Renal

Question 1

Pronephros

Answer 1

week 4

Question 2

Mesonephros

Answer 2

interim kidney in first trimester

becomes male genital system

Question 3

Metanephros

Answer 3

permanent kidney

appears in 5th week

Question 4

Ureteric bud gives rise to

Answer 4

ureter, pelvises, calyces, collecting ducts, fully canalized by week 10

Question 5

metanephric mesenchyme

Answer 5

interacts with ureteric bud

induces differentiation and formation of glomerulus through to distal convoluted tubule

Question 6

Ureteropelvic junction is last to canalize and most common site of ______

Answer 6

obstruction

can lead to hydronephrosis

Question 7

Babies who cant pee in utero develop the potter sequence which consists of:

Answer 7

pulmonary hypoplasia
oligohydramnios
twisted face
twisted skin
extremity defects
renal failure (in utero)

oligohydramnios causes the other problems due to compression

caused by aut. recessive polycystic kidney disease, obstructive uropathy, bilateral renal agenesis, chronic placental insufficiency

Question 8

horseshoe kidney

Answer 8

inferior poles of both kidneys duse abnormally and get trapped under the inferior mesenteric artery. This results in them remaining low in the abdomen

kidney functions normal

Question 9

Patient is born with only one functioning kidney.

Answer 9

congenital solitary functioning kidney

hypertrophy of contralateral kidney

Question 10

unilateral renal agenesis

Answer 10

ureteric bud fails to develop and induce differentiation of metanephric mesenchyme

complete absence of kidney and ureter

Question 11

multicystic dysplastic kidney

Answer 11

ureteric bud fails to develop and induce differentiation of metanephric mesenchyme

results in nonfunctioning kidney consisting of cysts and connective tissue

unilateral

Question 12

bilateral multicystic dysplastic kidney can result in

Answer 12

potters syndrome

Question 13

Duplex collecting system

Answer 13

bifurcation of ureteric bud before it enters the metanephric blastema creates a Y shaped bifid ureter

OR

two ureteric buds reaching and interacting with metanephric blastema

strongly associated with vesicoureteral reflux and or ureteral obstruction which increases risk of UTI

Question 14

Posterior urethral valves

Answer 14

Membrane remnant in the posterior urethra in males

persistence and lead to urethral obstruction

presents prenatally by hydronephros and dilated or thick walled bladder on ultrasound

Question 15

What is the most common cause of bladder outlet obstruction in male infants

Answer 15

Posterior urethral valves

Question 16

What kidney is used for donor transplantation

Answer 16

Left kidney because of its longer renal vein

Question 17

Renal blood flow

Answer 17

renal artery –> segmental artery –> interlobar artery –> arcuate artery –> interlobular artery–> afferent arteriole –> glomerulus –> efferent arteriole –> vasa recta/peritubular capillaries –> venous outflow

Question 18

Course of ureters

Answer 18

renal pelvis –> under gonadal arteries –> over common iliac artery –> under uterine artery/vas deferns (retroperitoneal)

Question 19

Three points of constriction of the ureter

Answer 19

ureterovesical junction
ureteropelvic junction
pelvic inlet

Question 20

In a 70 kg person what is the total body water and the ICF and ECF

Answer 20

total body water is 60% or 42 kg
ICF is 40% (2/3) or 28 kg
ECF is 20% (1/3) or 14 kg

Question 21

ECF is composed of

Answer 21

plasma 25% of ECF

Interstitial fluid 75% of ECF

Question 22

There is a ______ K concentration intracellularly

Answer 22

high

Question 23

plasma volume can be measured by radiolabeling ____

Answer 23

albumin

Question 24

extracellular volume can be measured by

Answer 24

inulin and mannitol

Question 25

The glomerular filtration barrier

Answer 25

composed of

• Fenestrated capillary endothelium
• Basement membrane with type 4 collagen chains and heparan sulfate
• Epithelial layer consisting of podocyte foot processes

Question 26

how does the glomerular filtration barrier work according to size and charge

Answer 26

• all three layers are neg charge and prevent entry of other neg charged molecules like albumin
• fenestrated capillary endothelium prevent entry of >100 nm molecules/blood cells
• podocyte foot processes interpose with basement membrane
• slit diaphragm which prevent entry of molecule >50-60 nm

Question 27

Renal clearance formula

Answer 27

Cx=(UxV)/P

Ux= Urine concentration of X
Px= Plasma concentration of X
V=Urine flow rate
Cx=Clearance of X

Question 28

If Cx is ____ than GFR

Answer 28

less than GFR

net reabsorption of X

Question 29

If Cx is ____ than GFR

Answer 29

greater than GFR

net tubular secretion of X

Question 30

If Cx is _____than GFR

Answer 30

equal to GFR

no net secretion or reabsorption

Question 31

____ clearance can be used to measure GFR. Why?

Answer 31

Inulin

because it is freely filtered and is neither reabsorbed nor secreted

Question 32

GFR equation

Answer 32

Uinulin x V/Pinulin = Cinulin

= Kf[(Plasma concentration of glomerular capillary - plasma concentration of bowman space)-(Osmotic concentration of glomerular capillary)]

= (Pcr x Una) / (Ucr x Pna)

V=urine flow rate

Question 33

_____ clearance is an approximate measure of GFR. Why only an estimate?

Answer 33

creatinine

Slightly overestimates the GFR because creatinine is moderately secreted by renal tubules

Question 34

Effective renal plasma flow (eRPF) can be estimated using ______

Answer 34

para-aminohippuric acid (PAH) clearance

100% excretion of all PAH that enters the kidney

Question 35

Effective renal plasma flow equation

Answer 35

eRPF=UpahxV/Ppah=Cpah

underestimates true renal plasma flow slightly

Question 36

renal blood flow =

Answer 36

RPF/(1-Hct)

Question 37

plasma volume

Answer 37

TBVx(1-Hct)

Question 38

Filtration fraction

Answer 38

FF= GFR/RPF

normal filtration fraction is 20%

Question 39

Filtered load

Answer 39

GFR x plasma concentration

Question 40

Prostaglandins _______ afferent arterioles

Answer 40

dilate

“PDA”

This causes increased renal plasma flow and increased GFR. Therefore no change in filtration fraction (GFR/RPF)

Question 41

Angiotensin II ___ efferent arterioles

Answer 41

constrict

“ACE”

This causes a drop in GFR but an increase in GFR, therefore there is an increase in FF (GFR/RPF)

Question 42

Filtered load

Answer 42

GFR x Px

Question 43

Excretion rate

Answer 43

V x Ux

Question 44

Reabsorption rate

Answer 44

filtered-excreted

Question 45

Secretion rate

Answer 45

excreted - filtered

Question 46

Fractional excretion of sodium (Fe na)

Answer 46

Fe Na= Na excreted/Na filtered= (VxUna)/(GFRxPna)

Question 47

At what plasma level does glucosuria begin

Answer 47

~200 mg/dL

Question 48

At what plasma level are transporters fully saturated (Tm)

Answer 48

~375 mg/dL

Question 49

At normal glucose levels (60-120) glucose is ______ reabsorbed in ________ tubule by Na/Glucose cotransport

Answer 49

completely

proximal convoluted tubule (PCT)

Question 50

What part of the nephron do you reabsorb all glucose and amino acids.

Answer 50

early proximal convoluted tubule

Question 51

what part of the nephron is most HCO3-, Na+, Cl-, PO4, K+, H2O, Uric Acid reabsorbed

Answer 51

early proximal convoluted tubule

Question 52

what part of the nephron is there a brush border and isotonic absorption. It generates and secretes NH3 which enables the kidney to secrete more H+

Answer 52

early proximal convoluted tubule

Question 53

Where does PTH act to inhibit Na/PO4 cotransport ? And what does it result in?

Answer 53

early proximal convoluted tubule

PO4 excretion

Question 54

Where does AT II act to stimulate Na/H exchange? and what does it result in

Answer 54

early proximal convoluted tubule

increase Na, H2O, and HCO3 reabsorption

contraction alkalosis

Question 55

Where is 65-80% of Na reabsorbed

Answer 55

early proximal convoluted tubule

Question 56

Where is H20 passively reabsorbed in the nephron and how

Answer 56

Thin descending loop of henle
via medullary hypertonicity
It is impermeable to Na

Question 57

what part of the nephron is the concentrating segment that makes urine hypertonic

Answer 57

Thin descending loop of henle

Question 58

What part of the nephron reabsorbs Na, K , and Cl. Indirectly induces paracellular reabsorption of Mg and Ca through a positive lumen potential generated by K backleak

Answer 58

Thick ascending loop of henle

10-20% of Na reabsorbed

Question 59

What part of the nephron is important for making the urine less concentrated and is impermeable to H20

Answer 59

Thick ascending loop of henle

Question 60

What part of the nephron is important for reabsorbing Na, Cl and is impermeable to H20. It is important for fully diluting (hypotonic) the urine.

Answer 60

Early distal convoluted tubule

5-10% Na reabsorbed

Question 61

PTH effect on early distal convoluted tubule

Answer 61

increases Ca/Na exchange which results in Ca reabsorption

Question 62

What part of the nephron is regulated by aldosterone and it reabsorbs Na in exchange for secreting K+ and H+

Answer 62

Collecting tubule

3-5% Na reabsorbed

Question 63

Effect of aldosterone on the collecting tubule

Answer 63

acts on mineralocorticoid receptor to induce protein synthesis

in principal cells: increase apical K conductance, increase Na/K pump, increase epithelial Na channel (ENaC) activity –> lumen negativity –> increases H+ ATPase activity –> H+ secretion –> increases HCO3/Cl exchanged activity

Question 64

Effect of ADH on the collecting tubule

Answer 64

acts at V2 receptor to insert aquaporin H2O channels on apical side

Question 65

What renal syndrome is due to a defect in the general reabsorption within the PCT

Answer 65

Fanconi syndrome

results in excretion of AA, glucose, HCO3, PO4, and all substances reabsorbed by the PCT

may lead to metabolic acidosis, hypophosphatemia, osteopenia

Question 66

What renal syndrome is due to a resorptive defect in the thick ascending loop of henle that affects Na/K/2Cl cotransporter

Answer 66

Bartter syndrome

results in metabolic alkalosos, hypokalemia, hypercalciuria

increased renin, aldosterone, urine Ca

Question 67

What renal syndrome is due to reabsorption defect of NaCl in DCT

Answer 67

Gitelman syndrome

results in metabolis lakalosis, hypokalemia, hypocalciuria

Increased renin, aldosterone
Decreased serum Mg and Urine ca

Question 68

What renal syndrome is due to gain of function mutation that increases activity of Na channel and thus increased Na reabsorption in collecting tubules

Answer 68

Liddle syndrome

results in metabolic alkalosis, hypokalemia, hypertension, decreased aldosterone

Increased BP
Decreased plasma renin and aldosterone

Question 69

What renal syndrome present similar to hyperaldosteronism ? how do you treat it?

Answer 69

liddle syndrome

treat with amiloride

“it is a liddle like hyperaldosteronism”

Question 70

What renal syndrome is due to a hereditary deficiency of 11beta hydroxysteroid dehydrogenase.

Answer 70

Syndrome of Apparent Mineralocorticoid excess

This results in excess cortisol (usually the enzyme would convert it to cortisone) and ultimately increased mineralocorticoid receptor activity

Metabolic alkalosis, hypokalemia, hypertension, decreased serum aldosterone level

Question 71

Syndrome of Apparent Mineralocorticoid excess can be caused from _____ acid present in licorice which blocks activity of 11beta hydroxysteroid dehydrogenase

Answer 71

glycyrrhetinic acid

Question 72

How can you best treat Syndrome of Apparent Mineralocorticoid excess

Answer 72

treat with K sparing diuretics which decrease mineralocorticoid effects

or treat with corticosteroids which result in decrease of endogenous cortisol production. Ultimately decreasing mineralocorticoid receptor activation

Question 73

TF/P > 1

Answer 73

Tubular fluid concentration/plasma concentration

when solute is reabsorbed less quickly than water or when solute is secreted

Question 74

TF/P = 1

Answer 74

Tubular fluid concentration/plasma concentration

When solute and water are reabsorbed at the same rate

Question 75

TF/P<1

Answer 75

Tubular fluid concentration/plasma concentration

when solute is reabsorbed more quickly than water

Question 76

What cells secrete renin?

Answer 76

juxtaglomerular cells in response to decreased renal blood pressure and increased sympathetic tone (beta 1)

Question 77

What is reaction is renin important for

Answer 77

converting angiotensinogen to angiotensin I

Question 78

What enzyme converts angiotensin I to angiotensin II

Answer 78

ACE

Question 79

Renin

Answer 79

responds to decreased renal perfusion pressure that is detected by renal baroreceptors in the afferent arterioles.

It increases renal sympathetic discharge (beta 1 effect) and decreases NaCl delivery to macula densa cells

Question 80

Angiotensin II

Answer 80

helps maintain blood volume and blood pressure. Net effect of preservation of renal function with increased FF in low volume state with simultaneous Na reabsorption to maintain circulating volume

responds to drop in BP by causing efferent arteriole constriction which increases GFR and increases FF but with compensatory Na reabsorption in proximal and distal nephron

limits reflex bradycardia which would normally accompany its pressor effects

Question 81

ANP/BNP

Answer 81

released from atria (ANP) and ventricles (BNP) in response to increase volume –> relaxes vascular smooth mm via cGMP and increases GFR –> decrease in renin

ANP : secreted in response to increased atrial pressure which causes increased GFR and increased Na filtration with no compensatory Na reabsorption in distal nephron. Net effect: Na loss and volume loss

“check” on the renin-angiotensin-aldosterone system

Question 82

What is the effect of ANP/BNP on the afferent and efferent arterioles

Answer 82

Afferent dilates
Efferent constriction
Promotes natriuresis (excretion of Na in urine)

Question 83

ADH

Answer 83

responds to increased plasma osmolality and responds to low blood volume states

stimulates reabsorption of water in collecting ducts

Also stimulates reabsorption of urea in collecting ducts to maintain corticopapillary osmotic gradient

Question 84

Aldosterone

Answer 84

primarily regulated ECF volume and Na content

responds to low blood volume states and increased plasma [K]

Causes increased Na reabsorption, K secretion, H secretion

Question 85

What responds to hyperkalemia by increasing K excretion

Answer 85

Aldosterone

Question 86

Angiotensin II effects

Answer 86

vasoconstriction –> increased BP

Constrict efferent arteriole –> Filtration fraction increase –> preserves GFR when RBF is low

Increase kidney Na/H activity at the PCT cell –> Na, HCO3, H20 reabsorption –> contraction alkalosis

Causes aldosterone secretion which causes the alpha intercalated cells to secrete H+ by increase in H+ ATPASE activity

Aldosterone secretion also causes principal cells to reabsorb Na nd secrete K

ADH release from posterior pituitary causes principal cells to reabsorb H20 by increasing aquaporins

Question 87

Juxtaglomerular apparatus

Answer 87

consists of mesengial cells, juxtaglomerular cells, and macula densa

maintains the GFR via renin-angiotensin aldosterone system

Question 88

Juxtaglmerular cells

Answer 88

modified smooth muscle of afferent arteriole

Question 89

Macula densa

Answer 89

NaCl sensor
Located at distal end of loop of Henle

sense decrease NaCl delivery to DCT and increase renin release –> efferent arteriole vasoconstriction –> increases GFR

Question 90

How can beta blockers impact the juxtaglomerular apparatus

Answer 90

they decrease BP by inhibiting Beta 1 receptors of the JGA and thus decreasing renin release

Question 91

Released by interstitial cells in peritubular capillary bed in response to hypoxia

Answer 91

erythropoietin

this is why it is supplemented in patients with chronic kidney disease

Question 92

_____ cells convert 25-OH vitamin D3 to 1,25-(OH)2 vitamin D3 (calcitriol, active form). What enzyme is important for this?

Answer 92

PCT cells

via 1alpha hydroxylase ( + by PTH)

Question 93

Paracrine secretion of ______ vasodilates the afferent arterioles to increase RBF

Answer 93

prostaglandins

Question 94

NSAIDs block ________and thus constriction of afferent arterioles and decreased GFR. This may result in acute renal failure in low renal blood flow states

Answer 94

prostaglandins

Question 95

______ is secreted by PCT cells and promotes natriuresis. At low doses it ______ the interlobular arteries, afferent arterioles, efferent arterioles and thus increases RBF (little or no change to GFR). At higher doses it acts as a _______

Answer 95

Dopamine
Dilates
Vasoconstrictor

Question 96

Parathyroid hormone effect on kidney

Answer 96

Secreted in response to a drop in plasma Calcium concentrations, increase in PO4, or decrease in plasma 1,25-(OH)2D3

Causes increase in Ca reabsorption (DCT), decrease in PO4 reabsorption (PCT), and increase 1,25(OH)2D3 production

increased Ca and PO4 absorption from gut via vitamin D

Question 97

Insulin shifts K out or into cells?

Answer 97

INsulin therefore INto cells –> hypokalemia

Question 98

What causes hypokalemia due to shift of K into cells

Answer 98

Hypoosmolarity
Alkalosis
Beta adrenergic agonist ( increase Na/K ATPase)
Insulin (increase Na/K ATPase)

Question 99

What causes hyperkalemia due to shift of K out of cells?

Answer 99

Digitalis (blocks Na/K ATPase)
Hyperosmolarity
Lysis of cells
Acidosis
Beta blockers
High blood sugar
Succinylcholine

“DO LABSSS”

Question 100

Hypokalemia effects

Answer 100

U waves and flattened T waves on ECG

Arrhythmias, mm cramps, spasm, weakness

Question 101

Hyperkalemia effects

Answer 101

Wide QRS, peaked T waves, arrhythmias, mm weakness

Question 102

Hypocalemia effects

Answer 102

Tetany, seizures, QT prolongation, twitching (Chvostek sign), spasm (trousseau sign)

Question 103

Hypercalemia effects

Answer 103

Stones --> renal stones
Bones --> Bone pain
Groans --> abdominal pain
Thrones --> increased urinary frequency
Psychiatric overtones --> anxiety, altered mental status

Question 104

Hypomagnesia effects

Answer 104

Tetany
Torsades de pointes
hypokalemia
hypocalcemia

Question 105

Hypermagnesia effects

Answer 105

Decreased DTRs
Lethargy
Bradycardia
Hypotension
Cardiac Arrest
Hypocalcemia

Question 106

hypophosphatemia effects

Answer 106

Bone loss
osteomalacia in adults
rickets in children

Question 107

Hyperphosphatemia effects

Answer 107

renal stones
metastatic calcifications
hypocalcemia

Question 108

SIADH effects on BP, Renin, aldosterone

Answer 108

normal or increased BP
Decreased Plasma renin
decreased aldosterone

Question 109

Primary hyperaldosteronosim (Conn syndrome)

Answer 109

Increased BP and aldosterone

Decreased plasma renin

Question 110

Renin secreting tumor

Answer 110

Increased BP, increased plasma renin, increased aldosterone

Question 111

Metabolic acidosis

Answer 111

decreased pH due to decreased [HCO3] or <20

compensate by decreasing PCO2 by hyperventiation

immediate compensation

Question 112

Metabolic alkalosis

Answer 112

increased pH due to increased [HCO3] or >28

immediate compensation by increasing PCO2 by hypoventiation

Question 113

Respiratory acidosis

Answer 113

Decreased pH due to increased PCO2 or >44

delayed compensation by increasing [HCO3] reabsorption

Question 114

Respiratory alkalosis

Answer 114

Increased pH due to decreased PCO2 or < 36

delayed compensation by decreasing [HCO3] reabsorption

Question 115

Winters formula

Answer 115

PCO2=1.5[HCO3]+8 +/- 2

predicted respiratory compensation for a simple metabolic acidosis

if predicted< measured PCO2 respiratory acidosis

if predicted> measured PCO2 respiratory alkalosis

Question 116

Henderson Hasselbach equation

Answer 116

pH= 6.1 + log((HCO3)/(0.03PCO2))

Question 117

Check the anion gap when there is

Answer 117

metabolic acidosis

Question 118

anion gap formula

Answer 118

Na- (Cl+HCO3)

if >12 anion gap
if 8-12 normal anion gap

Question 119

anion gap metabolic acidosis (AGMA)

Answer 119

MUDPILES

Methanol (formic acid)
Uremia
Diabetic Ketoacidosis
Propylene Glycol
Iron tablets or INH
Lactic Acidosis
Ethylene glycol (oxalic acid)
Salicylates (late)

Question 120

Normal anion gap metabolic acidosis (NAGMA)

Answer 120

HARDASS
Hyperalimentation
Addison disease
Renal tubular acidosis
Diarrhea
Acetazolamide
Spironolactone
Saline infusion

Question 121

Metabolic alkalosis caused by

Answer 121

Loop diuretics
Vomiting
Antacid Use
Hyperaldosteronism

Question 122

Distal renal rubular acidosis

Answer 122

Type 1

NAGMA

inability of alpha intercalated cells tos ecrete H+ –> no new HCO3 is generated –> metabolic acidosis

urine ph >5.5 and low serum K

increased risk for calcium phosphate kidney stones (due to increased urine pH and increased bone turnover)

Question 123

Proximal renal tubular acidosis

Answer 123

Type 2

NAGMA

defect in PCT HCO3 reabsorption which increases excretion of HCO3- in urine resulting in metabolic acidosis

urine pH <5.5 and decreased serum K

Increased risk for hypophosphatemic rickets (in fanconi syndrome)

Question 124

Hyperkalemic tubular acidosis

Answer 124

type 4

NAGMA

hypoaldosteronism or aldosterone resistance; hyperkalemia –> drop in NH3 synthesis in PCT –> decrease in NH4 excretion

Question 125

Amphotericin B toxicity can cause what type of renal tubular acidosis

Answer 125

Distal renal tubular acidosis

type 1

Question 126

Fanconi syndrome, multiple myeloma, carbonic anhydrase inhibitors can cause what type of renal tubular acidosis

Answer 126

Proximal renal tubular acidosis

type 2

Question 127

Decreased aldosterone production or increased aldosterone resistance can cause what type of renal tubular acidosis

Answer 127

Hyperkalemic tubular acidosis

type 4

Question 128

Hematuria with no casts

Answer 128

bladder cancer or kidney stones

Question 129

Pyuria with no casts

Answer 129

Acute cytitis

Question 130

RBC casts

Answer 130

Glomerulonephritis, hypertensive emergency

Question 131

WBC casts

Answer 131

Tubulointerstitial inflammation, acute pyelonephritis, transplant rejection

Question 132

Fatty casts (oval fat bodies)

Answer 132

Nephrotic syndrome. Associated with Maltese cross sign)

Question 133

Granular muddy brown casts

Answer 133

acute tubular necrosis

Question 134

Waxy casts

Answer 134

end stage renal disease/chronic renal failure

Question 135

Hyaline casts

Answer 135

nonspecific, can be a normal finding, often seen in concentrated urine samples

Question 136

Nephrotic syndrome

Answer 136

Massive proteinuria (>3.5 g/day), with hypoalbuminemia. hyperlipidemia, edema, frothy urine with fatty casts

podocyte disruption results in impaired charge barrier

associated with hypercoagulable state due to antithrombin (AT) III loss in urine and increased risk of infection (loss of immunoglobulins in urine and soft tissue compromise by edema)

Question 137

Nephritic syndrome

Answer 137

Inflammatory

RBC casts in urine and hematuria if glomeruli involved

due to GBM disruption

can see hypertension (due to salt retention), increased BUN and creatinine, oliguria, hematuria, azotemia

Question 138

Nephrotic-Nephritic syndrome

Answer 138

severe nephritic syndrome with profound GBM damage that damages the glomerular filtration charge barrier causing nephrotic range proteinuria (>3.5) and concomitant features of nephrotic syndrome

Question 139

What nephritic syndromes are commonly seen in nephrotic-nephritic syndrome

Answer 139

Diffuse proliferative glomerulonephritis

Membranoproliferative glomerulonephritis

Question 140

Most common cause of nephrotic syndrome in children

Answer 140

Minimal change disease (lipoid nephrosis)

mostly primary and is triggered by recent infection, immunization, immune stimulus. –> excellent response to steroids

light microscopy - normal
Immunofluorescence - negative
Electron microscopy - effacement of podocyte foot processes

Question 141

Most common cause of nephrotic syndrome in AF and Hispanics

Answer 141

Focal segmental glomerulosclerosis (nephropathy)

primary or secondary

primary has inconsistent response to steroids and make progress to chronic kidney disease

light microscopy- Segmental sclerosis and hyalinosis

Immunofluorescence- often negative but may be + for nonspecific focal deposits of IgM, C3, C1

Electron microscopy - effacement of foot processes similar to minimal change disease

Question 142

Membranous nephropathy/ membranous glomerulonephritis

Answer 142

can be primary or secondary

primary has poor response to steroids and can progress to CKD

Light microscopy- diffuse capillary and GBM thickening
Immunofluorescence- granular due to IC deposition
Electron microscopy- spike and dome” appearance of subepithelial deposits

Question 143

Most common organ to be affected by amyloidosis

Answer 143

Kidney!

light microscopy - congo red stain shows apple green birefringence under polarized light due to amyloid deposition in the mesangium

Nephropathy

Question 144

Most common cause of end stage renal disease in the united states

Answer 144

Diabetic glomerulonephropathy

Hyperglycemia –> nonenzymatic glycation of tissue proteins –> mesangial expansion

GBM thickening and increased permeability

Hyperfiltration due to glomerular HTN and increased GFR –> glomerular hypertrophy and glomerular scarring (glomerulosclerosis) leading to further progression of nephropathy

Light microscopy- Mesengial expansion, GBM thickening, eosinophilic nodular glomerulosclerosis (kimmelstiel-wilson lesions)

Question 145

Acute poststreptococcal glomerulonephritis

Answer 145

seen in children 2-4 weeks after a group A strep infection of pharynx or skin.

resolves in children
Adults can get renal insufficiency

sx: peripheral, periorbital edema, cola colored urine, HTN. + strep titers/serologies, decrease complement levels (C3) due to consumption

LM: glomeruli enlarged and hypercellular
IF: starry sky granular appearance. Lumpy bumpy. Due to IgG, IgM, C3 deposition along GBM and mesangium
EM: subepithelial immune complex humps

Question 146

Acute poststreptococcal glomerulonephritis is what type of hypersensitivity reaction

Answer 146

type III

Question 147

This nephritis results in a crescent moon shape on light microscopy

Answer 147

rapidly progressive (crescentic) glomerulonephritis

cresent consists of fibrin and plasma proteins with glomerular parietal cells, monocytes, and macrophages

Question 148

What conditions can result in rapidly progressive glomerulonephritis

Answer 148

1) good pastures
2) Granulomatosis with polyangitis (wegners)
3) Microscopic polyangitis

Question 149

This nephritic syndrome is mostly due to SLE

Answer 149

Diffuse proliferative glomerulonephritis

Light microscopy: wire looping of capillaries
IF: granular
EM: subendothelial and sometimes intramembranous IgG based ICs often with C3 deposition

Question 150

IgA nephropathy (Berger disease)

Answer 150

episodic hematuria that occurs concurrently with resp or GI tract infections (IgA is secreted by mucosal linings)

Renal pathology of IgA vasculitis or HSP

LM: mesengial proliferation
IF: IgA based IC deposits in mesangium
EM: mesengial IC deposition

Question 151

Alport syndrome is due to a mutation in

Answer 151

type IV collagen

Question 152

Alport syndrome

Answer 152

mutation in type IV collagen results in thining and splitting of glomerular basement membrane

Question 153

Triad of eye problems, glomerulonephritis, sensorineural deafness

Answer 153

cant see, cant pee, cant hear a bee

Alport syndrome

EM: basket weave

Question 154

Type I membranoproliferative glomerulonephritis may be secondary to _____ or _____ infection

Answer 154

hep B or hep C

Question 155

Type II membranoproliferative glomerulonephritis is associated with _____ nephritic factor

Answer 155

C3

IgG antibody that stabilizes C3 convertase which results in persistent complement activation –> drop in C3 levels

intramembranous deposits also called dense deposit disease

Question 156

Type I and II membranoproliferative glomerulonephritis have this appearance on H&E and PAS stains

Answer 156

mesangial ingrowth –> GBM splitting –> tram track appearance on H&E and PAS stains

Question 157

Most common kidney stone presentation

Answer 157

calcium oxalate stone in patient with hypercalciuria and normocalcemia

Question 158

Calcium oxalate

Answer 158

hypocitraturia, low pH, radioopaque on xray and CT, shaped like an envelope or dumbbell

can result from ethylene glycol (antifreeze), vitamin c abuse, malabsorption

treat with thiazides, citrate, low sodium diet

Question 159

Calcium phosphate

Answer 159

increased pH, radioopaque on xray and CT, wedge shaped prism

tx with low sodium diet and thiazides

Question 160

Ammonium magnesium phosphate (struvite)

Answer 160

increased pH, radiopaque on xray and CT, coffin lid appearance

Usually due to urease + bugs that hydrolyze urea to ammonia –> urea alkalinization

forms staghorn calculi

tx: eradication of underlying infection, surgical removal of stone

Question 161

Uric acid

Answer 161

decreased pH, radiolUcent on xray, minimally visible on MRI, rhomboid or rosettes

hyperuricemia. Often seen in diseases with increased cell turnover

treat with alkalinization of urine, allopurinol

Question 162

cystine

Answer 162

decreased pH, radioopaque on xray and CT, hexagonal

cystine reabsorbing PCT transporter loses function, causes cystinuria

results in COLA - cysteine, Ornithine, lysine, arginine poor reabsorption

staghorn calculi

+ sodium nitroprusside test

treat with low sodium diet, alkalinization of urine, chelating agents if refractor

Question 163

serum _____ becomes elevated if obstruction is bilateral or if patient has obstructed solitary kidney

Answer 163

creatinine

Question 164

Most common primary renal maligancy. Most common in men 50-70 yo. Increased incidence with smoking and obesity

Answer 164

Renal cell carcinoma (RCC=3 letters= chromosome 3 gene deletion)

polygonal clear cells that accumulate lipids and carbs. Often golder yellow due to increased lipid content

originate from the PCT __> invades renal vein (may develop varicocele if left sided) __ IVC –> hematogenous spread –> metastasis to lung

pt can also present with hematuria and polycythemia

rarely curative

Question 165

Benign epithelial cell tumor arising from collecting ducts and results in a well circumscribed mass with central scar. Patient has painless hematuria and large eosinophilic cells with abundant mitochondria without perinuclear clearing

Answer 165

Renal oncocytoma

Question 166

Most common renal malignancy of early childhood between 2-4 yo

Answer 166

Nephroblastoma (wilms tumor)

Question 167

Nephroblastoma (wilms tumor)

Answer 167

presents with large palpable unilateral flank mass and or hematuria. Contains embryonic glomerular structures

Question 168

Nephroblastoma (wilms tumor) results from what kind of mutation

Answer 168

LOF mutations of tumor suppressor genes WT1 and WT2 on chromosome 11

Question 169

Denys drash syndrome

Answer 169

• Wilms tumor
• Diffuse mesangial sclerosis (Early onset nephrotic syndrome)
• Dysgenesis of gonads (male pseudohermaphroditism), WT1 mutation

Question 170

WAGR complex

Answer 170

wilms tumor
Aniridia (absence of iris)
Genitourinary malformation
Mental retardation/intellectual disability (WT1 deletion)

Question 171

Beckwith-wiedemann syndrome

Answer 171

wilms tumor, macroglossia, organomegaly, hemihyperplasia (WT2 mutation)

Question 172

Transitional cell carcinoma

Answer 172

urothelial carcinoma

most common tumor of urinary tract system

painless hematuria without casts

risk: Phenacetin, Smoking, Aniline dyes, and cyclophosphamide

Question 173

Squamous cell carcinoma of the bladder

Answer 173

chronic irritation of urinary bladder can result in squamous metaplasia –> dysplasia and squamous cell carcinoma

risk: schistosoma haematobium infection, chronic cystitis, smoking, chronic nephrolithiasis.

present with painless hematuria

Question 174

Patient leaks with urge to void immediately due to overactive bladder (detrusor instability)

Answer 174

related to UTI

urgency incontinence

Question 175

Overflow incontinence

Answer 175

imcomplete emptying (detrusor underactivity or outlet obstruction) –> leak with overfilling

Question 176

What is the most common cause of UTI? what are the other causes?

Answer 176

E coli is most common overall
Staph sapro (sexually active)
Klebsiella
Proteus mirabilis (urine has ammonia scent)

Question 177

UTI lab findings

Answer 177

+ leukocyte esterase
+ nitrites (indicated gram -)
Sterile pyuria and - urine cultures suggest urethritis by N gonorrhoeae or chlamydia trachomatis

Question 178

Acute pyelonephritis

Answer 178

neutrophils infiltrate renal interstitium

affect cortex with sparing of glomeruli/vessels

WBC in urine ( +/- WBC cast)

CT shows striated parenchymal enhancement

Question 179

Chronic pyelonephritis

Answer 179

due to recurrent acute pyelonephritis

coarse asymmetric corticomedullary scarring , blunted calyx

Tubules contain eosinophilic casts resembling thyroid tissue (thyroidization of kidney)

Question 180

Xanthogranulomatous pyelonephritis

Answer 180

seen with chronic pyelonephritis

grossly orange nodules that can mimic tumor nodules; characterized by widespread kidney damage due to granulomatous tissue containing foamy macrophages

associated with proteus infection

Question 181

Acute kidney injury -abrupt decline in renal function as measured by increase of _____ and ____

Answer 181

creatinine and BUN

or by oliguria/anuria

Question 182

Prerenal azotemia

Answer 182

due to decreased RBF –> decreased GFR

Na/H20 and urea retained by kidney in an attempt to conserve volume

this increases BUN/creatinine ratio (urea is reabsorbed, creatinine is not) and decrease FEna

higher urine osmolality compared to intrinsic renal and postrenal injury

Question 183

Intrinsic renal failure

Answer 183

due to acute tubular necrosis : patchy necrosis –> debris obstructing tubule and fluid backflow across necrotic tubule –> decrease GFR

Urine has epithelial/granular casts

Urea reabsorption is impaired

decrease BUN/creatinine ratio and increase FE sodium

Question 184

Postrenal azotemia

Answer 184

due to outflow obstruction. develops only with bilateral obstruction or in a solitary kidney

Question 185

Chronic renal failure

Answer 185

usualyl due to HTN, DM, congenital anomalies

Question 186

Hypocalcemia, hyperphosphatemia, and failure of vitamin D hydroxylation associated with chronic renal disease and leads to

Answer 186

Secondary hyperparathyroidism

High serum PO4 can bing Ca and result in tissue deposits. This causes a drop in Ca

Decrease 1,25 OH2D3 results in decreased intestinal Ca absorption

results in subperiosteal thinning of bones

Question 187

Acute interstitial nephritis (tubulointerstitial nephritis)

Answer 187

Acute interstitial renal inflammation

pyuria (classically eosinophils) and azotemia occuring after administration of drugs that act as haptens, inducing hypersensitivity

Pee (diuretics)
Pain free (NSAIDs)
Penicillins and cephalosporins
Proton pump inhibitors
rifamPIN

Question 188

Most common cause of acute kidney injury in hospitalized patients

Answer 188

Acute tubular necrosis

Question 189

Acute tubular necrosis

Answer 189

can be fatal during the oliguric phase

increases FE sodium

granular “muddy brown” casts

can also be caused by ischemic - secondary to decreased renal blood flow which results in death of tubular cells that may slough into tubular lumen

Can also be caused by nephrotoxic due to secondary injury resulting from toxic substances

proximaly tubules are especially susceptible to nephrotoxic injury

Question 190

Acute tubular necrosis stages

Answer 190

1) inciting event
2) maintenance phase -oliguric. Risk of hyperkalemia, metabolic acidosis, uremia
3) recovery phase-polyuric, BUN and serum creatinine fall, risk of hypokalemia and renal wasting of other electrolytes minerals

Question 191

Vasospasms + DIC can result in generalized cortical infarction of both kidneys

Answer 191

Diffuse cortical necrosis

associated with obstetric catastrophes and septic shock

Question 192

Renal papillary necrosis

Answer 192

sloughing of necrotic renal papillae –> gross hematuria and proteinuria

may be triggered by recent injection or immune stimulus

associated with sickle cell disease or trait, acute pyelonephritis, NSAIDs, diabetes mellitus

Question 193

Numourous cysts in cortex and medulla. The kidneys are enlarged B/L. Eventually leads to destruction of parenchyma and progressive renal failure

Answer 193

autosomal dominant polycystic kidney disease

Question 194

Cystic dilation of colelcting ducts that presents in infancy.

Answer 194

Autosomal revessive polycystic kidney disease

associated with congenital hepatic fibrosis

significant oliguric renal failure in utero can lead to potter sequence.

Question 195

Inherited disease causing tubulointerstitial fibrosis and progressive renal insufficiency with inability to concentrate urine

Answer 195

Autosomal dominant tubulointerstitial kidney disease

or medullary cystic kidney disease

medullary cysts usually not visualized and there are smaller kidneys on ultrasound

poor prognosis

Question 196

mutation in PKD1 on chromosome 16 is common in what renal cyst disorder

Answer 196

Autosomal dominant polycystic kidney disease

also PKD2 on chromosome 4

associated with berry aneurysms, mitral valve prolapse, benign hepatic cysts, diverticulosis

Question 197

Ureter is immediately anterior to

Answer 197

internal iliac artery