Stones: Evaluation and Medical Management: Difference between revisions

See 2019 AUA Evaluation and Medical Management of Stones Guideline Notes

Imaging for Stone Disease

Plain Abdominal Film

• Findings
  • Can identify nephrocalcinosis, suggestive of RTA
  • Radiolucent stones (6):
    • Uric acid
    • Matrix
    • Medication stones (4):
      • Xanthine
      • Triamterene
      • 2,8-dihydroxyadenine
      • Indinavir
  • Radioopaque stones (4):
    • Calcium oxalate
    • Calcium phosphate
    • Poorly radioopaque:
      • Magnesium ammonium phosphate (struvite)
      • Cystine stones
        • Although magnesium ammonium phosphate and cystine stones are often radioopaque, they are not as dense as calcium oxalate or calcium phosphate stones
• Test characteristics§
  • Sensitivity: 57%
  • Specificity: 76%
• Advantage(s)
  • Availability
  • Relatively low radiation exposure
    • 0.7 mSv with KUB§
  • Cost (least expensive)
• Disadvantages
  • Inability to visualize small stones
  • Inability to visualize stones due to overlying/underlying anatomy (bones, phleboliths, etc.)
  • Underestimates >90% of stones >10mm

Ultrasound

• Test characteristics§
  • Sensitivity: 84%
  • Specificity: 53%
• Advantages
  • Availability
  • No radiation exposure
  • Cost (5x cost of KUB)§
• Disadvantages (2):
  • Inability to visualize most ureteral stones
  • Poor correlation between measured and actual stone size and location
    • If stone
      • <10mm, US underestimates size of stone 1/3 of the time
      • >10mm, US overestimates size of stone 1/3 of the time
    • US and CT measurements correlate 2/3 of the time

CT scan (without contrast)

• Findings
  • Pure uric acid stones have much lower Hounsfield units than calcium types
  • Forniceal extravasation
    • Usually associated with a small distal ureteral calculus.
    • Should be similarly to other ureteral stones: intervention should be undertaken when there is an associated fever, nausea/vomiting, or unrelenting pain. Otherwise, conservative observation is appropriate.
• Test characteristics§
  • Sensitivity: 95%
  • Specificity: 98%
• Advantages
  • Most sensitive modality for stones
• Disadvantages
  • Exposure to radiation§
    • Low-dose CT is ≈3.0 mSv, standard CT without contrast is 10.0 mSV
  • Availability
  • Cost (10x cost of KUB)§

MRI

• Test characteristics§
  • Sensitivity: 82%
  • Specificity: 98%
• Findings
  • Stones appear as filling defects
• Advantages
  • No exposure to radiation
• Disadvantages
  • Availability
  • Cost (most expensive, 30x cost of KUB)§

Acute management

• Renal colic pain management[1]
  • Toradol 30 mg IV
  • Cardiac Lidocaine 1.5 mg/kg IV in 100 mL NS over 10 minutes (MAX 200 mg)
  • Acetaminophen 1000 mg PO
  • 1 L 0.9% NS bolus

Diagnosis and Evaluation of Metabolic Stone Disease

UrologySchool.com Summary

AUA

• Screening Evaluation
  • History and Physical Exam
  • Laboratory (5)
    1. Urinalysis +/- culture
    2. Serum electrolytes (Na, K, Cl, HCO3)
    3. Serum calcium
    4. Serum creatinine
    5. Serum uric acid
• Extended evaluation
  • One or two 24-hour urine collections

Goals of Evaluation

• Identify potential associated metabolic disorders such as (5)
  1. Distal renal tubular acidosis (RTA)
  2. Primary hyperparathyroidism
  3. Enteric hyperoxaluria
  4. Cystinuria
  5. Gouty diathesis
• Reduce risk of stone recurrence
  • First-time stone formers have been estimated to have a 50% risk for recurrence within the subsequent 10 years
  • Patients at higher risk for repeat episodes (6):
    1. Family history of stones
    2. Intestinal disease (particularly when causing chronic diarrheal states)
    3. Pathologic skeletal fractures
    4. Osteoporosis
    5. UTI
    6. Gout

History and Physical Exam

History

• Screen for factors that predispose to calculi
  • Conditions associated with stone disease (8):
    1. Obesity
    2. Hyperthyroidism
    3. Gout
    4. Renal tubular acidosis (RTA) type 1
    5. Diabetes mellitus type 2
    6. Bone disease
    7. Primary hyperparathyroidism
    8. Malabsorptive gastrointestinal states due to bowel resection, bariatric surgery or bowel or pancreatic disease
       1. Chronic diarrhea that could be caused by inflammatory bowel disease (Crohn disease, ulcerative colitis) or irritable bowel syndrome
       2. Gout may predispose the patient to hyperuricosuria or gouty diathesis with either uric acid calculi or calcium oxalate stone formers
       3. Surgical history should be obtained focusing particularly on bariatric surgery and surgeries of the intestinal tract. In contrast to gastric bypass surgery, restrictive bariatric surgeries such as gastric sleeve or gastric band do not seem to increase the risk for kidney stones
  • Dietary history
    • Should include average daily intake of fluids (amount and specific beverages), protein (types and amounts), calcium, sodium, high oxalate-containing foods, fruits and vegetables and over-the-counter supplements.
      • Nutritional factors associated with stone disease, depending on stone type and risk factors, include
        • Calcium intake below or significantly above the recommended dietary allowance (RDA)
        • Low fluid intake
        • High sodium intake
        • Limited intake of fruits and vegetables
        • High intake of animal-derived purines
  • Medications
    • Stone-provoking medications or supplements (9):
      1. Probenecid
      2. Some protease inhibitors
      3. Lipase inhibitors
      4. Triamterene
      5. Chemotherapy
      6. Vitamin C
      7. Vitamin D
      8. Calcium
      9. Carbonic anhydrase inhibitors such as topiramate, acetazolamide, zonisamide

Physical Exam

• Body mass index
  • Increased BMI, larger waist size, and weight gain are correlated with an increased risk for stone episodes
    • The association of obesity and uric acid stone formation is primarily due to change in urinary pH
    • The association of obesity with calcium oxalate stone formation is primarily due to increased excretion of promoters of stone formation (oxalate, uric acid, sodium, and phosphorus)

Laboratory

• Urinalysis +/- culture +/- microscopy
  • Urinalysis should include pH
    • pH > 7.0 is suggestive of infection lithiasis or RTA
    • pH < 5.5 suggests uric acid lithiasis secondary to gouty diathesis
  • Urine culture
    • Should be obtained in patients with a urinalysis suggestive of UTI.
    • Presence of urea-splitting organisms, such as Proteus species, raises the possibility of struvite stones
    • Many infected calculi will harbour bacteria even after treatment with broad-spectrum antibiotics
    • Half of infected calculi grow bacterial cultures that are different from the preoperative urine specimen
  • Urine microscopy
    • Identify crystals pathognomonic of stone type.
• Serum chemistries (electrolytes (Na, K, Cl, HCO3), calcium, creatinine and uric acid)
  • May suggest underlying medical conditions associated with stone disease (e.g., primary hyperparathyroidism, gout, RTA type 1 or other metabolic derangements)
  • Assessment of underlying renal function is necessary
• Parathyroid hormone (PTH)
  • Indicated as part of the screening evaluation if primary hyperparathyroidism is suspected
    • Primary hyperparathyroidism should be suspected when (3):
      1. Mid-range PTH despite high or high normal serum calcium
      2. Increased urinary calcium
      3. Predominantly calcium phosphate stone composition
  • Measurement of vitamin D levels may be helpful as low vitamin D levels may mask primary hyperparathyroidism, or contribute to secondary hyperparathyroidism.
  • A high or high normal intact PTH in these settings should prompt further endocrine evaluation, imaging or referral for consideration of parathyroidectomy.
• Stone composition, if available
  • When a stone is available, a stone analysis should be obtained at least once.
  • Can direct metabolic investigation or potentially obviate the need for a complete metabolic evaluation
  • Calcium phosphate stone composition associated with:
    1. RTA Type 1
    2. Primary hyperparathyroidism
    3. Medullary sponge kidney
    4. Use of carbonic anhydrase inhibitors

Metabolic/Extended Diagnostic Evaluation

• Consists of one or two 24-hour urine collections obtained on a random diet★

Indications

• AUA (7):★
  1. Recurrent stone formers
  2. Family history of stone disease
  3. Solitary kidney
  4. Malabsorptive intestinal disease or resection
  5. Obesity
  6. Recurrent UTIs
  7. Medical conditions predisposing to stones (e.g., RTA Type 1, primary hyperparathyroidism, gout, diabetes mellitus type)
• Included in other lists
  1. Pathological skeletal fractures
  2. Osteoporosis
  3. Infirm health (unable to tolerate repeat stone episodes)
  4. Anatomic abnormalities
  5. Stones composed of cystine, uric acid, and struvite
  6. Children should generally be evaluated because of concerns about renal damage and long-term sequelae of stone recurrence

24-hour urine collections

• Can be used to inform and monitor treatment protocols
• Analyzed at minimum for (9): ★
  1. Volume
  2. pH
  3. Creatinine
  4. Sodium
  5. Potassium
  6. Calcium
  7. Oxalate
  8. Uric acid
  9. Citrate
  10. In stone formers with known cystine stones or a family history of cystinuria or for those in whom cystinuria is suspected, urinary cystine should additionally be measured.
  11. Sulfate can be added to assess the volume of protein loading from animal meat

• The accuracy of a 24-hour urine collection should be assessed prior to interpretation of results.
  • To assess the adequacy of collection, 24-hour urinary creatinine excretion, taking into account patient gender and body weight, as well as patient recall of the start and end times of his or her collection, should be considered
    • Significant aberrations in total creatinine excretion from estimated volumes (males 20-25mg/kg and females 15-20mg/kg in 24 hours) imply incomplete collection, overcollection, greater than expected muscle mass, or less than expected muscle mass
      • For abnormally collected 24 hour urine collections, can divide metabolite excretion by creatinine excretion to compare collections
• Markers of protein intake, such as urine urea nitrogen or urinary sulfate, are reflective of animal protein intake and can be used to assess dietary adherence.
• Urinary potassium measured at baseline can be compared to urinary potassium obtained during follow-up to gauge compliance with medication regimens.
• Primary hyperoxaluria should be suspected when urinary oxalate excretion > 75 mg/day in adults without bowel dysfunction. These patients should be considered for referral for genetic testing and/or specialized urine testing
• Fast and calcium load testing should not be performed routinely to distinguish among types of hypercalciuria

Conservative Management

Diet Therapies

• General diet therapies to reduce risk of stone recurrence (6)
  1. Increase fluid intake
  2. Limit sodium intake
  3. Moderate calcium intake
  4. Limit intake of oxalate-rich foods
  5. Increase intake of fruits and vegetables
  6. Limit intake of non-dairy animal protein

Increase fluid intake

1. Fluid intake that will achieve a urine volume of > 2.5 liters daily is recommended in all stone formers
   • An RCT of recurrent calcium oxalate stone formers randomized to a high fluid intake vs. no specific recommendations found significantly reduced stone recurrence rates in the high fluid intake group (12% vs. 27%, respectively, at 5 years)
   • Although there is no definitive threshold for urine volume and increased risk, an accepted goal is ≥2.5 liters of urine daily.#**Because of insensible losses and varying intake of fluid contained in food, a universal recommendation for total fluid intake is not appropriate
   • Overall, most evidence suggests that it is not the type of fluid ingested that is important for stone prevention but rather the absolute amount of fluid volume taken in per day
     • Water hardness should be a minor concern with respect to stone formation
     • Carbonated water may provide some protective benefit
     • Citrus juices (particularly lemon and orange juices) may be a useful adjunct to stone prevention
     • Alcoholic beverages, coffee, decaffeinated coffee, tea and wine have been shown to be associated with a lower risk of stone formation
     • Sugar-sweetened beverages demonstrated an increased risk.
       • The only specific beverage that has been evaluated for an effect on stone recurrence in an RCT is soft drinks; the group avoiding soft drinks demonstrated a marginally lower rate of stone recurrence at the end of the 3-year trial but the effect appeared to be limited to those consuming primarily phosphoric acid-based (e.g. colas) rather than citric acid-based soft drinks
       • Soda flavored with phosphoric acid may increase stone risk, whereas those with citric acid may decrease risk
         • Several sodas are acidified by citric acid and contain an amount of citrate equal to or greater than that of lemonade, including Diet Sunkist Orange, Diet 7Up, Sprite Zero, Diet Canada Dry Ginger Ale, Sierra Mist Free, Diet Orange Crush, Fresca, and Diet Mountain Dew. All of the aforementioned sodas have the potential to decrease the risk of kidney stones similar to or greater than lemonade.
         • In contrast, colas, including Caffeine Free Diet Coke, Diet Coke, Diet Coke with Lime, Coke Zero, Caffeine Free Diet Pepsi and Pepsi, are acidified by phosphoric acid, not by citric acid and contain low citrate levels.
           • One randomized study of recurrent stone formers with baseline soda consumption > 160 ml per day, found that over a 3-year period those who abstained from any soft drink consumption had a lower risk of symptomatic stone events (34%) compared to those who continued to drink sodas acidified by phosphoric acid (41%; RR, 0.83).§
       • Performance sports drinks
         • May increase urinary citrate and pH thereby reducing risk of stones.
           • However, these drinks have a high fructose and total carbohydrate content so they should not be recommended as the primary means of hydration for stone formers.
         • Do not lead to hypernatriuria, even though sodium content may be high
         • No effect on urinary calcium, oxalate, and uric acid.

Limiting sodium intake

• Limiting sodium intake (target of ≤100 mEq (2,300 mg)) is recommended in patients with calcium stones and relatively high urinary calcium

• High sodium intake is associated with:
  1. Increased calcium excretion
  2. Increased urinary pH
  3. Decreased citrate excretion
• RCTs have demonstrated a benefit of dietary sodium restriction

Moderate calcium intake

• Consuming 1,000-1,200 mg per day of dietary calcium is recommended in patients with calcium stones and relatively high urinary calcium

• A lower calcium diet in the absence of other specific dietary measures is associated with an increased risk of stone formation
  • Lower calcium intake results in insufficient calcium to bind dietary oxalate in the gut, thereby increasing oxalate absorption and urinary oxalate excretion.
• In contrast, the RDA of calcium, defined as 1,000-1,200 mg/day for most individuals, was shown to be associated with reduced risk
• Total calcium intake should not exceed 1,000-1,200 mg daily
  • If a patient with calcium urolithiasis uses calcium supplements, 24-hour urine samples should be collected on and off the supplement.
    • If urinary supersaturation of the calcium salt in question increases during the period of supplement use, the supplement should be discontinued.
• Calcium supplements are safe if attention is paid to preparation (calcium citrate appears to be a more stone-friendly calcium supplement because of the additional inhibitory action of citrate) and especially timing (should be taken with meals)

Limit intake of oxalate-rich foods

• Limiting intake of oxalate-rich foods and maintaining normal calcium consumption is recommended in patients with calcium oxalate stones and relatively high urinary oxalate

• Urinary oxalate is also modulated by calcium intake, which influences intestinal oxalate absorption
• Other factors that may contribute to higher urinary oxalate include vitamin C (ascorbic acid is metabolized to oxalate) and other over-the-counter nutrition supplements.
• Although dietary oxalate clearly plays a role in increased urinary oxalate, it is difficult to restrict its intake because oxalate is ubiquitous and found in most vegetable matter. However, it is important to avoid large portions of foodstuffs that are rich in oxalate, such as spinach, beets, chocolate, nuts, and tea.
• Whereas general advice on a restricted-oxalate intake might be given to patients with recurrent nephrolithiasis, a low-oxalate diet would be most useful in patients with enteric hyperoxaluria, such as those with underlying bowel abnormalities or previous gastric bypass surgery

Increase intake of fruits and vegetables

• Recommended in patients with calcium stones and relatively low urinary citrate

• Urinary citrate excretion is determined by acid-base status; conditions such as metabolic acidosis, renal tubular acidosis and chronic diarrhea, and some medications, such as carbonic anhydrase inhibitors, may promote hypocitraturia**Acidosis can arise from a diet that is inordinately rich in foods with a high potential renal acid load such as meats, fish, poultry, cheese, eggs, and to a lesser extent, grains.
  • Dietary citrate increases urinary citrate excretion
• Although a number of fruits and juices have been evaluated for their effect on urinary stone risk factors, none have been prospectively evaluated in an RCT assessing actual stone formation.

Limit intake of non-dairy animal protein

• Recommended in patients with calcium stones and relatively low urinary citrate
• May help reduce stone recurrence in patients with uric acid stones or calcium stones and relatively high urinary uric acid

• Protein intake increases urinary calcium, oxalate, and uric acid excretion
  • Urinary uric acid is derived from both endogenous and exogenous sources
    • Diet-derived purines account for an ≈30% of urinary uric acid
• If diet assessment suggests that purine intake is contributory to high urinary uric acid, patients may benefit from limiting high- and moderately high purine containing foods.
  • "High purine" foods are generally considered specific fish and seafood (anchovies, sardines, herring, mackerel, scallops and mussels), water fowl, organ meats, glandular tissue, gravies and meat extracts.
  • "Moderately-high" sources of purines include other shellfish and fish, game meats, mutton, beef, pork, poultry and meat-based soups and broths
• RCTs have demonstrated a benefit of a diet with reduced animal protein (meat) intake

Cystine Stones

1. Patients with cystine stones should be counselled to increase fluid intake and limit sodium and protein intake
   • High fluid intake is particularly important in cystine stone formers; the target for urine volume is typically higher than that recommended to other stone formers; oral intake of ≥4 L/day is often required
   • Lower sodium intake has been shown to reduce cystine excretion
   • Limiting animal protein intake is of benefit in patients with cystine stones

Other

• Weight-loss diets
  • The consumption of a low-carbohydrate, high-protein diet delivers a marked acid load to the kidney, increases the risk for stone formation, and may increase the risk of bone loss

• Metabolic syndrome is associated with lower urinary pH
• Roux-en-Y-gastric bypass surgery may significantly increase the overall risk for stone formation
• Vitamin D
  • Controversy exists over the role of vitamin D supplementation and kidney stone formation
  • Patients who undergo vitamin D repletion should have their 24-hour urine calcium monitored

Follow-up of diet therapies

• If the patient’s metabolic or environmental abnormalities have been corrected, the conservative therapy can be continued and the patient followed every 6-12 months with repeat 24-hour urine testing as indicated.
  • Follow-up is essential not only to monitor the efficiency of treatment but also to encourage patient compliance. If, however, a metabolic defect persists, a more selective medical therapy may be instituted.

Selective medical therapy for nephrolithiasis

• See Tables 52-9 and 52-10 for dosages and side effects
• Hypercalcuria
  • In patients with renal or absorptive type I hypercalciuria, thiazide is the first choice.
    • Recall, in absorptive hypercalciuria I, increased absorption will occur regardless of the amount of calcium in the patient’s diet (these patients will demonstrate an hypercalcuria on both the fasting and the loading specimens). In contrast, patients with absorptive hypercalciuria II will have a normal amount of urinary calcium excretion during calcium restriction, but will show elevations during their regular diet
    • Currently, no treatment is capable of correcting the basic abnormality of type I absorptive hypercalcuria
    • Thiazides may have a limited long-term effectiveness in type I absorptive hypercalcuria
    • In type II absorptive hypercalciuria, no specific drug treatment may be necessary because the physiologic defect is not as severe as in type I.
  • Thiazides
    • MOA
      1. Directly stimulate calcium reabsorption in the distal nephron
      2. Promotes excretion of sodium causing extracellular volume depletion
         • Long-term thiazide therapy results in volume depletion, extracellular volume contraction, and proximal tubular resorption of sodium and calcium.
    • Chlorthalidone (25-50 mg/day) or indapamide (2.5 mg/day) are preferred to hydrochlorothiazide since they are long-acting and are once a day dosing.
      • Indapamide is technically not a thiazide but does share a successful hypocalciuric effect with the other agents.
    • Patients placed on thiazide diuretics for management of hypercalciuria should also be placed on dietary sodium restriction
      • An excess sodium load will inhibit reabsorption of calcium in the proximal tubule, thereby causing hypercalciuria.
    • Adverse events
      • Lassitude and sleepiness
        • Most common side effects of thiazides
        • Can occur in the absence of hypokalemia
        • Usually seen on initiation of treatment but resolves with continued therapy.
      • Metabolic/electrolyte abnormalities (3 hypers, 3 hypos + metabolic alkalosis)
        1. Hyperglycemia
        2. Hyperlipidemia
        3. Hyperuricemia
        4. Hypokalemia
        5. Hypomagnesemia
        6. Hypocitraturia
        7. Metabolic alkalosis

• Hypokalemia and hyperglycemia
  • The degree of diuretic-induced hypokalemia correlates with level of hyperglycemia.
    • Mechanism: hypokalemia impairs insulin secretion, thereby increasing plasma glucose.
  • Potassium supplementations should always be considered at either the onset of thiazide therapy or upon the discovery of glucose intolerance
    • Can prevent or significantly lessens the degree of hypokalemia or glucose intolerance
    • Can be administered as potassium citrate, potassium-sparing agents (triamterene), or with dietary supplements such as a banana per day
      • Citrates are generally well tolerated, with only a small risk for GI upset
        • A liquid preparation of potassium citrate, rather than the slow-release tablet preparation, is recommended in patients with rapid intestinal transit time (i.e. chronic diarrhea); the slow-release medication may be poorly absorbed
      • Conflicting evidence of an increased risk of calcium phosphate stone formation with the long-term use of potassium citrate therapy
    • Particularly important in patients with evident potassium deficiency, patients on digitalis therapy, and those individuals who develop hypocitraturia
• Hypocitraturia
  • Result of hypokalemia with intracellular acidosis
    • • Patients with undiagnosed primary hyperparathyroidism may develop hypercalcemia after initiation of thiazide therapy
        • Although most patients with primary hyperparathyroidism demonstrate hypercalcemia and hypercalciuria, a normal serum calcium level in the presence of an inappropriately high serum PTH value may be seen in some cases, making the diagnosis more difficult. Administration of a thiazide diuretic will enhance renal calcium reabsorption and exacerbate the hypercalcemia, thereby facilitating the diagnosis (“thiazide challenge”)
          • In the thiazide challenge, cessation of thiazide should reduce PTH and serum calcium. However, in primary hyperparathyroidism, PTH and serum calcium remain persistently elevated with cessation of thiazide.
      • Bisphosphonates combined with thiazide diuretics appear to reduce hypercalciuria while protecting the bone
    • Thiazide diuretics lose their effectiveness in the treatment of hypercalciuria in up to 25% of patients on long-term management.
      • Loss of effectiveness is due to increased serum calcium levels which stimulate the C cells in the thyroid to produce more calcitonin. Increased calcitonin leads to increased urinary calcium excretion.
  • Fish oil
    • An effective, first-line therapy for mild-moderate hypercalciuria
      • Thought to have a protective role in preventing nephrolithiasis by decreasing urinary calcium and oxalate excretion through alteration of prostaglandin metabolism
  • Hyperparathyroidism complicated by stone disease is best treated with surgical excision of the adenoma

• Hyperuricosuric Calcium Oxalate Nephrolithiasis
  • Patients with hyperuricosuria should be instructed to decrease dietary purine intake
  • Pharmacologic approaches to the management of hyperuricosuric calcium nephrolithiasis (2):
    1. Alkalinizing the urine so that uric acid remains in a dissolved state
       • Potassium citrate may be used
         • CUA Guidelines only discuss allopurinol for hyperuricosuric calcium oxalate nephrolithiasis, not potassium citrate
    2. Decreasing the production of uric acid
       • Allopurinol (300 mg/day) may be used
         • MOA: blocks the ability of xanthine oxidase to convert xanthine to uric acid.
           • The resultant decrease in serum uric acid will ultimately lead to a decrease in urinary uric acid as well.
         • Allopurinol’s use in hyperuricosuria associated with dietary purine overindulgence also may be reasonable if patients are unable or unwilling to comply with dietary purine restriction.

• Enteric hyperoxaluria
  • Fluid intake should be strongly encouraged to correct the relative state of dehydration
  • Dietary/supplemental calcium may help bind intestinal oxalate and decrease its absorption
  • Treatment with potassium citrate (60 to 120 mEq/day) may correct the hypokalemia and metabolic acidosis in patients with enteric hyperoxaluria and, in some individuals, increase urinary citrate toward normal.

• Hypocitraturic Calcium Oxalate Nephrolithiasis
  • Citrates are first-line therapy for the management of RTA, thiazide-induced hypocitraturia, and idiopathic hypocitraturia
    • Potassium citrate therapy is able to correct the metabolic acidosis and hypokalemia found in patients with distal RTA

• Hypomagnesuric Calcium Nephrolithiasis
  • Magnesium oxide or magnesium hydroxide can be used to restore urinary magnesium; hypocitraturia can be corrected with potassium citrate
    • Use of magnesium has been limited by the risk for diarrhea
    • Potassium-magnesium may restore urinary magnesium and citrate levels with minimal GI side effects

• Uric acid stones
  • Goal is to increase the urinary pH > 5.5, preferably between 6.0-6.5, through an alkalinizing agent such as potassium citrate
    • With adequate alkali therapy, patient's can raise the urine pH above the dissociation constant of uric acid.
      • Attempts at alkalinizing the urine to a pH > 7.0 should be avoided. At a higher pH, there is a danger of increasing the risk for calcium phosphate stone formation.
    • Patients may initially present with low/normal 24-hour urinary uric acid levels because the uric acid will precipitate out of solution in the acid urinary environment. Once the urine has been alkalized, all of the uric acid will come back into solution, causing a significant increase in the measured urinary uric acid.
  • Patient's treated with sodium alkali will occasionally begin forming calcium oxalate stones due to an excess sodium load that will inhibit reabsorption of calcium in the proximal tubule, thereby causing hypercalciuria
    • Potassium citrate is advantageous because it is not only a good alkalinizing agent, but it appears to be devoid of the complication of calcium stones.
  • Acetazolamide is effective in increasing the urinary pH in patients with uric acid and cystine stone formation who are already taking potassium citrate.
    • Acetazolamide, a carbonic anhydrase inhibitor, leads to an increase in urinary bicarbonate and increased H+ reabsorption.
    • Up to 50% of patients may discontinue acetazolamide due to adverse effects.

• Cystinuria
  • First-line: aggressive fluid intake, urinary alkalinization, and salt avoidance (excess dietary sodium can lead to increases in cystine excretion)
  • Second line: cystine-binding agents
    • MOA: increase cystine solubility in urine by formation of a more soluble mixed-disulfide bond (i.e., cystine to drug, rather than cystine to cystine).
    • Options include α-mercaptopropionylglycine (tiopronin [Thiola]), D-penicillamine (Cuprimine), and captopril
      • d-Penicillamine and α-MPG are equally effective in their ability to decrease urinary cystine levels. However, α-mercaptopropionylglycine is significantly less toxic than d-penicillamine.
      • Side effects of D-penicillamine include gastrointestinal disturbances, fever and rash, arthralgia, leukopenia, thrombocytopenia, proteinuria with nephrotic syndrome, polymyositis, and pyridoxine (Vitamin B6) deficiency
        • Pyridoxine (vitamin B6) deficiency supplementation is recommended

• Infection stones
  • The preferred management of struvite calculi involves aggressive surgical approaches
  • The medical management of infection calculi centers on the prevention of recurrence, rather than medical dissolution.
    • Long-standing effective control of infection with urea-splitting organisms should be achieved if at all possible with improved bladder health, adequate urinary drainage, and suppressive antibiotics
    • Acetohydroxamic acid (AHA)
      • MOA: urease inhibitor; may reduce the urinary saturation of struvite and therefore delay stone formation
      • Adverse effects
        • Minor side effects common (up to 30% of patients)
        • Deep venous thrombosis (15%)
        • Hemolytic anemia
          • Most serious side effect
          • Occurs in up to 15% of the patients; more prevalent in patients with renal insufficiency
      • Frequently reserved for patients deemed too ill for surgical management.
    • Phosphate therapy is contraindicated in cases of infection calculi because this medication may promote further stone formation.

Medical management of pediatric calculi

• Neonates can develop furosemide-induced nephrolithiasis.
  • Neonates treated with loop diuretics should be screened for the development of nephrocalcinosis.
  • Cessation of furosemide diuresis is considered helpful and standard therapy.
    • Although switching to a thiazide diuretic may not actively cause the dissolution of calculi, it at least removes the causative agent and allows the kidney an opportunity to heal and clear the calcium deposits.
• The appearance of urinary calculi during childhood should raise the distinct possibility of an inherited genetic disorder, such as cystinuria, distal RTA, or primary hyperoxaluria
• There is a lack of consensus regarding normal laboratory values during 24-hour urine collections in children. Clinicians have relied on ratios to correct for the wide variation of weight
• The medical management of nephrolithiasis and the prevention of subsequent recurrences in children do not differ that dramatically from the approaches undertaken for adults

Questions

1. What is the risk of stone recurrence at 10 years in first-time stone formers?
2. What is the microscopic appearance of common urinary calculi?

Answers

1. 50%

References

• Wein AJ, Kavoussi LR, Partin AW, Peters CA (eds): CAMPBELL-WALSH UROLOGY, ed 11. Philadelphia, Elsevier, 2015, chap 52