Chronic renal failure

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Chronic renal failure
ICD-10 N18
ICD-9 585
eMedicine med/374 

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Associate Editor-In-Chief: Cafer Zorkun, M.D., Ph.D. [2]

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Overview

Chronic renal failure (CRF), also known as chronic kidney failure (CKF) or chronic kidney disease (CKD), or chronic renal insufficiency (CRI) is a slowly progressive loss of renal function over a period of months or years, and defined as an abnormally low glomerular filtration rate, which is usually determined indirectly by the creatinine level in blood serum.

CRF that leads to severe illness and requires some form of renal replacement therapy (such as dialysis) is called end-stage renal disease (ESRD).

Signs and symptoms

Initially it is without specific symptoms and can only be detected as an increase in serum creatinine. As the kidney function decreases:

CRF patients suffer from accelerated atherosclerosis and have higher incidence of cardiovascular disease, with a poorer prognosis.

Diagnosis

In many CRF patients, previous renal disease or other underlying diseases are already known. A small number presents with CRF of unknown cause. In these patients, a cause is occasionally identified retrospectively.

It is important to differentiate CRF from acute renal failure (ARF) because ARF can be reversible. Abdominal ultrasound is commonly performed, in which the size of the kidneys are measured. Kidneys in CRF are usually smaller (< 9 cm) than normal kidneys with notable exceptions such as in diabetic nephropathy and polycystic kidney disease. Another diagnostic clue that helps differentiate CRF and ARF is a gradual rise in serum creatinine (over several months or years) as opposed to a sudden increase in the serum creatinine (several days to weeks). If these levels are unavailable (because the patient has been well and has had no blood tests) it is occasionally necessary to treat a patient briefly as having ARF until it has been established that the renal impairment is irreversible.

Numerous uremic toxins (see link) are accumulating in chronic renal failure patients treated with standard dialysis. These toxins show various cytotoxic activities in the serum, have different molecular weights and some of them are bound to other proteins, primarily to albumin. Such toxic protein bound substances are receiving the attention of scientists who are interested in improving the standard chronic dialysis procedures used today.

Causes

Complete Differential Diagnosis of Causes of Chronic Renal Failure

The most common causes of CRF are diabetic nephropathy, hypertension, and glomerulonephritis. Together, these cause approximately 75% of all adult cases. Certain geographic areas have a high incidence of HIV nephropathy.

Historically, kidney disease has been classified according to the part of the renal anatomy that is involved, as:

Etiology of CRI

Screening / Diagnostic Laboratory Studies

Measurement of Renal Function

  • Serum creatinine (Cr)
    • Determined by glomerular filtration rate (GFR) and by generation, tubular secretion and extrarenal clearance of Cr
    • May be inaccurate estimate of function, particularly in patients with mild renal insufficiency
    • Drugs may inhibit tubular secretion of Cr and falsely elevated serum Cr (cimetidine, trimethoprim (TMP))
  • Creatinine clearance
    • Estimate: [(140-age) x body wt (kg)] / [Plasma Cr x 72] (multiply result x 0.85 for women)
    • Calculated based on 24-hour urine collection
      • CrCl (mL/min) = [Urine Cr (mg/dL) x Urine volume (mL/d)] / [Plasma Cr x 1440]
    • If GFR < 50, CrCl overestimates GFR

Determination of Chronicity

Urinalysis

    • May suggest glomerular vs. nonglomerular cause
  • Urine sodium excretion (FENa):
    • More useful for ARF to distinguish prerenal state from acute tubular necrosis (ATN)
    • May not be low in volume depleted CRI patient due to tubular dysfunction

Ultrasound

Ultrasound

  • To rule out obstruction
  • To assess kidney size (small = chronic disease; large = DM, amyloidosis)
  • Can detect PCKD
  • Doppler can evaluate vascular flow – stenosis, thrombosis

MRI and CT

CT scan

  • If nephrolithiasis suspected (best test) – can detect radiolucent stones
  • More sensitive than ultrasound for PCKD
  • Best evaluation for cysts/malignancy

Other Imaging Findings

  • Kidney, Ureter, and Bladder (KUB)
    • If nephrolithiasis suspected (screening test)
      • Will detect calcium-containing, struvite, and cystine stones
      • Will miss uric acid stones, small stones, and stones overlying bony structures

Other Diagnostic Studies

Biopsy
  • Indications for Biopsy
  • Contraindications
    • Uncorrectable bleeding disorder
    • Small kidneys indicative of chronic, irreversibile disease (<7-8 cm length)
    • Severe hypertension not controllable with medications
    • Multiple, bilateral cysts or a renal tumor
    • Hydronephrosis
    • Active renal or perirenal infection
    • Solitary native kidney (relative contraindication)

Treatment

The goal of therapy is to slow down or halt the otherwise relentless progression of CRF to ESRD. Control of blood pressure and treatment of the original disease, whenever feasible, are the broad principles of management. Generally, angiotensin converting enzyme inhibitors (ACEIs) or angiotensin II receptor antagonists (ARBs) are used, as they have been found to slow the progression to ESRD.[1][2]

Replacement of erythropoietin and vitamin D3, two hormones processed by the kidney, is usually necessary, as is calcium. Phosphate binders are used to control the serum phosphate levels, which are usually elevated in chronic renal failure.

After ESRD occurs, renal replacement therapy is required, in the form of either dialysis or a transplant.

  • Treatment of Reversible Exacerbants
    • Volume Depletion
      • May be subtle
      • Autoregulation impaired with DM, hypertension, CRI--decreases GFR with mild volume depletion
      • Careful trial of volume repletion may--return of baseline renal function
      • (Increase dietary Na, reduce diuretic dosing)
    • Nephrotoxins
      • NSAIDs
        • Most toxic in setting of volume depletion, CHF, diuretic use
        • Reduce prostaglandin (PG) synthesis--unopposed vasoconstriction with decreased GFR
        • Can also cause ATN (acute tubular necrosis)
      • Aminoglycosides
        • Nonoliguric ARF typically occurs at 7-10 days
        • Increased risk with older patients, prolonged therapy and greater total dose
      • IV contrast
        • ARF usually occurs within 24-48 hours of dye administration
        • Peak Cr after 5-7 days with return to baseline at 10-14 days
        • Risk ARF increased with DM and higher volume of dye
      • Note: certain meds increase serum Cr (via inhibiting Cr secretion or interfering with assay) without changing GFR, e.g. cimetidine, trimethoprim (TMP), cefoxitin, flucytosine; BUN will not rise because GFR is preserved
    • Urinary Tract Obstruction
  • Reduce Progression
    • Protective therapy most effective if initiated early, before Cr > 1.5-2.0 mg/dL
    • Treat Hypertension
      • Systemic hypertension--elevated intraglomerular pressure +/or glom hypertrophy
      • Blood Pressue (BP) control shown in multiple trials to slow progression of renal disease
      • Goal BP < 130/80-85; < 125/75 in patients with proteinuria > 1-2 g/d
      • ACE inhibitors (ACEI) and Angiotensin II receptor blockers (ARB) preferred 1st line agents due to renoprotective effects
      • Additional agents as needed, including diuretics if volume overload
    • Restrict Dietary Protein
      • Controversial – may decrease intraglomerular pressure
      • Conflicting studies – some show benefit, others do not
      • No significant adverse effects shown in large trial
      • Recommendations
        • No restriction (> 0.8 g/kg/d) if GFR 25-55 mL/min
        • Limit protein to 0.8 g/kg/d if progression or uremic symptoms
        • Limit to 0.6 g/kg/d if severe CRI (GFR 13-25 mL/min)
      • Close follow-up by dietician given risk of malnutrition in CRI population
    • Control blood sugar:
      • Tight control (A1c < 7.0, FBS 70-120) reduces progression in DM I
      • Unclear if as beneficial in DM II, but potentially helpful
  • Treat complications
    • Volume Overload
      • Impaired excretion of Na/H2O due to decreased GFR +/- AII/aldo activation
      • Restrict dietary Na to 1-2 g/d if hypertension or edema
      • Diuretics
        • Thiazides ineffective if GFR < 25 mL/min (~ Cr > 2-3)
        • Switch to loop diuretic as Cr rises; may need bid dosing
        • Addition of thiazide to loop diuretic can--additional diuresis
        • Watch for excessive volume depletion
    • Hyperkalemia
      • K usually maintained until GFR < 15-20 mL/min
      • Increased risk of hyperkalemia with oliguria, high K diet, (ACEI therapy)
      • Increased risk with many meds: ACEI, NSAIDs, K-sparing diuretics, digoxin, TMP
      • Increased risk in diabetics with type IV RTA
      • Management
        • Low K diet (< 60 mEq/d) once GFR < 15 mL/min
        • Avoidance of salt substitutes (may contain K salts)
        • +/- loop diuretic
        • Low dose Kayexelate (5 g with meals) if needed
    • Ca/PO4 Abnormalities
      • Reduced renal synthesis 1,25-(OH)2D--low serum Ca-- 2° hyperparathyroidism
        • (Occurs when GFR < 40 mL/min)
      • Reduced GFR--phosphate retention
      • Elevated parathyroid hormone (PTH)--mobilization of Ca from bone; increased excretion PO4
      • Therapy goals = normalize Ca/PO4 and maintain parathyroid hormone (PTH)< 200 (2-3x uln)
        • Ca/PO4 management should be initiated when Cr ~ 2
        • CaxPO4 product should be < 60 to prevent met calcification
        • Low PO4 diet: < 800 mg/d (challenging)
        • Ca-based oral PO4 binders: Ca acetate or CaCO3 with meals
        • Avoid Al-based PO4 binders except for acute therapy of hi CaxPO4 products
        • Avoid Ca citrate (increases gastrointestinal absorption of aluminum)
        • RenaGel = new non-Ca/Al-containing PO4 binder (cationic polymer)
          • (For patients who cannot tolerate CaCO3 or need additional agent)
        • Calcitriol 0.125-0.25 mg/d improves Ca & PTH levels, decreases bone disease
          • (Monitor Ca--reduce dose if hyercalcemic)
    • Metabolic Acidosis
      • Occurs when GFR < 25 mL/min due to inability to excrete H+ ions
      • Underlying cause = impaired renal NH3 prodxn and HCO3 reabsorption
      • Risk = bone buffering of acidosis--worsened osteodystrophy via Ca/PO4 loss
        • Increased skeletal muscle breakdown--loss of lean body mass
      • Therapy goal = HCO3 > 22 mEq/L via alkali therapy (NaHCO3 0.5-1 mEq/kg/d)
    • Anemia
      • Normocytic, normochromic, hypoproliferative anemia due to reduced erythropoietin production
      • May be exacerbated by reduced rbc survival, coexistent Fe/folate deficiency, etc.
      • Generally occurs when Cr > 2-3 mg/dL
      • If untreated, hematocrit (Hct) usually stabilizes at ~ 25
      • Therapy recommendations = erythropoietin if symptomatic anemia or Hgb < 10 g/dL (in pre-dialysis patients)
        • Goal Hct 33-36
        • Must replete Fe stores first (oral FeSO4)
        • Initial dose ~ 150 U/kg sc weekly to increase Hct
        • Maintenance dose ~ 75 U/kg weekly once Hct goal reached
        • Improves symtoms and may reduce left ventricle (LV) mass (via improvemt of hyperdynamic state)
        • Side effects = increased blood pressure (BP); may need to augment antihypertensive regimen
  • Plan for Renal Replacement Therapy (RRT)
  • Indications for referral to nephrologist
    • Unclear etiology of new or chronic renal insufficiency
    • For diagnostic evaluation, e.g. biopsy
    • GFR < 50 mL/min: i.e. before vascular access/RRT required

Prognosis

The prognosis of patients with chronic kidney disease is guarded as epidemiological data has shown that all cause mortality (the overall death rate) increases as kidney function decreases.[3] The leading cause of death in patients with chronic kidney disease is cardiovascular disease, regardless of whether there is progression to ESRD.[3][4][5]

While renal replacement therapies can maintain patients indefinitely and prolong life, the quality of life is severely affected.[6][7] Renal transplantation increases the survival of patients with ESRD significantly when compared to other therapeutic options;[8][9] however, it is associated with an increased short-term mortality (due to complications of the surgery). Transplantation aside, high intensity home hemodialysis appears to be associated with improved survival and a greater quality of life, when compared to the conventional thrice weekly hemodialysis and peritoneal dialysis.[10]

See also

References

  1. Ruggenenti P, Perna A, Gherardi G, Gaspari F, Benini R, Remuzzi G. Renal function and requirement for dialysis in chronic nephropathy patients on long-term ramipril: REIN follow-up trial. Gruppo Italiano di Studi Epidemiologici in Nefrologia (GISEN). Ramipril Efficacy in Nephropathy. Lancet. 1998 Oct 17;352(9136):1252-6. PMID 9788454.
  2. Ruggenenti P, Perna A, Gherardi G, Garini G, Zoccali C, Salvadori M, Scolari F, Schena FP, Remuzzi G. Renoprotective properties of ACE-inhibition in non-diabetic nephropathies with non-nephrotic proteinuria. Lancet. 1999 Jul 31;354(9176):359-64. PMID 10437863.
  3. 3.0 3.1 Perazella MA, Khan S. Increased mortality in chronic kidney disease: a call to action. Am J Med Sci. 2006 Mar;331(3):150-3. PMID 16538076.
  4. Sarnak MJ, Levey AS, Schoolwerth AC, Coresh J, Culleton B, Hamm LL, McCullough PA, Kasiske BL, Kelepouris E, Klag MJ, Parfrey P, Pfeffer M, Raij L, Spinosa DJ, Wilson PW; American Heart Association Councils on Kidney in Cardiovascular Disease, High Blood Pressure Research, Clinical Cardiology, and Epidemiology and Prevention. Kidney disease as a risk factor for development of cardiovascular disease: a statement from the American Heart Association Councils on Kidney in Cardiovascular Disease, High Blood Pressure Research, Clinical Cardiology, and Epidemiology and Prevention. Circulation. 2003 Oct 28;108(17):2154-69. PMID 14581387. Free Full Text.
  5. Tonelli M, Wiebe N, Culleton B, House A, Rabbat C, Fok M, McAlister F, Garg AX. Chronic Kidney Disease and Mortality Risk: A Systematic Review. J Am Soc Nephrol. 2006 May 31; PMID 16738019.
  6. Heidenheim AP, Kooistra MP, Lindsay RM. Quality of life. Contrib Nephrol. 2004;145:99-105. PMID 15496796.
  7. de Francisco AL, Pinera C. Challenges and future of renal replacement therapy. Hemodial Int. 2006 Jan;10 Suppl 1:S19-23. PMID 16441862.
  8. Groothoff JW. Long-term outcomes of children with end-stage renal disease. Pediatr Nephrol. 2005 Jul;20(7):849-53. Epub 2005 Apr 15. PMID 15834618.
  9. Giri M. Choice of renal replacement therapy in patients with diabetic end stage renal disease. EDTNA ERCA J. 2004 Jul-Sep;30(3):138-42. PMID 15715116.
  10. Pierratos A, McFarlane P, Chan CT. Quotidian dialysis--update 2005. Curr Opin Nephrol Hypertens. 2005 Mar;14(2):119-24. PMID 15687837.

Acknowledgements

The content on this page was first contributed by: C. Michael Gibson, M.S., M.D., Rebecca Cunningham, M.D.

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