Exam 3: Renal Pathophysiology

Question 1

Top two causes of renal failure:

Answer 1

Diabetes

HTN

Question 2

Endocrine functions of kidneys:

Answer 2

EPO secretion

Vitamin D activation

Question 3

Role of Vitamin D:

Answer 3

Cofactor for intestinal calcium absorption

Question 4

Severe renal impairment occurs at this % of nephrone damage:

Answer 4

75-90%

Question 5

Substances not reabsorbed from the tubules:

Answer 5

Urea

Creatinine

Question 6

Substances partially secreted into the tubules according to body’s needs:

Answer 6

K+
Cl-
Na+

Question 7

Substances completely reabsorbed in the proximal tubule:

Answer 7

Glucose
Proteins
Amino acids

Question 8

HCO3- concentration in the filtrate drops at the ______ due to:

Answer 8

Distal tubule; switch to phosphate/ammonia buffers

Question 9

Three aspects of tubuloglomerular feedback:

Answer 9

1. Baroreceptors in the afferent arteriole inhibits renin when pressure is ↑
2. Stimulation of β1 receptors causes renin release
3. Macula densa sensing ↑ NaCl inhibits renin release

Question 10

Glucose transporter on apical side of renal epithelium:

Answer 10

SGLT2

Question 11

The point at which the tubule cannot reabsorb any further glucose is called:

Answer 11

Renal threshold

Question 12

HCO3- is reabsorbed via this process:

Answer 12

Combines with H+ in the tubule to form H2CO3, which dissociates to CO2 and water, which can cross the membrane

Question 13

Renal compensation for acidosis:

Answer 13

More H+ excretion

Forming HCO3- via glutamine metabolism

Question 14

Renal compensation for alkalosis:

Answer 14

Excretion of filtered HCO3-

Question 15

Electrolyte sequelae of renal compensation for acidosis and mechanism:

Answer 15

Hyperkalemia due to inhibition of the K+ out/H+ in pump on the apical membrane

Question 16

Effects of ADH on the nephron:

Answer 16

Binds to V2 receptor on basolateral membrane; ↑cAMP activates aquaporin 2 which allows 3 H2O across the apical membrane

Question 17

Diabetes insipidus is caused by:

Answer 17

Insufficient ADH

Question 18

S/s of DI:

Answer 18

Large volumes of dilute fluid excreted into urine; severe fluid imbalanes

Question 19

Nephrogenic diabetes insipidus is:

Answer 19

When collecting tubules are unresponsive to ADH

Question 20

Three conditions that cause renin release:

Answer 20

↓ renal blood flow
↓ serum sodium
Activation of β1-adrenergic nerves

Question 21

Condition for aldosterone and angiotensin II release:

Answer 21

Renin release

Question 22

Condition for natriuretic peptide release:

Answer 22

Overstretch of atrial cells due to excess blood volume

Question 23

Actions of natriuretic peptides:

Answer 23

Inhibits actions of angiotensin II

Loss of Na+ and water in urine

Question 24

Condition for urodilatin release:

Answer 24

Distal/collecting tubule identify increased circulating volume

Question 25

Actions of urodilatin:

Answer 25

Similar to natriuretic peptides; inhibit Na+/H2O reabsorption

Question 26

How do ACE inhibitors act as diuretics?

Answer 26

Inhibit formation of angiotensin II and aldosterone, which work to retain water

Question 27

How do loop diuretics work?

Answer 27

Block the Na+/K+/2Cl- pumps in the aloH

Question 28

How do thiazide diuretics work?

Answer 28

Block Na+ reabsorption

Question 29

Types of potassium-wasting diuretics:

Answer 29

Osmotic
Loop
Thiazide

Question 30

Types of potassium-sparing diuretics:

Answer 30

Aldosterone-blocking agents

Question 31

Most useful lab studies to evaluate kidney function:

Answer 31

Urinalysis
Serum creatinine
BUN
GFR tests

Question 32

24-hour urine sample good for:

Answer 32

Evaluating substances that are secreted in varying amounts throughout day

Question 33

Abnormal urine odor:

Answer 33

Ammonia smell (due to bacteria)

Question 34

Normal color in urine is due to:

Answer 34

Urochrome pigments

Question 35

Brown or bright red urine is due to:

Answer 35

RBCs (hematuria)

Question 36

Cloudy urine is due to:

Answer 36

WBCs (infection)

Question 37

Dark yellow or orange urine is due to:

Answer 37

Concentration

Question 38

Excess epithelial cells in the urine indicate:

Answer 38

Inflammation/injury in the nephron (cells sloughing off lining of tubule)

Question 39

WBC casts in the urine are associated with:

Answer 39

Renal infections (pyelonephritis)

Question 40

RBC casts in the urine are associated with:

Answer 40

Inflammation of the glomerulus (glomerulonephritis)

Question 41

Epithelial casts in the urine are associated with:

Answer 41

Sloughing of tubular cells (acute tubular necrosis)

Question 42

Normal creatinine level:

Answer 42

0.7 to 1.5 mg/dl

Question 43

Elevated creatinine indicates:

Answer 43

Increased rate of muscle breakdown or decrease in renal function

Question 44

Urea is:

Answer 44

An end product of protein metabolism that’s excreted primarily by the kidney

Question 45

Normal urea level:

Answer 45

10-20 mg/dl

Question 46

Elevated urea level indicates:

Answer 46

Decrease in renal function or fluid volume

Increased catabolism/dietary protein intake

Question 47

Most accurate way to measure GFR:

Answer 47

Inulin clearance test

Question 48

Define azotemia:

Answer 48

Elevation of BUN/Cr levels, related to decrease in GFR

Question 49

Define uremia:

Answer 49

Elevation of urea in blood

Question 50

Define pyuria:

Answer 50

Presence of leukocytes in urine

Question 51

Five categories of intra-renal disorders:

Answer 51

Congenital
Neoplastic
Infectious
Obstructive
Glomerular

Question 52

Describe pain caused by intrarenal d/o:

Answer 52

Felt at CVA
Dull, constant character
May be felt through out T10-L1 dermatomes

Question 53

Agenesis is:

Answer 53

Lack of kidney development in fetus

Question 54

Bilateral vs. unilateral agenesis:

Answer 54

Bilateral: not compatible with life
Unilateral: functional kidney hypertrophies to compensate

Question 55

Hypoplasia can lead to:

Answer 55

Pediatric ESRD if severe enough

Question 56

Two types of cystic kidney disease and the population they present in:

Answer 56

Autosomal recessive: kids
Autosomal dominant: adults

ADults

Question 57

Genes involved in autosomal dominant cystic kidney diseases:

Answer 57

Chromosome 16 –> PKD1 (85%!)

Chromosome 4 –> PKD2

Question 58

Role of PKD1:

Answer 58

Supports Ca2+ channel in renal epithelium

Question 59

Role of PKD2:

Answer 59

Codes for the Ca2+ channel involved

Question 60

Pathogenesis of cystic kidney disease:

Answer 60

↓ Ca2+ in cell and ↑ cAMP leads to cysts and reduction of kidney function

Question 61

Extra-renal impacts of cystic kidney disease:

Answer 61

Other organs (esp. liver) can have cysts

Question 62

S/s of cystic kidney disease:

Answer 62

↓ GFR
Inability to concentrate urine
HTN
Pain (most common)

Question 63

Dx of cystic kidney disease:

Answer 63

Genetic hx and ultrasonography

Question 64

Tx of cystic kidney disease:

Answer 64

Supportive; BP control and managing renal failure

Question 65

Parts of the kidney affected by renal cell carcinoma:

Answer 65

Cortex

PCT

Question 66

Risk factors for renal cell carcinoma:

Answer 66

Smoking
Obesity
HTN
Family hx

Question 67

S/s of renal cell carcinoma:

Answer 67

Asymptomatic until advanced
CVA tenderness
Hematuria
Palpable mass

Question 68

Tx of renal cell carcinoma:

Answer 68

Nephrectomy

Question 69

Metastases of renal cell carcinoma are:

Answer 69

Resistant to radiation, immunotherapy, chemotherapy

Question 70

Physiological protective measures against renal infection:

Answer 70

Acidic pH
Urea present in urine
Secretions (men: prostatic, women: urethral)
Unidirectional urine flow

Question 71

Most common cause of acute pyelonephritis:

Answer 71

Ascending infection from lower urinary tract

Question 72

Dx of acute pyelonephritis:

Answer 72

WBC casts in urine

Question 73

Tx of acute pyelonephritis:

Answer 73

Prompt abx

Question 74

Pathogenesis of chronic pyelonephritis:

Answer 74

Reflux or obstructive process –> urine stasis

Chronic inflammation causing scarring/nephron damage

Question 75

S/s of chronic pyelonephritis:

Answer 75

Abdominal/flank pain
Fever
Malaise
Anorexia

Question 76

Dx of chronic pyelonephritis:

Answer 76

Renal imaging

Question 77

Tx of chronic pyelonephritis:

Answer 77

Correct the underlying process

Extended abx tx

Question 78

Common causes of obstructive renal disease:

Answer 78

Stones (most common)
Tumors
Prostatic hypertrophy
Strictures of ureters/urethra

Question 79

Sequelae of complete obstruction:

Answer 79

Hydronephrosis
↓ GFR
Ischemic kidney damage d/t ↑ intraluminal pressure
Acute tubular necrosis
Chronic kidney disease

Question 80

Most renal calculi are composed of:

Answer 80

Calcium crystals

Question 81

Non-calcium stones made of:

Answer 81

Uric acid
Struvite
Cystine

Question 82

S/s of renal calculi:

Answer 82

Intense, abrupt, radiating renal colic pain
N/V
Diaphoresis
Hematuria

Question 83

Dx of renal calculi:

Answer 83

CT scan

Question 84

Tx of renal calculi:

Answer 84

Fluids (> 2L/day)
Lithotripsy/endoscopy
Ureteral stenting
Ureteroscopy
Pain medication!!
Dietary changes depending on type of stone

Question 85

Three types of glomerular cells:

Answer 85

Endothelial
Mesangial
Podocytes

Question 86

Primary vs. secondary glomerular disorders:

Answer 86

Primary: only the kidney involved
Secondary: results from other diseases, conditions, meds

Question 87

Secondary glomerular disorders:

Answer 87

Goodpasture syndrome
Systemic lupus erythematosus
Diabetic nephropathy

Question 88

Goodpasture syndrome in the kidney:

Answer 88

Antibodies vs. the glomerular basement membrane (also affects lungs)

Question 89

Systemic lupus erythematosus in the kidney:

Answer 89

Antibody complexes settle into the mesangial region of the glomerulus

Question 90

Diabetic nephropathy pathogenesis:

Answer 90

Glucose binds to protein and complex sticks to endothelial cells, causes damage

Question 91

Three ways to classify glomerular disorders:

Answer 91

Diffuse vs. focal (all vs. some glomeruli)
Global vs. segmental (all vs. some parts of glomeruli)
Membranous vs. sclerotic (thickening of capillaries vs. scarring)

Question 92

Three sites of deposition in glomerular disorders:

Answer 92

Mesangial (SLE)
Subendothelial
Subepithlial (Goodpasture)

Question 93

S/s of glomerular disorders:

Answer 93

Hematuria
Proteinuria** (classical)
Abnormal casts
↓ GFR
Edema
HTN

Question 94

Nephrotic syndrome characterized by:

Answer 94

Protein loss in urine: 3 - 3.5gm in 24 hrs

Question 95

Nephritic syndrome characterized by:

Answer 95

Mild to moderate proteinuria, hematuria, RBC casts (nephrotic syndrome + inflammation)

Question 96

Glomerulonephritis is:

Answer 96

An immune response to a variety of triggers that produces inflammation in the glomeruli

Question 97

Glomerulonephritis is more common in:

Answer 97

Men

Question 98

Pathogenesis of acute glomerulonephritis:

Answer 98

Immune cells are attracted to inflammation in glomeruli, resulting in lysosomal degradation of the basement membrane

Question 99

GFR falls in acute glomerulonephritis due to:

Answer 99

Contraction of the mesangial cells –> decreased area for filtration

Question 100

S/s of acute glomerulonephritis:

Answer 100

Proteinuria
Oliguria
Azotemia
Edema
HTN

Question 101

Tx for acute glomerulonephritis:

Answer 101

Steroids
Plasmapheresis
Dietary, fluid mgmt
HTN mgmt

Question 102

Pathogenesis of postinfectious acute glomerulonephritis:

Answer 102

Infectious agent causes antibody-antigen deposition (IgG) in the glomerulus –> proliferation of mesangial cells –> lesions

Question 103

Infections that lead to postinfectious acute glomerulonephritis:

Answer 103

Impetigo and throat infections with group A β-hemolytic strep

Question 104

Group in which postinfectious acute glomerulonephritis typically is found:

Answer 104

Children in developing countries

Question 105

S/s of postinfectious acute glomerulonephritis:

Answer 105

Smoky or coffee-colored urine

Question 106

Pathogenesis of IgA nephropathy (Berger disease):

Answer 106

Post-URI or GI viral infection, IgA complex deposition in mesangial cells –> mesangial injury

Question 107

S/s of IgA nephropathy (Berger disease):

Answer 107

Proteinuria

Hematuria in 1-2 days

Question 108

Typically IgA nephropathy (Berger disease) is seen in:

Answer 108

Adults

Question 109

Difference between post-infectious and IgA nephropathy (Berger disease) glomerulonephritis:

Answer 109

Post-infectious: IgG, will see edema and HTN

Berger: IgA, NO edema/HTN

Question 110

Pathogenesis of chronic glomerulonephritis:

Answer 110

Progressive course of proliferative, membranous lesions (glomeruli replaced with collagen)
Sclerosis/fibrosis of kidney

Question 111

S/s of chronic glomerulonephritis:

Answer 111

Proteinuria
-/+ hematuria
Slowly declining renal fxn

Question 112

Tx of chronic glomerulonephritis:

Answer 112

Supportive interventions (fluid mgmt, etc) until dialysis/transplant necessary

Question 113

Pathogenesis of nephrotic syndrome:

Answer 113

Increased glomerular permeability to proteins; proteinuria leads to hypoalbuminemia; edema occurs d/t ↓ osmotic pressure in blood

Question 114

Causes of nephrotic syndrome:

Answer 114

Minimal change disease
SLE
DM

Question 115

S/s of nephrotic syndrome:

Answer 115

Proteinuria
Edema** (most common)
HLD, hypercoag d/t ↑ liver fxn (due to ↓ albumin)

Question 116

Tx of nephrotic syndrome:

Answer 116

Diuretics
Lipid-lowering agents
AntiHTNs
Immunosuppression/modulation

Question 117

Pathogenesis of minimal change disease:

Answer 117

Triggered by allergic or immune condition

Foot processes of glomerular podocytes fuse together; decreased production of basement membrane anions

Question 118

S/s of minimal change disease:

Answer 118

Edema
Nephrotic levels of proteinuria
Hypoalbuminemia

Question 119

Tx of minimal change disease:

Answer 119

Corticosteroids

Question 120

Acute renal failure is:

Answer 120

Sudden reduction in kidney function

Question 121

ARF causes:

Answer 121

Fluid/lyte/acid-base imbalances
Retention of waste products
↑ serum Cr
↓ GFR

Question 122

Causes of pre- vs. intra- vs. post-renal:

Answer 122

Pre: ↓ renal perfusion
Intra: parenchymal renal disease
Post: obstruction

Question 123

How can BUN/Cr be used to dx cause of ARF?

Answer 123

Only if BUN is elevated - ratio will determine location of cause

Question 124

Normal BUN/Cr ratio:

Answer 124

10-20

Question 125

Normal BUN:

Answer 125

8-10 mg/dl

Question 126

Normal Cr:

Answer 126

0.6 - 1.2 mg/dl

Question 127

BUN/Cr ratio > 20 indicates:

Answer 127

Pre-renal ARF; urea has more time to be reabsorbed

Question 128

Bun/Cr ratio < 10 indicates:

Answer 128

Intra-renal ARF; tubules failing, reabsorbing less urea

Question 129

Bun/Cr ratio 10-20 indicates:

Answer 129

Post-renal ARF

Question 130

BUN and creatinine are each handled in the nephron in this fashion:

Answer 130

BUN: filtered in glomerulus, reabsorbed by tubule
Cr: filtered in glomerulus, secreted in filtrate

Question 131

Causes of prerenal ARF:

Answer 131

Any sudden/severe drop in BP or interruption of blood flow

Hypovolemia, HoTN, heart failure
Renal artery obstruction
Fever/vomiting/diarrhea
Burns
Diuretics, edema, ascites

Question 132

Drugs that can cause prerenal ARF:

Answer 132

ACE inhibitors, angiotensin II blockers, NSAIDs

Question 133

Low GFR in prerenal ARF leads to:

Answer 133

Oliguria
High urine SG/osmolarity
Low urine Na+
Azotemia

Question 134

Prolonged prerenal ARF leads to:

Answer 134

Acute tubular necrosis

Question 135

Tx of prerenal ARF:

Answer 135

Improve renal perfusion via fluid replacement or dialysis

Question 136

Pathogenesis of post-renal ARF:

Answer 136

Obstruction distal to the kidney causes elevated pressure all the way back to the Bowman capsule which impairs glomerular filtration

Question 137

Prolonged post-renal ARF leads to:

Answer 137

Acute tubular necrosis and irreversible kidney damage

Question 138

Early phase of post-renal ARF:

Answer 138

Reflex adaptation to maintain GFR: afferent arteriole dilation
Lasts 12-24 hours

Question 139

Late phase of post-renal ARF:

Answer 139

Afferent arteriole dilation ceases after 12-24 hours
Renal perfusion, glomerular blood flow, and GFR drop
Oliguria/anuria
Ischemia/nephron loss

Question 140

Recovery phase of post-renal ARF:

Answer 140

Pre-renal vessels relax
Perfusion restored
GFR increases in surviving nephrons
Dilation may be permanent!

Question 141

Causes of acute tubular necrosis:

Answer 141

Nephrotoxic insults (contrast media)
Ischemic insults (sepsis)

Question 142

Vascular pathogenesis of intrarenal ARF:

Answer 142

Renal blood flow decreases –> hypoxia, vasoconstriction

Question 143

Tubular pathogenesis of intrarenal ARF:

Answer 143

Inflammation/reperfusion injury –> casts, obstruction of flow, tubular backleak

Question 144

Three phases of ATN:

Answer 144

Prodromal phase
Oliguric phase
Post-oliguric phase

Question 145

Prodromal phase of ATN:

Answer 145

Insult to the kidney has occured

Question 146

Oliguric phase of ATN:

Answer 146

~1-2 weeks (up to 8 weeks)
UOP 50-400 ml/day
Progressive uremia
Decreased GFR/hypervolemia

Question 147

Post-oliguric phase of ATN:

Answer 147

Diuresis
Impaired tubular function
Azotemia
Fluid volume deficit until recovery
2-10 days, up to 1 year

Question 148

Prognosis for acute renal failure:

Answer 148

Good in otherwise healthy patients if underlying issue is corrected

Question 149

Predictors of mortality from ARF:

Answer 149

Oliguria, severe illness, MI, stroke, seizure, immunosuppression, mechanical ventilation

Question 150

Progression of chronic renal failure:

Answer 150

Chronic kidney disease –> chronic renal failure –> end-stage renal disease

Question 151

CRF stage which requires dialysis:

Answer 151

ESRD

Question 152

Comorbidities linked to CRF:

Answer 152

HTN, DM

Question 153

Definition of CRF:

Answer 153

Kidney damage/impairment of 3 months or more

GFR < 60 for 3+ months

Question 154

Kidneys compensate until this % of damage:

Answer 154

75-80%

Question 155

Stage 1/2 CRF:

Answer 155

Minimizing risk factors

Question 156

Stage 3 CRF:

Answer 156

Symptoms appear, tx may be needed

Question 157

Stage 4 CRF:

Answer 157

Plan for dialysis/transplant

Question 158

Stage 5 CRF:

Answer 158

Renal replacement tx needed for survival

Question 159

Role of angiotensin II in renal injury:

Answer 159

Vasoconstriction increases GFR

Question 160

Pathogenesis of CRF:

Answer 160

Renal injury –> loss of nephrons, vasoconstriction from angiotensin II

Glomerular capillary hypertension, over time, leads to increased permeability/filtration

Proteinuria, increased protein reabsorption

Tubular/interstitial inflammation, fibrosis, scarring

Creates systemic HTN which worsens glomerular capillary HTN

Question 161

Risk factors for CRF:

Answer 161

DM
HTN
Pyelonephritis (recurrent)
Glomerulonephritis
Polycystic kidney disease
Family hx
Toxin exposure
Age > 65

Question 162

Management of CRF:

Answer 162

BG control
ACEIs or ARBs to reduce proteinuria
Management of HTN

Question 163

Management of metabolic acidosis:

Answer 163

Mild (7.3 to 7.35) no tx

< 7.3 may take NaHCO3

Question 164

CV effects of CRF:

Answer 164

Hypervolemia/HTN
Atherosclerosis
Heightened RAAS/SNS activity

Question 165

Metabolic effects of CRF:

Answer 165

Uremic syndrome/impaired healing
Hyperkalemia
Metabolic acidosis

Question 166

Electrolyte imbalances in CRF:

Answer 166

Hyperkalemia
Hypermagnesemia
Hyperphosphatemia

Question 167

Bone/mineral disorders from CRF:

Answer 167

Elevated phos/PTH causes altered bone metabolism

Kidneys unable to reabsorb calcium

Question 168

Hematological effects of CRF:

Answer 168

Lack of EPO –> anemia
Uremia shortens RBC lifespan
Blunted immune response

Question 169

Primary reason to initiate dialysis in CRF:

Answer 169

Uremia or hyperkalemia unresponsive to other txs

Question 170

Pathogenesis of renal-related HTN:

Answer 170

Renin release by injured kidney -or- hypervolemia due to renal mishandling of sodium

Question 171

Pulmonary impacts of CRF:

Answer 171

Chronic pulmonary edema

Question 172

Micturition mediated by:

Answer 172

Pons
Gravity/pressure
Peristalsis
CNS

Question 173

Pons’ role in micturition:

Answer 173

Relaxation of internal sphincter

Contraction of bladder

Question 174

Cerebral cortex’s role in micturition:

Answer 174

Inhibition via conscious control of external sphincter

Question 175

ANS role in micturition:

Answer 175

SNS: L1-2 allow relaxation and filling
PSNS: S2-4 cause bladder contraction, relaxation of internal sphincter

Question 176

Incontinence is normal when:

Answer 176

Never!

Question 177

Urge incontinence is:

Answer 177

Involuntary leakage along with/after feeling the need to void

Question 178

Causes of urge incontinence:

Answer 178

Bladder infection
Radiation tx
Tumors
Stones
CNS dmg
Idiopathic

Question 179

Causes of stress incontinence:

Answer 179

Weakening of pelvic muscles or urethral sphincter deficiency

Question 180

Causes of overflow incontinence:

Answer 180

Obstruction of urethra

Under/inactive detrusor

Question 181

Types of enuresis:

Answer 181

Primary nocturnal enuresis
Secondary enuresis: after 6 mo dry
Monosymptomatic nocturnal enuresis: no other signs of lower UTI malfunction
Nonmonosymptomatic nocturnal enuresis: urgency/frequency/daytime incontinence as well

Question 182

Pathogenesis of enuresis:

Answer 182

ADH deficiency
Overactivity of destrusor
Immature arousal mechanisms

Question 183

Manifestations of vesicoureteral reflux:

Answer 183

Recurrent UTI
Voiding dysfunction
Renal insufficiency
Hypertension in children

Question 184

Ureterocele is:

Answer 184

Cystic dilation at distal end of ureter

Question 185

Manifestations of ureteroceles:

Answer 185

Hydronephrosis
UTIs
Voiding dysfunction
Hematuria
Urosepsis
Failure to thrive

Question 186

Tx of ureterocele:

Answer 186

Surgical intervention

Question 187

Most cases of cystitis are from:

Answer 187

Infection originating in urethra

Question 188

Common minerals that make urinary tract stones:

Answer 188

Calcium
Oxalate
Phosphate
Uric acid

Question 189

Effect of dietary calcium on kidney stones:

Answer 189

Prevents them via binding of oxalate

Question 190

Endocrine dysfunction associated with kidney stones:

Answer 190

Hyperparathyroidism

Question 191

Effect of hydronephrosis on kidney structure:

Answer 191

Dilation of pelvis/calyces

Thinning of renal parenchyma