4 Clinical Evaluation of Renal Function

Question 1

Kidney

• Roles of the kidney
• Most important parameter in assessing kidney function & kidney disease progression

Answer 1

• Roles of the kidney
  
  • Maintain homeostasis & a constant extracellular environment
    
    • Excrete metabolic waste
    • Reabsorb & secrete in tubules
    • Concentrate, dilute, & acidify urine
  • Secrete hormones
• Most important parameter in assessing kidney function & kidney disease progression
  
  • Glomerular filtration rate (GFR): renal ecretory capacity

Question 2

GFR

• General
• Most common methods to estimate GFR
• Other markers of kidney function

Answer 2

• General
  
  • Most important parameter in clinically evalutating kidney funciton
  • Overall index of kidney function
  • = sum of filtration rates in all functioning nephrons
  • Measure of excretory function
  • Used w/ H&P, urinalysis, imaging, & biopsy to evaluate disease etiology
• Most common methods to estimate GFR
  
  • Serum creatinine & estimation equations
    
    • Most common
    • Rely upon creatinine
  • Creatinine clearance
• Other markers of kidney function
  
  • Blood urea nitrogen (BUN)
  • Serum cystatin C (only in reserach)

Question 3

Normal GFR

• How much plasma glomeruli filter
• GFR depends on…
• Normal GFR value
• GFR vs. age
• GFR is corrected for…
• Significance of decreased GFR

Answer 3

• Glomeruli filter ~125 ml/min of plasma
• GFR depends on age, sex, & body size
• Normal GFR = 130 ml/min in men & 120 ml/min in women
• GFR declines ~1% per year above 40yo
• GFR is corrected for body surface area (important in children)
• Significance of decreased GFR
  
  • Acute or chronic kidney disease
  • Level of GFR assesses disease severity
  • Not an exact correlation b/c kidney adapts to nephron loss by compensatory hyperfiltration in remaining normal nephrons

Question 4

Assessing GFR

• Measured directly vs. estimated
• Clearance
• Amt of plasma filtered by glomeruli
• Substance chosen for clearance measurement in clinical practice
• Inulin characteristics
• Measurement of GFR using inulin clearance

Answer 4

• Measured directly vs. estimated
  
  • GFR can’t be measured directly but can be estimated from clearance of an ideal filtration marker
• Clearance
  
  • Volume of plasma cleared entirely of a substane / time
  • Clearance = (U * V) / P
• Amt of plasma filtered by glomeruli
  
  • Estimated by the clearance of ideal markers like inulin
• Substance chosen for clearance measurement in clinical practice
  
  • Endogenous creatinine
• Inulin characteristics
  
  • Neither absorbed nor secreted by renal tubules
  • Freely filterable across glomerular membranes
  • Not metabolized or produced by kidneys
• Measurement of GFR using inulin clearance
  
  • GFR is measured by determining plasma conc & excretion of inulin
  • Amt of inulin excreted = amt filtered
  • Inulin clearance determines amt of plasma filtered by glomreuli (GFR)

Question 5

Assessing GFR w/ inulin clearance

• Filterability of inulin
• Equation derivation
• Equation
• How Cin is measured
• Criteria for the clerance of a substance to equal GFR

Answer 5

• Inulin is freely filterable
  
  • Amt excreted = amt filtered
  • Conc in filtrate = conc in plasma
• Equation derivation
  
  • Filtered amt of inulin = GFR * plasma inulin conc
  • Excreted amt of inulin = urine inulin conc * urine volume
    
    • Volume units: L / min
  • Filtered amt of inulin = excreted amt of inulin
  • GFR * plasma inulin conc = urine inulin conc * urine volume
• Equation
  
  • GFR = [urine inulin conc (Uin) * urine volume (V)] / plasma inulin conc (Pin)
  • GFR = inulin clearance (Cin)
• How Cin is measured
  
  • Infuse inulin IV to achieve steady state blood level
  • Measure plasma inulin, urine inulin, & urine volume simultaneously
• Criteria for the clerance of a substance to equal GFR
  
  • Substance must be freely filterable at the glomerulus
  • Substance can/t be secreted or reabsorbed in tubules
  • Substance must be in steady state concs in the blood w/ no extrarenal route of excretion

Question 6

Measurement of GFR in clinical practice

• Inulin vs. creatinine
• Creatinine characteristics
• Methods to assess GFR using creatinine

Answer 6

• Inulin vs. creatinine: in clinical practice…
  
  • Not practical to use inulin infusion to calc Cin to assess GFR
  • Assess GFR w/ endogenous creatinine
• Creatinine characteristics
  
  • Endogenously produced from the metabolism of creatine & phosphocreatine in skeletal muscle
  • Excreted by kidneys
  • Freely filtered across the glomerulus
  • Neither reabsorbed nor metabolized by the kidney
  • Amt filtered = amt excreted when renal function is stable (steady state)
• Methods to assess GFR using creatinine
  
  • Calc GFR w/ creatinine clearance
  • Measure serum creatinine
  • Estimate equations using serum creatinine to estimate GFR

Question 7

Steady state

• Achieved when…
• Creatinine in steady state

Answer 7

• Achieved when…
  
  • Ingested amt + produced amt = excreted amt + consumed amt
• Creatinine in steady state
  
  • Filtered creatinine = GFR * serum creatinine conc (Pcr)
  • Excreted creatinine = urine creatinine conc (Ucr) * urine flow rate (V)
    
    • Constant in absence of acute kidney failure b/c muscle mass remains relatively constant
    • V units: L / min
  • Filtered creatinine = excreted creatinine
• Take-home about steady state
  
  • Methods that evaluate GFR (Cr clearance, estimatoin equations) can only be used when Pcr is stable (in steady state), as in pts w/ CKD or stable normal Cr

Question 8

Measurement of creatinine clearance

• Equation derivation
• Equation
• Technique

Answer 8

• Equation derivation
  
  • Amt excreted = amt filtered
  • Creatinine is freely filterable so filtrate conc = plasma conc in steady state
  • Filtered Cr = GFR * plasma Cr conc (Pcr)
  • Excreted Cr = urine Cr (Ucr) * urine volume (V)
  • Filtered Cr = excreted Cr
  • CrCl * Pcr = Ucr * V
• Equation
  
  • CrCl = GFR = (Ucr * V) / Pcr
  • Units: ml / min
• Technique
  
  • 24 hr urine collection
  • Measure Ucr & Pcr
  • Normalized to BSA of 1.73 m² (esp for children)

Question 9

Example

• 60 kg women
• Pcr = 1.2 mg/dL
• Ucr = 100 mg/dL
• V = 1.2 L/day
• Calculate CrCl

Answer 9

• V
  
  • = 1.2 L/day
  • = 1.2 L/day * 1000 ml/L * 1/1440 day/min
  • = 0.83 ml/min
• CrCl
  
  • = (Ucr * V) / Pcr
  • = (100 mg/dL * 0.83 ml/min) / 1.2 mg/dL
  • = 70 ml/min
• CrCl = 70 ml/min

Question 10

Limitations of creatinine clearance

• (1)
• How (1) is checked
• Muscle mass in dif pt populations
• (2)

Answer 10

• (1) Incomplete urine collection
  
  • Difficult to obtain a complete 24 hr urine, esp in children
    
    • Pts forget, collect too much, etc.
  • Impossible to obtain in pts w/ incontinence or diarrhea
• Adequacy of a 24 hr urine collection is checked by comparing the measured amt of Cr excretion to the expected amt based on weight, gender, & age
  
  • Women: 15-25 mg/kg/d
  • Men: 20-30 mg/kg/day
  • Elderly (muscle wasting): 10 mg/kg/d
  • Children: 14.7 + (0.45 * age) mg/kg/d
• Muscle mass in dif pt populations
  
  • Muscle mass & Cr production/excretion decreases w/ age > 40yo
  • Muslce mass decreases in pts who are bed-ridden, physically inactive, amputed, or on chronic corticosteroids
• (2) Increasing Cr secretion
  
  • Decrease GFR –> increase Pcr + enhance tubular secretion
  • Advanced CKD: Cr excreted > Cr filtered –> overestimate GFR

Question 11

Measurement of serum creatinine

• Cr characteristics
• GFR vs. Pcr
• Pcr vs. kidney function
• Normal Pcr
• Pcr is affected by…

Answer 11

• Cr characteristics
  
  • Endogenously produced from the metabolism of Cr in skeletal muscle
  • Excreted by kidneys
  • Freely filtered across the glomerulus
  • Neither reabsorbed nor metabolized by the kidney
• GFR vs. Pcr
  
  • GFR = CrCl = (Ucr * V) / Pcr
  • Decrease GFR –> increase Pcr curvilinearly
• Pcr vs. kidney function
  
  • Higher Pcr –> worse kidney function
• Normal Pcr
  
  • Adult: 0.6 - 1.2 mg/dl
  • Children: lower
• Pcr is affected by both Cr production & clearance
  
  • Muscle mass
  • Diet
  • Creatine supplements
  • Malnutrition
  • Amputations

Question 12

Limitations of serum Cr measurement

Answer 12

• Cr production differs b/n pts depending on muscle mass
  
  • More muscle mass –> higher Cr
  • Less muscle mass –> lower Cr
  • Amputation, muscle wasting, malnutrition –> low muscle mass –> Pcr appear normal but could represent low GFR
• Glomerular injury may not initially change GFR or Pcr
  
  • If this is suspected, look for other signs of kidney disease (ex. protein or blood in urine, abnormal renal imaging)

Question 13

Estimation equations based on Pcr

• Why used
• Cockroft-Gault formula
• MDRD formula
• Ex. 23yo white man, 80kg, Cr 1.2 mg/dl

Answer 13

• Why used
  
  • Limitations of Pcr due to variatoins in muscle mass
  • Alternatives to 24 hr urine collection
  • Equations take into account variables like age, sex, race, & body size (predictors of muscle mass)
• Cockroft-Gault formula
  
  • GFR = [(140 - age) * (weight in kg)] / (72 * P_Cr)
  • For older drug dosing​ guidelines
  • Based on demographics, serum Cr, & lean body weight
  • Multiply by 0.85 for women b/c they have less muscle mass than men
  • Obese pts: weight can over-estimate Cr cleraance, so use lean body weight
• MDRD (modificaiton of diet in renal disease) formula
  
  • Most commonly used in clinical practice
  • Effect of dietery protein restriction & BP control on renal disease progression –> equation that predicts GFR from Pcr
• Ex. 23yo white man, 80kg, Cr 1.2 mg/dl
  
  • GFR = 80 ml/min

Question 14

Limitations of estimation equations

• MDRD
• Cockcroft-Gault
• Validation in clinical populations
• Newer methods proposed but not widely used

Answer 14

• MDRD
  
  • Tends to underestimate GFR when r is normal or near-normal
  • Why labs report GFR > 60 ml/min when it’s expected to be close to nromal (80 ml/min)
• Cockcroft-Gault
  
  • Tends to overestimate GFR due to tubular secretion
• Validation in clinical populations: formulas haven’t been validated in…
  
  • Children
  • Pregnant women
    Certain ethnic groups
  • Pts w/ unusual muscle mass, body habitus, & weight
• Newer methods proposed but not widely used
  
  • CKD-EPI
  • Blood test Cystatin C

Question 15

Example

• 23yo female, 55 kg, 24 hr urine collection
• V = 2000 ml / 24 hr
• Ucr = 50 mg/dl
• Pcr = 0.6 mg/dl
• CrCl?
• Is kidney function normal?

Answer 15

• CrCl = (50 mg/dl * 2000 ml / 1440 min) / 0.6 mg/dl = 115 ml/min
• Normal renal function
  
  • Normal = 110 ml/min

Question 16

Example

• 23yo female, 55 kg, 24 hr urine collection
• V = 2000 ml / 24 hr
• Ucr = 50 mg/dl
• Pcr = 1.2 mg/dl
• CrCl?
• Is kidney function normal?

Answer 16

• CrCl = (50 mg/dl * 2000 ml / 1440 min) / 1.2 mg/dl = 58 ml/min
• Moderate decrease in kidney function
  
  • Normal = 110 ml/min
  • Even though lab reports Pcr of 1.2 mg/dl as normal, level doesn’t represent normal kidny function

Question 17

Importance of adequate urine collection

• Ex. if 23yo woman collects urine for 24 hr but misses several voids
• Inadequate & incomplete collection
• Regardless of chronic changes in renal function, Cr excretion…

Answer 17

• Ex. if 23yo woman collects urine for 24 hr but misses several voids
  
  • Measured Cr excretion = 500 mg/d
  • Expected Cr excretion = 55 kg * 20 mg/kg = 1100 mg/d
• Inadequate & incomplete collection
  
  • Gives false determination of GFR
• Regardless of chronic changes in renal function, Cr excretion…
  
  • Is relatively stable over time unless muscle mass changes
  • Decrease GFR –> decrease Cr filtration & excretion –> increase Pcr –> brings total Cr filtration back to normal –> re-establishes balance b/n produciton & excretoin (steady state)

Question 18

Example

• 23yo 80 kg man w/ more muscle mass than a woman
• Pcr = 1.2 mg/dl
• Ucr = 110 mg/dl (compared to a woman: 50 mg/dl)
• V = 2000 ml / 1440 min
• CrCl?
• Is kidney function normal?

Answer 18

• CrCl = (110 mg/dl * 2000 ml / 1440 min) / 1.2 mg/dl = 126 ml/min
• Normal kidney function
  
  • Ucr is a reflection of muscle mass (muscle breakdown product)
    
    • More muscle –> more urinary Cr
  • “Normal” Pcr range of 0.6 - 1.2 mg/dl only reflects normal GFR in light of pt muscle mass

Question 19

Summary of measurement of GFR in clinical practice

• Cr clearance
  
  • Method
  • Cons
• Pcr
  
  • Method
  • Pros
  • Cons
• Estimated GFR using MDRD
  
  • Method
  • Pros
• Estimated GFR using Cockcroft-Gault
  
  • Method
  • Pros
  • Cons

Answer 19

• Cr clearance
  
  • Method
    
    • Urine 24 hr collection of Cr w/ simulatneous Pcr measurement
  • Cons
    
    • Urine collection can be unreliable
      
      • Inadequate or over-collection –> false results
    • Can overestimate GFR secondary to increased creatinine secretion in advanced CKD
• Pcr
  
  • Method
    
    • Simple blood draw
  • Pros
    
    • Easy to obtain
  • Cons
    
    • Varies w/ muscle mass & is inaccurate in extreme muscle mass
    • Affected by some drugs
• Estimated GFR using MDRD
  
  • Method
    
    • Simple blood draw
  • Pros
    
    • Avoids urine 24 hr collection
    • Better estimation of GFR than Pcr alone
    • Commonly reported on clinical lab results
• Estimated GFR using Cockcroft-Gault
  
  • Method
    
    • Simple blood draw
  • Pros
    
    • Avoids urine 24 hr collection
    • Commonly used in prescribing info for dose adjustments
  • Cons
    
    • Tends to over-estimate GFR

Question 20

Blood urea nitrogen (BUN)

• Normal values
• Use
• BUN vs. Cr for measuring GFR
• BUN assesses…
• Azotemia

Answer 20

• Normal values
  
  • 7-21 mg/dl
• Use
  
  • Marker of kidney function
  • Kidney failure –> increased BUN
• BUN vs. Cr for measuring GFR
  
  • BUN is a worse marker b/c it’s also dependent on…
    
    • Protein intake
      
      • Increase intake –> increase BUN
    • Catabolism
      
      • Increase catabolism –> increase BUN
    • Liver function
      
      • Cirrhosis –> decrease BUN
    • Volume status
      
      • Volume depletion –> low urine flow rates –> increase urea reabsorption along renal tubules
  • Urea clearance = 60% of Cr or inulin clearance
• BUN assesses…
  
  • GFR
  • Protein intake
  • Presence of catabolism
  • Volume status
  • Renal perfusion
• Azotemia
  
  • Elevation of BUN & Pcr

Question 21

Acute kidney injury (AKI)

• AKI definition
• GFR in AKI
• Cr in AKI
• CrCl in AKI

Answer 21

• AKI definition
  
  • Loss of renal function over hours to days
  • Azotemia: retention of nitrogenous waste broducts in blood
    
    • Increased BUN & Pcr
• GFR in AKI: decreased due to…
  
  • Decreased Cr excretion
  • Increased Pcr & BUN
  • Pt not in steady state
• Cr in AKI: decreased
  
  • Production stays constant
  • Pcr increases due to muscle mass & muscle break down (1 mg/dl / day)
• CrCl in AKI: not used
  
  • 24 hr urine collection not used
    
    • CrCl isn’t a reflection of GFR b/c the pt isn’t in steady state
    • Pcr is increasing daily, which is a variable in CrCl/GFR estimation
  • Formulas to determine CrCl also don’t apply

Question 22

Example

• 22yo 80kg male involved in a car accident
• –> ICu w/ HoTN & multiple injuries
• Urine output = 10 cc / 4 hr
• Pcr = 1.2 mg/dl
• Urine exam: tubular cells & granular casts
• BUN & Cr: increase daily, keep ~10-15 : 1 ratio consistent
• CrCl?
• Kidney function assessment

Answer 22

• Can’t calculate CrCl / GFR b/c not in steady state
  
  • Increasing BUN & Pcr –> formulas for CrCl aren’t applicable
• Kidney function assessment
  
  • Urine output of 10 cc / 4 hr = absence of urine output = kidney failure
  • BUN : Cr :: 10-15 : 1 –> intrinsic renal disease
    
    • Acute tubular necrosis from low BP secondary to bleeding from the accident
    • Helps determine locaiton of kidney problem (pre-kidney, intrinsic, or obstruction)

Question 23

Tools to evaluate kidney abnormalities

Answer 23

• H&P
• Assessment of GFR
  
  • Chronic renal failure: calc GFR from Pcr if chronic
  • Acute renal failure: calc pattern of increase in BUN & Cr
• Urinalysis
  
  • Include urine sediment
• Imaging
• Kidney biopsy (sometimes)

Question 24

Urinalysis: specific gravity

• Specific gravity
  
  • Definition
  • Range
  • Increased by…
  • Determined by…
  • Dependent on…
• Osmolality
  
  • Dependent on…
• Specific gravity vs. osmolality
  
  • Dilute urine
  • Concentrated urine

Answer 24

• Specific gravity
  
  • Weight of urine compared to distilled water
  • Range: 50-1200 mOsm/kg
  • Increased by glucosuria & radiographic contrast excreted in urine
  • Determined by hydrometer, refractometer, & dipstick
  • Dependent on the number, size, & density of particles in urine
• Osmolality
  
  • Dependent only on the number of particles in urine
• Specific gravity vs. osmolality: roughly correlate
  
  • Dilute urine: osmolality = 50 mOsm/kg –> specific gravity = 1.001
  • Concentrated urine: osmolality = 800 mOsm/kg –> specific gravity = 1.02

Question 25

Urinalysis: chemical composition by dipstick

• Urine pH
  
  • Range
  • Useful in evaluating…
  • UTIs
• Blood
  
  • Descrimination
  • Location
  • Problem indicated
• Glucose
  
  • Normally
  • Some renal diseases
• Ketones
  
  • May be present w/…
• Urobilinogen
  
  • Produced in…
  • Some…
  • Obstructive jaundice
  • Non-obstructive jaundice
• Bilirubin
  
  • Urine obtains…
• Nitrite
  
  • Screening test
  • Won’t detect…
  • False negatives
• Leukocytes
  
  • Threshold
  • False negatives

Answer 25

• Urine pH
  
  • Range: 4.5 - 8.0
  • Useful in evaluating pts w/ renal stone disease
    
    • Uric acid stones may be associated w/ a low urine pH
    • Ca phosphate stones may be associated w/ a high urine pH
  • UTIs w/ urea splitting organisms –> high (alkaline) pH
• Blood
  
  • Doesn’t discriminate b/n RBCs, hemoglobinuria, & myoglobinuria
    
    • Microscopic exam determines if RBCs are present
  • May be from any site (kidney, ureter, bladder, urethra, prostate/vagina)
  • RBCs + proteinuria –> intrinsic renal problem
• Glucose
  
  • Normally: all glucose is freely filtered at the glomerulus & reabsorbed
  • Some renal diseases: low glucose absorption threshold –> glucosuria at normal serum glucose levels
• Ketones
  
  • May be present w/ diabetic ketoacidosis or starvation
• Urobilinogen
  
  • Produced in gut from metabolized bilirubin
  • Some is reabsorbed & excreted in urine
  • Obstructive jaundice: bilirubin doesn’t reach gut –> decreased urobilinogen
  • Non-obstructive jaundice: increased urobilinogen
• Bilirubin
  
  • Urine only obtains unconjugated bilirubin
• Nitrite
  
  • Screening test for gram(-) bacteria that convert urinary nitrate –> nitrite
  • Won’t detect infections due to enterococcus or non-nitrite-producing organisms
  • Ascorbate –> false negatives
• Leukocytes
  
  • Threshold: 5-15 WBC/HPF
  • False negatives: glycosuria, high specific gravity, cephalexin, tetracycline therapy

Question 26

Urinalysis: chemical composition by dipstick: proteinuria

• Normally
• Protein confirmation & quantificaiton
• Estimating daily protein excretion
• Abnormal proteinuria may result from…
• Macroalbuminuria
• Microalbuminuria
• Nephrotic range proteinuria

Answer 26

• Normally
  
  • No protein detected (< 100 mg/d)
  • High amts –> glomerular (not tubular) disease
• Protein confirmation & quantificaiton
  
  • Protein presence confirmed by adding 20% sulfasalicyclic acid to urine –> precipitates protein –> makes urine cloudy
  • Protein amt quanitifed w/ 24 hr urine collection + Cr measurement
• Estimating daily protein excretion
  
  • Estimate from urine albumin or ptorein & creatinine in a spot urine
  • Albumin or protein conc / Pcr = protein : Cr ratio to estimate 24 hr protein excretion
• Abnormal proteinuria may result from…
  
  • Leaking of protein through an abnromal BM (primarily albumin)
  • Leaking of protein from tubules
    
    • Uncommon, seen in Blakan nephropahty & other tubulointerstitial nephritis
  • Overlow protein
    
    • In multiple myeloma (Bence-Jones protein) or other disorders w/ increased Ig production
• Macroalbuminuria
  
  • Albuminuria > 300 mg/d
  • Detected by dipstick
• Microalbuminuria
  
  • Albuminuria 30 - 300 mg/d
  • Measured to detect early diabetic nephropathy
• Nephrotic range proteinuria
  
  • > 3 g/d of proteinuria
  • Seen in glomerulonephritis

Question 27

Microscopic examination of urine

• Use
• Bland sediment
• Acute tubular necrosis sediment
• Nephritic sediment
• Nephrotic sediment
• Pyelonpehritis & acute interstitial nephritis
• Chronic renal failure
• Telescoped urine

Answer 27

• Use
  
  • Assessing dif possible causes of renal failure
  • Diagnosing UTIs & hematuria
• Bland sediment
  
  • Normal urine w/ few cells/casts
  • Only casts that may be seen: hyaline
    
    • May form in increased numbers w/ fever & exercise
  • Pre-renal azotemia or obstruction: few formed elements in urine
• Acute tubular necrosis sediment
  
  • Most common cause of acute renal failure
  • Has tubular cells, granular debris, & pigmented granulra casts
• Nephritic sediment
  
  • Has dysmorphic RBCs & acanthocytes w/ granular & RBC casts
    
    • RBC casts indicate glomerular hematuria
  • Present in proliferative glomerulonephritis & renal vasculitis
• Nephrotic sediment
  
  • Has 4+ protein, fatty casts, & oval fat bodies (lipid filled cells)
  • Seen in…
    
    • Glomerulonephritis w/ nephrotic range proteinuria
    • Non-proliferative glomerulonephritis w/ heavy proteinuria
• Pyelonpehritis & acute interstitial nephritis
  
  • Has many WBCs & WBC casts
  • (+) culture for pyelonephritis (>10⁵ organisms) but not acute interstitial nephritis
• Chronic renal failure
  
  • Has broad casts w/ dilated tubules in functioning nephrons
• Telescoped urine
  
  • Has chronicity (broad casts) & more acute disease (granular casts & RBC casts)
  • Characteristic bu tnot specific for rapidly progressive glomerulonephritis

Question 28

Crystals found in urine

• Calcium oxalate
• Uric acid crystals
• Cystine crystals
• Triple (magnesium ammonium) phosphate crystals
• Calcium carbonate crystals

Answer 28

• Calcium oxalate
  
  • Found in acid urine
  • May occur w/o disease
  • Look like envelopes
  • Ethylene glycol overdose –> increased Ca oxalate crystalluria
• Uric acid crystals
  
  • Found in acid urine
  • Varied appearance
• Cystine crystals
  
  • Found in acid urine
  • Hexagons
  • Always pathologic
  • Presence confirmed by nitroprusside test
• Triple (magnesium ammonium) phosphate crystals
  
  • Found in alkaline urine
  • Associated w/ urea spliting bacteruria & infection
  • Look like coffins
• Calcium carbonate crystals
  
  • Found in alkaline urine
  • Granular masses or dumbbells

Question 29

Imaging techniques

• Renal ultrasound
• Computer assisted tomography & magnetic resonance imaging
• Renal arteriogram
• Intravenous pyelogram
• Radioisotopic imaging

Answer 29

• Renal ultrasound
  
  • Good for renal size, renal masses, echogenicity, renal cysts, & obstruction
  • Safe
  • Doesn’t involve IV dye
  • Doppler imaging of renal vessels can assess renal artery stenosis or thrombosis
• Computer assisted tomography & magnetic resonance imaging
  
  • Evaluate renal masses & copmlex cyst & renal blood vessels
  • Seldom first imaging study ordered
• Renal arteriogram
  
  • Used to confirm renal artery stenosis or complete the evaluation of a renal tumor
  • Last step in evaluating a potential living related renal transplant donor
• Intravenous pyelogram
  
  • Not commonly used
• Radioisotopic imaging
  
  • Evaluates the function of the kidney
  • useful in diagnosing renal artery stenosis when enalaprilat is used

Question 30

Example

• 40yo 50kg woman w/ Lupus
• H: swelling of legs, fatigue
• P: lower extremity edema
• Urinalysis: 4+ protein & 2+ blood (normal is 0)
• Ucr = 100 mg/dl, Pcr = 1 mg/dl, BUN = 10 mg/dl
• 24 hr urine collection: 5 g/day proteinuria, 1000 mg/day total urinary Cr
• CrCl
• Kidney function

Answer 30

• CrCl
  
  • (100 mg/dl * 1000 mg / 1440 min) / 1 mg/dl = 69 ml/min
• Kidney funciton: abnormal
  
  • Decreased GFR –> early CKD
  • Heavy protein leak
  • Blood in urine –> inflammation

Question 31

Example

• 40yo 72kg male
• Gross hematuria
• FH: father died of kidney failure
• P: proteuberant abdomen, BP = 150/100
• Lab: Pcr = 4 mg/dl, BUN = 40 mg/dl
• Urinalysis: 4+ blood, trace protein
• Ultrasound: enlarged kidneys
• CrCl
• Kidney function

Answer 31

• CrCl
  
  • CG: [(140 - 40) * 72] / (4 * 72) = 25 ml/min
• Kidney function: abnormal
  
  • Decreased GFR + FH kidney disease + enlarged kidneys –> AD polycystic kidney disease

Question 32

Example

• 70yo 80 kg man
• Severe HTN
• H: smoker, high cholesterol, 3 anti-HTN meds
• P: BP = 180/120, fundi w/ HTN blood vessel changes, S4 gallop, 1+ ankle edema
• Lab: Pcr = 2 mg/dl, BUN = 50 mg/dl
• Urinalysis: no protein, no blood
• Angiogram: no blood flow to one kidney, severe stenosis of renal artery on other kidney
• CrCl
• Kidney function

Answer 32

• CrCl
  
  • C-G formula: [(140 - 70) * 80] / (2 * 72) = 41 ml/min
• Kidney function: abnormal
  
  • Moderately decreased GFR + no blood flow + stenosis –> renovascular disease

Question 33

GFR evaluation summary

• BUN
  
  • CKD
  • AKI
• Pcr
  
  • CKD
  • AKI
• 24 hr urine CrCl
  
  • CKD
  • AKI
• Cockroft-Gault formula
  
  • CKD
  • AKI
• MDRD formula
  
  • CKD
  • AKI

Answer 33

• BUN
  
  • CKD: +
  • AKI: +
• Pcr
  
  • CKD: ++
  • AKI: ++
• 24 hr urine CrCl
  
  • CKD: +++
  • AKI: no
• Cockroft-Gault formula
  
  • CKD: +++
  • AKI: no
• MDRD formula
  
  • CKD: +++
  • AKI: no