Steve O's Ridiculous Renal Realities

Question 1

Mesonephros

Answer 1

functions as the interim kidney for 1st trimester;

later contributes to the male genital system

Question 2

Metanephros

Answer 2

permanent;
first appears in 5th week of gestation;
nephrogenesis continues through 32-26 weeks of gestation;
Contains ureteric bud, metanephric mesenchyme,

Question 3

Ureteric bud

Answer 3

derived from caudal end of mesonephric duct;
gives rise to ureter, pelvises, calyces, and collecting ducts;
fully canalized by 10th week

Question 4

metanephric mesenchyme

Answer 4

ureteric bud interacts with this tissue;

interaction induces differentiation and formation of glomerulus through the distal convoluted tubule

Question 5

Ureteropelvic junction

Answer 5

last to canalize and the most common site of obstruction (hydronephrosis) in fetus

Question 6

Potter’s sequence

Answer 6

Oligohydramnios causing compression of developing fetus leading to limb deformities, facial anomalies (low set ears, and retrognathia) and and compression of chest leading to pulmonary hypoplasia (cause of death);
causes include ARPKD, posterior urethral valves, bilateral renal agenesis

Question 7

Horseshoe kidney

Answer 7

Inferior poles of both kidneys fuse;
as they ascend from pelvis, get trapped under inferior mesenteric artery and remain low in the abdomen;
kidney function is normal;
increased risk for ureteropelvic junction obstruction, hydronephrosis, renal stones, and rarely renal cancer (wilms tumor);
associated with Turner Syndrome

Question 8

Multicystic dysplastic kidney

Answer 8

Due to abnormal interaction between ureteric bud and metanephric mesenchyme;
this leads to a nonfunctional kidney consisting of cysts and connective tissue;
if unilateral (most common), generally asymptomatic with compensatory hypertrophy of contralateral kidney;
often diagnosed prenatally via ultrasound;
not inherited, cysts are in renal parenchyma

Question 9

Why is the left kidney taken during living donor transplant?

Answer 9

Because the renal vein is longer

Question 10

Ureters: what is the course from kidney to bladder

Answer 10

pass under uterine artery and under ductus deferens (retroperitoneal);
Water under bridges;
Gynecologic procedures involving ligation of the uterine vessels may damage the ureter leading to ureteral obstruction or ureteral leak

Question 11

Glomerular filtration barrier

Answer 11

Filters based on charge and on size;
Composed of- Fenestrated capillary endothelium (size barrier), Fused basement membrane with heparan sulfate (negatively charged barrier), Epithelial layer consisting of podocyte foot processes;

Question 12

When is the charge barrier lost in the GF barrier

Answer 12

Lost in nephrotic syndrome, resulting in albuminuria, hypoproteinemia, generalized edema, and hyperlipidemia

Question 13

How to measure effective renal plasma flow

Answer 13

estimated using para-aminohuppuric acid (PAH) clearance because it is both filtered and actively secreted in the proximal tubule;
nearly all PAH entering the kidney is excreted

Question 14

Glucose clearance

Answer 14

Glucose reabsorbed in PCT;

anything over ~200 not reabsorbed;

Question 15

Amino acid clearance

Answer 15

Sodium dependent transporters in proximal tubule reabsorb amino acids;

Question 16

Hartnup disease

Answer 16

autosomal recessive;
deficiency of neutral amino acid (e.g. tryptophan) transporters in proximal renal tubular cells and on enterocytes;
leads to neutral aminoaciduria and decreased absorption from the gut;
results in pellagra like symptoms;
treat with high protein diet and nicotinic acid

Question 17

Fluid compartments and their size

Answer 17

60% is total body water;
40% total body weight is intracellular;
20% of total body weight is extracellular;
5% of total body weight is plasma volume;
15% of total body weight is interstitial volume

Question 18

Notable components of PCT

Answer 18

contains brush border;
reabsorbs all glucose and amino acids and most of the bicarb, Na, Cl, Phosphate, K+, and H2O;
isotonic absorption;
generates and secretes NH3, which acts as a buffer for secreted H+;
PTH inhibits Na/Phosphate cotransport leading to secretion of Phosphate;
ATII stimulates Na/H+ exchange causing increased Na, H2O, and bicard reabsorption (permitting contraction alkalosis);
65-80% Na reabsorbed here

Question 19

Thin descending loop of henle

Answer 19

Passively reabsorbs H2O via medullary hypertonicity (impermeable to Na+);
concentrating segment;
Makes urine hypertonic

Question 20

Important components of the Loop of Henle

Answer 20

Actively reabsorbs Na, K, and Cl-;
indirectly induces the parallel reabsorption of Mg2+ and Ca2+ through + lumen potential generated by K+ backleak;
impermeable to H20;
makes urine less concentrated as it ascends;
10-20% Na reabsorbed

Question 21

important components of the Distal Convoluted Tubule

Answer 21

Actively reabsorbs Na and Cl;
makes urine hypotonic;
PTH increases Ca/Na exchange leading to Ca reabsorption;
5-10% of Na reabsorbed

Question 22

Important components of the collecting tubule

Answer 22

Reabsorbs Na in exchange for secreting K and H (regulated by aldosterone);
aldosterone acts on mineralcorticoid receptor which inserts Na channel on luminal side;
ADH acts on V2 receptor inserting aquaporin channel;
3-5% Na reabsorbed here

Question 23

Fanconi syndrome

Answer 23

Reabsorptive defect in PCT;
assoc. w/ increased excretion of nearly all amino acids, glucose, bicarb, and phosphate;
may result in metabolic acidosis (proximal renal tubular acidosis);
causes include hereditary defects (e.g. wilson disease), ischemia, and nephrotoxins/drugs;
FABulous Glittering Liquid

Question 24

Bartter syndrome

Answer 24

Reabsorptive defect in thick ascending loop of henle;
autosomal recessive, affects Na/K/2Cl cotransporter;
results in hypokalemia, and metabolic alkalosis with hypercalciuria;
FABulous Glittering Liquid

Question 25

Gitelman syndrome

Answer 25

Reabsorptive defect of NaCl in DCT;
Autosomal recessive;
less severe than Bartter syndrome;
leads to hypokalemia and metabolic alkalosis, but no hypercalciuria;
FABulous Glittering Liquid

Question 26

Liddle syndrome

Answer 26

Increased Na reabsorption in distal and collecting tubules (increased activity of epithelial Na channel);
autosomal dominant;
results in HTN, hypokalemia, metabolic alkalosis, decreased aldosterone;
treat with amiloride

Question 27

Where does Angiotensin II go to have an effect

Answer 27

1) acts on AT I receptors on smooth muscle causing vasoconstriction and increased BP;
2) constricts efferent arteriole causing increased FF to preserve GFR in low volume states;
3) activates aldosterone;
4) activates ADH release from posterior pituitary;
5) Stimulates hypothalamus causing thirst

Question 28

ANP

Answer 28

released from atria in response to increased volume;
may act as a check on RAAS;
relaxes smooth muscle via cGMP causing increased GFR and decreased renin

Question 29

ADH: what does it respond to

Answer 29

primarily regulates osmolarity;

also responds to low blood volume

Question 30

Aldosterone: what does it regulate

Answer 30

Primarily regulates ECF Na+ content and volume;

responds to low blood volume states as well

Question 31

Juxtaglomerular apparatus

Answer 31

consists of JG cells (modified smooth muscle of afferent arteriole) and the macula densa (NaCl sensor, part of the distal convoluted);
JG cells secrete renin in response to decreased renal blood pressure, decreased NaCl deliver to distal tubule and increased sympathetic tone (B1);
note that beta blockers work here as well as heart

Question 32

Erythropoietin

Answer 32

released by interstitial cells in the peritubular capillary bed in response to hypoxia;

Question 33

Kidney function on Vit. D

Answer 33

Proximal tubule cells convert 25-OH vit. D to 1,25-(OH)2 vitamin D;
Via 1alpha-hydroxylase (increased by PTH)

Question 34

Renin secreted by

Answer 34

JG cells in response to decreased renal arterial pressure and increased renal sympathetic discharge via beta1

Question 35

Prostaglandins and their effect on kidneys

Answer 35

Paracrine secretion vasodilates the afferent arterioles to increase RBF;
NSAIDs block this leading to constriction of the afferent arteriole and decreased GFR;
this may result in acute renal failure

Question 36

Potassium shift due to digitalis

Answer 36

K shift out of cells

Question 37

Potassium shift due to hyperosmolarity

Answer 37

K+ shifts out of cell

Question 38

Potassium shift due to hypo-osmolarity

Answer 38

K+ shifts into cell

Question 39

Potassium shift due to insulin deficiency

Answer 39

K+ shifts out of cell

Question 40

Potassium shift due to insulin activity

Answer 40

K+ shifts into cell (increased Na/K ATPase)

Question 41

Potassium shift due to lysis of cells

Answer 41

K+ shifts out of cell

Question 42

Potassium shift due to acidosis

Answer 42

K+ shifts out of cell

Question 43

Potassium shift due to alkalosis

Answer 43

K+ shifts into cell

Question 44

Potassium shift due to beta adrenergic antagonist

Answer 44

K+ shifts out of cell

Question 45

Potassium shift due to beta adrenergic agonist

Answer 45

K+ shifts into cell (increased Na/K ATPase)

Question 46

Symptoms of low Na level

Answer 46

Nausea, malaise, stupor, coma

Question 47

symptoms of high Na level

Answer 47

Irritability, stupor, coma

Question 48

Symptoms of Low K level

Answer 48

U wave on ECG, flattened t waves, arrhythmias;

muscle weakness

Question 49

Symptoms of High K level

Answer 49

Wide QRS and peaked T waves on ECG, arrhythmias;

muscle weakness

Question 50

Symptoms of low Ca2+ levels

Answer 50

Tetany, seizure, QT prolongation

Question 51

Symptoms of high Ca2+ levels

Answer 51

stones (renal), bones (pain), groans (abdominal pain), psychiatric overtones (anxiety, altered mental status), but not necessarily calciuria

Question 52

Symptoms of low Mg2+ levels

Answer 52

tetany, torsades de pointes

Question 53

Symptoms of high Mg2+ levels

Answer 53

Decreased DTRs, lethargy, bradycardia, hypotension, cardiac arrest, hypocalcemia

Question 54

Metabolic Acidosis with increased anion gap (>12)

Answer 54

MUDPILES;

Methanol, Uremia, Diabetic ketoacidosis, Propylene glycol, Iron or INH, Lactic acidosis, Ethylene glycol, Salicylates

Question 55

Metabolic acidosis with normal anion gap (8-12)

Answer 55

HARDASS;

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

Question 56

Renal tubular acidosis in general

Answer 56

a disorder of the renal tubules which leads to non-anion gap hyperchloremic metabolic acidosis

Question 57

Renal tubular acidosis: type 1

Answer 57

Distal, pH >5.5;
Defect in ability of alpha intercalated cells to secrete H+, thus new bicarb is not generate leading to metabolic acidosis;
associated with hypokalemia, increased risk for calcium phosphate kidney stones (due to increased pH and increased bone turnover);
Caused by amphotericin B toxicity, analgesic nephropathy, multiple myeloma (light chains), and congenital anomalies (obstruction) of the urinary tract

Question 58

Renal tubular acidosis: type 2

Answer 58

Proximal, pH

Question 59

Renal tubular acidosis: Type 4

Answer 59

Hyperkalemic, pH

Question 60

What are the causes of RBC casts

Answer 60

glomerulonephritis, ischemia, or malignant HTN;

Question 61

What are the causes of WBC casts

Answer 61

tubulointerstitial inflammation, acute pyelonephritis, transplant rejection

Question 62

What are the causes of Fatty casts

Answer 62

oval fat bodies;

nephrotic syndrome

Question 63

What are the causes of Granular casts

Answer 63

muddy casts;

Acute tubular necrosis

Question 64

What are the causes of Waxy casts

Answer 64

advanced renal disease/chronic renal failure

Question 65

What are the causes of hyaline casts

Answer 65

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

Question 66

Nomenclature for glomerular disorders: Focal

Question 67

Nomenclature for glomerular disorders: diffuse

Answer 67

> 50% of glomeruli are involved;

e.g. diffuse proliferative glomerulonephritis

Question 68

Nomenclature for glomerular disorders: Proliferative

Answer 68

Hypercellular glomeruli;

e.g. Mesangial proliferation

Question 69

Nomenclature for glomerular disorders: membranous

Answer 69

thickening of glomerular basement membrane;

e.g. membranous nephropathy

Question 70

Nomenclature for glomerular disorders: primary glomerular disease

Answer 70

Involve only glomeruli;
this a primary disease of the kidney;
e.g. minimal change disease

Question 71

Nomenclature for glomerular disorders: Secondary glomerular disease

Answer 71

Involves glomeruli and other organs, this a disaese of another organ system, or a systemic disease that has impact on the kidney;
e.g. SLE, diabetic nephropathy

Question 72

Glomerular diseases that cause Nephritic syndrome

Answer 72

Berger (IgA glomerulonephropathy);
Acute Poststreptococcal glomerulonephritis;
Alport syndrome;
Rapidly progressive glomerulonephritis

Question 73

Glomerular diseases that cause Nephrotic syndrome

Answer 73

Focal segmental glomerulosclerosis;
Membranous nephropathy;
Minimal change disease;
amyloidosis;
Diabetic glomerulonephropathy

Question 74

Glomerular diseases that cause both nephritic and nephrotic

Answer 74

Diffuse proliferative glomerulonephritis;

membranoproliferative glomerulonphritis

Question 75

Nephrotic syndromes in general cause what

Answer 75

nephrOtic syndrome presents with massive prOteinuria (>3.5 g/day, forthy urine), hyperlipidemia, fatty casts, edema;
Assoc. w/ thromboembolism (hypercoagulable state due to AT III loss in urine);
increased risk of infection (loss of immunoglobulins)

Question 76

Focal segmental glomerulosclerosis

Answer 76

LM-segmental sclerosis and hyalinosis;
IF is negative;
EM effacement of foot process similar to minimal change disease;
Most common cause of nephrotic syndrome in blacks and hispanics;
can be assoc. w/ HIV, sickle cell, interferon treatment, and chronic kidney disease due to congenital absence or removal;
inconsistent response to steroid therapy;
may progress to chronic renal disease

Question 77

Membranous nephropathy

Answer 77

LM- diffuse capillary and GBM thickening;
IF-Granular as a result of immune complex deposition;
EM- Spike and Dome with subepithelial deposits;
most common cause of primary nephrotic syndrome in whites;
can be associated with antibodies to phopholipase A2 receptor, drugs (NSAIDs, penicillamine), infections, SLE or solid tumors;
poor response to steroids;
may progress to chronic renal disease;

Question 78

Minimal change disease

Answer 78

LM-normal glomeruli (lipid may be present in PCT cells);
IF is negative;
EM will show effacement of the foot processes;
Nephrotic syndome;
Most common in children;
may be triggered by recent infection, immunization, or immune stimulus;
may be assoc. w/ hodgkin lymphoma (e.g. cytokine mediated damage);
excellent response to corticosteroids

Question 79

Amyloidosis Nephrotic syndome

Answer 79

LM- congo red stain shows apple-green birefringence under polarized light;
kidney is the most commonly involved organ;
assoc. with chronic conditions (e.g. Multiple Myeloma, TB, rheumatoid arthritis)

Question 80

Membranoproliferative glomerulonephritis

Answer 80

nephritic syndrome that can also present as Nephrotic;
Type 1- subendothelial immune complex deposition with granular IF;
tram track appearance due to GBM splitting caused by mesangial ingrowth;
Associated with HBV, HCV, may be idiopathic
Type 2- Intramembranous IC deposits “dense deposits”;
associated with C3 nephritic factor (stabilizes C3 convertase leading to decreased serum C3 levels

Question 81

Diabetic glomerulonephropathy

Answer 81

LM- mesangial expansion, GBM thickening, eosinophilic nodular glomerulosclerosis (kimmelstiel Wilson lesion);
nonenzymatic glycosylation of efferent arterioles leading to increased GFR and increased mesangial expansion

Question 82

Overview of nephritic syndromes

Answer 82

nephrItic=Inflammatory;
when it involves glomeruli it leads to hematuria and RBC casts in urine;
associated with azotemia, oliguria, HTN (due to salt retention), and proteinuria (

Question 83

Acute poststreptococcal glomerulonephritis

Answer 83

LM-glomeruli enlarged and hypercellular;
IF- (starry sky) granular appearance (lumpy bumpy) due to IgG, IgM, and C3 deposition along GBM and mesangium;
EM- subepithelial immune complex (IC) humps;
Most frequently in children;
occurs ~2 weeks after group A strep infection of pharynx, skin;
resolves spontaneously;
Type III hypersensitivity;
presents with peripheral and periorbital edema, dark urine (cola colored), and HTN;
increased anti-DNase B titers and decreased compliment levels

Question 84

Rapidly progressing glomerulonephritis

Answer 84

Can present as nephritic or nephrotic;
LM and IF show crescent moon shape;
crescents consist of fibrin and plasma protein (e.g. C3b) w/ glomerular parietal cells, monocytes, and macrophages;
Associated with goodpastures, granulomatosis w/ polyangitis, microscopic polyangiitis;
Poor prognosis;
rapidly deteriorating renal function (Days to weeks)

Question 85

Goodpasture syndrome

Answer 85

type II hypersensitivity;
antibodies to GBM and alveolar basement membrane causing linear IF;
Hematuria/hemoptysis;
against type IV collagen (lungs, kidney, and lens)

Question 86

Diffuse proliferative glomerulonephritis

Answer 86

due to SLE or MPGN;
LM "loop wiring" of capillaries;
EM- subendothelial and sometimes intramembranous IgG-based ICs often with C3 deposition;
IF- granular;
Most common cause of death in SLE;
can be nephritic or nephrotic

Question 87

IgA nephropathy

Answer 87

AKA berger disease;
Nephritic syndrome;
LM- mesangial proliferation;
EM- mesangial IC deposits;
IF- IgA based IC deposits in mesangium;
seen in HSP;
often presents/flares with a URI or acute gastroenteritis;
episodic hematuria with RBC casts

Question 88

Alport syndrome

Answer 88

presents as nephritic syndrome;
Mutation in type IV collagen leading to thinning and splitting of the glomerular basement membrane;
Most commonly X-linked;
Glomerulonephritis, deafness, and less commonly eye problems

Question 89

Urine dipstick is positive for RBCs in urine, what does this mean

Answer 89

means dipstick reacted to peroxidase reaction of hemoglobin;
if no RBCs seen under microscopy then you have myoglobinurea;
myoglobinurea will cause reactive oxygen species so hydrate and alkalination of urine must be done

Question 90

Calcium renal stones

Answer 90

See envelope or dumbbell shaped crystals in urine;
radiopaque;
precipitates in increased pH (calcium phosphate) and decrease pH (calcium oxylate);
Promoted by hypercalciuria (look for diseases that increase Ca levels);
oxalate crystals can come from ethylene glycol (antifreeze), vit C abuse, Crohn disease;
prevent with Thiazide, citrate, and increased fluid;
Most common stone is calcium oxylate

Question 91

Ammonium Magnesium Phosphate renal stones

Answer 91

Coffin lid crystals;
Radiopaque;
precipitate at increased pH;
AKA struvite stone;
caused by infection (urease + like proteus, kleb, staph);
can form staghorn calculi that can be nidus for UTIs;
treat with eradication of underlying infection and surgical removal of stone

Question 92

Uric Acid renal stones

Answer 92

Rhomboid or rosettes stone;
radiolucent;
precipitate at decreased pH;
Risk factors- decreased urine volume, arid climates, and acidic pH;
visible on CT and ultrasound, not on x-ray;
strong association with hyperuricemia (like gout);
often seen in leukemia (high cell turnover diseases);
treat with alkalization of urine

Question 93

Cystine renal stones

Answer 93

Hexagonal stones;
radiopaque;
precipitate in decreased pH;
mostly seen in children, secondary to cystinuria;
can form staghorn calculi;
sodium nitroprusside test +;
treat with alkalinization of urine and increased hydration

Question 94

Hydronephrosis

Answer 94

distention/dilation of the renal pelvis and calyces;
usually caused by urinary tract obstruction;
other causes include retroperitoneal fibrosis and vesicoureteral reflux;
dilation occurs proximal to site of pathology;
only impairs renal function if bilateral or patient only has one kidney;
leads to compression atrophy of renal cortex and medulla

Question 95

Renal cell carcinoma

Answer 95

originates from proximal tubule cells;
see polygonal clear cells filled with accumulated lipids and carbohydrates;
most common in men 50-70;
increased incidence in smokers and obesity;
manifests clinically with hematuria, palpable mass, secondary polycythemia, flank pain, fever, and weight loss, invades renal vein then IVC and spreads hematogenously;
metastasizes to lung and bone;
associated with defect in chromosome 3 (von-hippel-lindau);
resistant to chemo and radiation;
most common primary renal malignancy

Question 96

Renal oncocytoma

Answer 96

Benign epithelial cell tumor;
large eosinophilic cells with abundant mitochondria without perinuclear clearing (vs. chromophobe RCC);
presents with painless hematuria, flank pain, and abdominal mass;
treat with nephrectomy

Question 97

Wilms tumor

Answer 97

nephroblastoma;
most common renal malignancy of early childhood (ages 2-4);
contains embryonic glomerular structures;
presents with huge, palpable flank mass and/or hematuria;
Loss of function mutations in tumor suppressor genes WT1 or WT2 on chromosome 11;
may be part of beckwith-Wiedemann syndrome or WAGR complex (Wilms, Aniridia, Genitourinary malformation, mental Retardation)

Question 98

Transitional Cell Carcinoma

Answer 98

Most common tumor of urinary tract system;
can occur in renal pelvis, renal calyces, ureters, and bladder;
painless hematuria (no casts) suggests bladder cancer;
associated with problems in your Pee SAC (Phenacetin, Smoking, Aniline dyes, and Cyclophosphamide)

Question 99

Squamous cell carcinoma of the bladder

Answer 99

Chronic irritation of urinary bladder leads to squamous metaplasia causing dysplasia and squamous cell carcinoma;
Risk factors include Schistosoma haematobium infection (middle east), chronic cystitis, smoking, chronic nephrolithiasis;
presents as painless hematuria

Question 100

Acute infectious cystitis

Answer 100

inflammation of urinary bladder;
presents as suprapubic pain, dysuria, urinary frequency, and urgency;
systemic signs (fever, chills) are usually absent;
Risk factors include female, sexual intercourse, and indwelling catheters;
causes- e coli, staph saprophyticus, klebsiella, proteus mirabilis (ammonia scent), adenovirus (hemorrhagic cystitis);
Lab findings- + leukocyte esterase, nitrites appear for gram - organisms, sterile pyuria and - urine cultures suggests gonorrhoeae or chlamydia

Question 101

Acute pyelonephritis

Answer 101

Affects cortex w/ sparing of glomeruli and vessels;
presents with dysuria, fever, CVA tenderness, nausea, and vomiting;
caused by ascending UTI (e coli), vesiculoureteral reflux, and hematogenous spread to kidney;
often presents with WBC casts in urine;
CT shows striated parenchymal enhancement;
risk factors are indwelling urinary catheter, tract obstruction, DM, and pregnancy;
Complications include chronic pyelonephritis, renal papillary necrosis, perinephric abscess;
treat with antibiotics

Question 102

Chronic pyelonephritis

Answer 102

the result of recurrent episodes of acute pyelonephritis;
typically requires predisposition to infection such as vesicoureteral reflux or chronic obstructing kidney stones;
Coarse asymmetric corticomedullary scarring, blunted calyx;
tubules can contain eosinophilic casts resembling thyroid tissue (thyroidization of kidney)

Question 103

Drug-induced interstitial nephritis (tubulointerstitial nephritis)

Answer 103

Acute interstitial renal inflammation;
pyuria (classically eosinophils) and azotemia occurring after administration of drugs that act as haptens, inducing hypersensitivity;
nephritis typically occurs 1-2 weeks after certain drugs (e.g. diuretics, penicillin derivatives, sulfonamides, rifampin), but can occur months after starting NSAIDs;
associated with fever, rash, hematuria, and CVA tenderness, but can be asymptomatic

Question 104

Diffuse cortical necrosis

Answer 104

Acute generalized cortical infarction of both kidneys;
likely due to a combination of vasospasm and DIC;
associated with obstetric catastrophes (e.g. abruptio placentae) and septic shock

Question 105

Avute tubular necrosis: stages and overview

Answer 105

most common cause of intrinsic renal failure;
self-reversible in some cases, but can be fatal if not treated;
death most often occurs during initial oliguric phase;
findings- granular (muddy brown) casts;
3 stages- 1) inciting event 2) maintenance phase-oliguric, lasts 1-3 weeks, risk of hyperkalemia, metabolic acidosis 3) recovery phase-polyuric, BUN and creatinine fall, risk of hypokalemia

Question 106

Avute tubular necrosis: 2 types

Answer 106

1) Ischemic- secondary to decreased renal blood flow (e.g. hypotension, shock, sepsis, CHF), results in death of tubular cells that may slough into tubular lumen (proximal tubule and thick ascending limb are highly susceptible to injury)
2) Nephrotoxic- secondary to injury resulting from toxic substances (e.g. aminoglycosides, radiocontrast agents, lead, cisplatin), crush injury (myoglobinurea), hemoglobinuria, proximal tubule is particularly susceptible to injury

Question 107

Renal papillary necrosis

Answer 107

Sloughing of renal papillae leading to gross hematuria and proteinuria;
may be triggered by a recent infection or immune stimulus;
associated with DM, acute pyelonephritis, chronic phenacetin use (acetaminophen is phenacetin derivative), sickle cell anemia and trait

Question 108

Acute Renal Failure

Answer 108

In normal nephron BUN is reabsorbed (for countercurrent multiplication), but creatinine is not;
acute kidney injury is defined as an abrupt decline in renal function with increased creatinine and increased BUN over a period of several days

Question 109

Prerenal azotemia

Answer 109

As a result of decreased RBF (e.g. hypotension) causing decreased GFR;
Na/H2O and urea retained by kidney in an attempt to conserve volume, so BUN/creatinine ratio increases;
urine osmolarity > 500;
urine Na 20

Question 110

Intrinsic renal failure

Answer 110

Generally due to acute tubular necrosis or ischemia/toxins;
less commonly due to acute glomerulonephritis (e.g. RPGN);
patchy necrosis leads to debris obstructing tubule and fluid backflow across necrotic tubule leading to decreased GFR;
urine has epithelial/granular casts;
BUN reabsorption is impaired leading to decreased BUN/creatinine ratio;
Urine osmolarity 40;
FENa >2%;
Serum BUN/Cr

Question 111

Postrenal azotemia

Answer 111

due to outflow obstruction (stones, BPH, neoplasia, congenital anomalies);
develops only with bilateral obstruction;
Urine osmolarity 40;
FENa >1% (mild)-2% (if severe);
Serum BUN/Cr >15

Question 112

Consequences of renal failure

Answer 112

inability to make urine and excrete nitrogenous waste;
MAD HUNGER- Metabolic Acidosis, Dyslipidemia (increased tg), Hyperkalemia, Uremia (increased bun and creatinine), Na/h2o retention, Growth retardation, Erythropoietin failure (anemia), Renal osteodystrophy

Question 113

Renal osteodystrophy

Answer 113

Failure of Vit D hydroxylation, hypocalcemia, and hyperphosphatemia leading to secondary hyperparathyroidism;
hyperphosphatemia also independently decreased serum Ca by causing tissue calcifications, whereas decreased 1,25-(OH)2 vitamin D leads to decreased intestinal Ca2+ absorption;
causes subperiosteal thinning of bones

Question 114

ADPKD

Answer 114

adults;
bilateral enlarged kidneys with tons of cysts;
destroys the kidney parenchyma;
presents with flank pain, hematuria, hypertension, urinary infection, progressive renal failure;
Autosomal dominant defect in PKD1 (85%, chromosome 16) or PKD2 (15%, chromosome 4);
death from chronic kidney disease or HTN (caused by increased renin);
associated with berry aneurysms, mitral valve prolapse, benign hepatic cysts

Question 115

ARPKD

Answer 115

Infants;
autosomal recessive;
associated with congenital hepatic fibrosis;
significant in utero renal failure can lead to potter sequence;
future concerns of HTN, portal HTN, progressive renal insufficiency;
no surface cysts like ADPKD, only in parenchyma

Question 116

medullary cystic disease

Answer 116

Inherited disease causing tubulointerstitial fibrosis and progressive renal insufficiency with inability to concentrate urine;
medullary cysts usually not visualized;
shrunken kidneys on ultrasound;
poor prognosis

Question 117

simple vs complex renal cyst

Answer 117

simple cysts usually found in outer cortex filled with ultrafiltrate, very common, and account for majority of all renal masses, found incidentally and typically asymptomatic;
Complex cysts, including those that are septated, enhanced, or have solid components as seen on CT, require follow-up or removal due to risk of renal cell carcinoma

Question 118

Mannitol

Answer 118

osmotic diuretic, increased tubular fluid osmolarity, producing increased renal flow, decreased ICP and Intraocular pressure;
used for drug overdose, increased intracranial/ocular pressure;
toxicity-pulmonary edema, dehydration;
contraindicated in anuria, CHF

Question 119

Acetazolamide

Answer 119

mechanism- carbonic anhydrase inhibitor, causes self-limited sodium bicarb diuresis and decreased total body bicarb stores;
used for glaucoma, urinary alkalinization, metabolic alkalosis, altitude sickness, pseudotumor cerebri;
toxicity-hyperchloremic metabolic acidosis, paresthesias, NH3 toxicity, sulfa allergy

Question 120

Furosemide

Answer 120

Mechanism: inhibits Na/K/2Cl of thick ascending limb of loop Henle, abolishes hypertonicity of medulla, preventing concentration of urine, stimulates PGE release (vasodilate afferent arteriole), increased Ca excretion (loops loose Ca);
used for edema, HTN, and hypercalcemia;
toxicity- ototoxicity, hypokalemia, dehydration, allergy (sulfa), Nephritis (interstitial), Gout, OH DANG!

Question 121

Ethacrynic acid

Answer 121

Mechanism- phenoxyacetic acid derivative (not a sulfonamide), essentially same action as furosemide;
Use: diuresis in patients allergic to sulfa drugs;
Toxicity: same as furosemide, can cause hyperuricemia, never use to treat gout

Question 122

Hydrochlorothiazide

Answer 122

inhibits NaCl reabsorption in early distal tubule, decreasing diluting capacity of the nephron, decreased Ca excretion (increasing plasma Ca, so if increased PTH don’t give);
Uses- HTN, CHF, idiopathic hypercalciuria, nephrogenic diabetes insipidus, osteoporosis;
toxicity- hypokalemic metabolic acidosis, hyponatremia, hyperglycenmia, hyperlipidemia, hyperuricemia, and hypercalcemia, sulfa drug

Question 123

K+ sparing diuretics:

Answer 123

Spironolactone and eplerenone are competitive aldosterone receptor antagonists in the cortical collecting tubule;
triamterene and amiloride act at the same part of the tubule by blocking Na channels in CCT;
uses- hyperaldosteronism, K depletion, CHF;
Toxicity- hyperkalemia (can lead to arrhythmias), endocrine effects with spironolactone (gynecomastia, antiandrogen effects)

Question 124

ACE inhibitors: mechanism

Answer 124

captopril, enalapril, lisinopril;
inhibit ACE, decreasing ATII causing decreased GFR by preventing constriction of efferent arterioles;
levels of renin increase as result of loss of feedback inhibition;
inhibition of ACE also prevents inactivation of bradykinin, a potent vasodilator;

Question 125

ACE inhibitors: uses

Answer 125

captopril, enalapril, lisinopril;

HTN, CHF, proteinuria, diabetic nephropathy, prevent unfavorable heart remodeling as a result of chronic HTN;

Question 126

ACE inhibitors: toxicity

Answer 126

CATCHH;
Cough, Angioedema (contraindicated in Cl esterase inhibitor deficiency), Teratogenic (fetal renal malformations), increased Creatinine (decreased GFR), Hyperkalemia, and Hypotension;
avoid in bilateral renal artery stenosis because it will cause further GFR decrease

Question 127

Angiotensin II receptor blockers

Answer 127

ARBS;
-sartans;
similar to ACE inhibitors but do not increased bradykinin so less chance of cough;
Competitively inhibits ATII at angiotensin I receptor;
AT II is the most powerful Na retention hormone