Decrease Na and H2O reabsorption and K excretion (potassium sparing)

Question 53

What are the different casts that may be found in urine and what do they indicate? (3)

Answer 53

1. WBC- pylonephritis
2. RBC- glomerulonephritis
3. Epithelial casts- ATN

Question 54

Where is kidney associated pain most often felt?

Answer 54

CVA/flank pain; transmitted from T10-T12 and L1 via sympathetic afferent neurons

Question 55

What is agenesis?

Answer 55

Congenital abnormality. Kidneys don’t develop in the fetus.
Bilateral = incompatible with life
Unilateral= compensatory hypertrophy of functional kidney

Question 56

What is hypoplasia of the kidney?

Answer 56

Congenital abnormality. Some fetal kidney development. Could lead to pediatric ESRF.

Question 57

What causes cystic kidney disease?

Answer 57

Genetically transmitted. 
Autosomal recessive (often lethal and do not make it to reproductive age= less common)
Autosomal dominate (Chromosome 16 PKD1 most common and Chromosome 4 PKD2)

Question 58

What is cystic kidney disease?

Answer 58

Characterized by fluid filled renal cysts, may expand and disrupt urine flow.

Decreased cilia formation of the epithelial cells in the nephron that should detect pressure and solute content passing through and stimulate Ca and cAMP. Decreased intracellular Ca and excessive intracellular cAMP causes reduction of normally function kidney tissue and development of cysts.

Decreased GFR and ability to concentrate urine

Question 59

What are the clinical manifestation of cystic kidney disease?

Answer 59

1. Hypertension (decreased GFR=decreased urine=incr. volume)
2. Pain (common)
3. Concomitant cystic liver involvement

Question 60

What are common causes of secondary glomerular disorders?

Answer 60

Goodpasture syndrome
SLE
Diabetic neuropathy

Question 61

What type of urine is common of a patient with nephrotic syndrome?

Answer 61

Proteinuria d/t necrosis of the glomerulus
3-3.5g loss/day
Usually no hematuria(?)

Question 62

What type of urine is common of a patient with nephritic syndrome?

Answer 62

Mild to moderate proteinuria
*Hematuria and RBC casts present in sediment (RBCs are indicative of less severe injury because they are less negatively charged than protein)

Question 63

How can proteinuria eventually result in hyperlipidemia and hypercoagulability?

Answer 63

Proteinuria leads to hypoalbuminemia which stimulates the liver to increased fat production (hyperlipidemia) and clotting factor production (hypercoagulability)

Question 64

How can proteinuria cause generalized edema?

Answer 64

Proteinuria causes hypoalbumemia which decreases intravascular osmotic pressure allowing fluid to move into the interstitium causing generalized edema

Question 65

What is minimal change disease or MCD?

Answer 65

• Lipoid nephrosis
• Initiated by allergic or immune condition causing decreased GFR
• Fusion of the glolmerular podocytes and decreased production of anions of the basement membrane =decreased barrier)
• Occurs in children
• Sudden onset of edema, nephrotic levels of proteinuria, and hypoalbuminemia

Question 66

What is acute glomerulonephritis?

Answer 66

Acute inflammation of the glomerulus.
Related to antibody deposition leading to inflammation which results in lysosomal degradation of the basement membrane.
GFR may fall d/t contraction of mesangial cells

Question 67

What are the clinical manifestations of acute glomerulonephritis?

Answer 67

Hematuria, proteinuria, oliguria, azotemia, edema and HTN

Question 68

What does membranous nephropathy describe?

Answer 68

Diffuse thickening of the glomerular basement membrane. (Glomerulonephritis)

Question 69

What is a common cause of postinfectious acute glomerulonephritis? (aka acute proliferative glomerulonephritis)

Answer 69

Follows skin (impetigo) and throat infections 
*Group A beta-hemolytic streptococci

Developing countries, smoky/coffee-colored urine

Question 70

What is Berger disease?

Answer 70

• Acute glomerulonephritis
• IgA nephropathy (found in tracts)
• Upper resp or GI viral infections
• Complex deposition leading to mesangial injury
• Hematuria presents in 1-2days
• Proteinuria (but no HTN or edema)
• Variable prognosis, could lead to ESRD

Question 71

What is indicative of chronic glomeruloneprhitis?

Answer 71

Sclerosis and fibrosis of the kidney

Question 72

What type of urine do patients with chronic glomerulonephritis present with?

Answer 72

Proteinuria with or without hematuria

Question 73

What does the sudden reduction of kidney function consistent with acute renal failure lead to?(4)

Answer 73

• Disruption in fluid, lyte, and acid-base balance
• Retention of nitrogenous waste
• Increased serum Cr
• Decreased GFR

Question 74

What are the three sites of disruption in acute renal failure?

Answer 74

Prerenal (decreased renal perfusion)
Intrarenal (parenchymal renal damage)
Postrenal (obstruction to urine flow)

Question 75

What happens to the BUN:Cr ration with each respective cause of acute renal failure?

Answer 75

Normal 10-20

Prerenal >20
Intrarenal <10
Postrenal 10-20 (equally affected)

Question 76

What will a patient present with d/t decreased GFR secondary to pre-renal acute renal failure?

Answer 76

Oliguria, high urine specific gravity and osmolality, low urine Na, azotemia

Question 77

What are the two possible pathological processes associated with intra-renal acute renal failure?

Answer 77

1. Vascular- RBF decreased, hypoxia, vasoconstriction

2. Tubular- inflammation and reperfusion injury, causes casts, obstructs urine flow, tubular backleak

Question 78

Two most common causes of ATN?

Answer 78

Ischemia

Nephrotoxin

Question 79

Three phase of ATN include:

Answer 79

• Prodromal phase- insult occurs
• Oliguric phase- 1-2 to 8wks; oliguria, progressive uremia, decreased GFR, hypervolemia, hyperkalemia (?dialysis)
• Postoliguric phase- recovery; diuresis, tubular function impaired and azotemia continues, fluid volume deficient until kidneys recover

Full recovery is defined as normal BUN/Cr, may take up to a year.

Question 80

Most common causes of chronic renal failure?

Answer 80

• HTN
• Diabetes

Recurrent pylonephritis
Glomerulonephritis
Polycystic Kidney Disease
Family hx of CKD
Toxin exposure 
Age over 65
Ethnicity

Question 81

What is chronic renal failure defined as?

Answer 81

• Decreased kidney function or kidney damage of 3 months duration based on blood tests, urinalysis, and imaging
• GFR <60ml/minute/1.73m2 for 3 months with or without indication of damage

Question 82

What causes relaxation of the internal sphincter and contraction of the bladder to enable urination?

Answer 82

Pons

Question 83

What role does the cerebral cortex play in urination?

Answer 83

Inhibits via conscious control of the external sphincter

Question 84

What role to sympathetic and parasympathetic nerves play in bladder function?

Answer 84

Sympathetic (L1-2)- allow relaxation and filling

Parasympathetic (S2-4)- cause bladder contraction and relaxation of the internal sphincter to initiate emptying

Question 85

To void:

Answer 85

The detrusor muscle of the bladder must contract and urethral sphincters must relax

Question 86

What is acute pylonephritis?

Answer 86

Infection of the renal pelvis/parenchyma usually from an ascending UTI

Question 87

What is chronic pylonephritis usually associated with?

Answer 87

Reflux or an obstructive process leading to persistent urine stasis
(chronic inflammation causes scarring and loss of functional nephrons)

Question 88

Common causes of urinary tract obstruction include:

Answer 88

*Stones
Tumors
Prostatic hypertrophy
Strictures of the ureters or urethra

Question 89

Why do renal calculi most often form?

Answer 89

Supersaturation of solutes (Ca and Phos), low urine volume, abnormal decreased urine pH

Question 90

Symptoms of kidney stone migration include:

Answer 90

Intense renal colic pain, abrupt and may radiate
N/V
Diaphoresis
Hematuria may be present

Question 91

What is cystitis and what could cause it?

Answer 91

Inflammation of the bladder lining (cystele)

Infection (most common, originates in urethra), chemical irritants, stones, trauma

Question 92

Dietary Calcium ______ kidney stones.

Answer 92

Prevents by binding oxalate and preventing absorption

Question 93

How can hyperparathyroidism lead to hypercalcemia and kidney stones?

Answer 93

PTH is release from the parathyroid gland and increases circulating Ca levels. If Ca is not bound it increases the risk for stone formation

Question 94

Hydronephrosis is:

Answer 94

Distention/dilation of the kidney with urine.

Marked dilation of the renal pelvis and calyces and thinning of the renal parenchyma=decreased function

Question 95

What can an overactive detrusor muscle causes?

Answer 95

Urge incontinence

Question 96

Stress incontinence is secondary to:

Answer 96

Increases in intra abdominal pressure d/t weakening of pelvic muscles or intrinsic urethral sphincter deficiency

Question 97

Overactive bladder syndrome is associated with:

Answer 97

Increased daytime frequency and nocturia

Question 98

When does neurogenic bladder occur?

Answer 98

Pathology that produces a disruption of nervous communication governing micturition

Question 99

Overflow incontinence can be caused by:

Answer 99

Underactive/inactive detrusor muscle

Question 100

Possible pathogenesis of enuresis:

Answer 100

Deficiency in ADH
Nocturnal overactivity of the detrusor muscle
Immature/abnormal arousal mechanisms (incr. symp, dec para)
Familial pattern

Question 101

Vesicoureteral Reflux is:

Answer 101

Congenital
Reflux of urine from the ureter-bladder junction

(may manifest as HTN in children)

Question 102

What is ureteral ectopy?

Answer 102

Congenital
Single ureter implanted in an abnormal location or a duplicate ureter
Increased risk for infection and reduced renal function

Question 103

What is ureterocele?

Answer 103

Cystic dilation at distal end of the ureter that feeds into the bladder
Causes ureteral and renal calyx dilation, reflux and infection
Surgical intervention necessary

(s/s- hydronephrosis, UTIs, voiding dysfxn, hematuria, urosepsis, FTT)

Question 104

Systemic hypertension leading to glomeruli dysfunction can lead to what pathologic change:

Answer 104

Obstruction of the renal tubule

Question 105

A mass of proliferating cells found in Bowman’s space is associated with what disease?

Answer 105

Crescentic glomerulonephritis/rapidly progressing glomerulonephritis

Question 106

Acute renal failure due to liver failure (hepatorenal syndrome) is due to:

Answer 106

Diminished intrarenal blood flow

Question 107

What three regulatory mechanisms are involved in tubuloglomerular feedback?

Answer 107

1. Baroreceptor mechanism (if pressure low=stimulate renin)
2. Macula densa (if Na in tubule low=stimulate renin)
3. Sympathetic activity (if low=stimulate renin)

All are signs of low blood volume and pressure, renin release increases pressure.