Transcript ARF
TRAUMA-ICU NURSING EDUCATIONAL SERIES Acute Renal Failure: The Response to Severe Injury and Hypovolemic Shock Bradley J. Phillips, M.D. Critical Care Medicine Boston Medical Center Boston University School of Medicine Renal Function and Failure Overview Renal Physiology Trauma and Renal Function Initial management of Oliguria Acute Renal Failure Key Management Issues Glomerular Architecture Physiology in Normal State Renal blood flow (RBF) 20-25% cardiac output distribution • 85% outer cortical • 15% inner cortex outer medulla • <1% inner medulla Physiology in Normal State Glomerular filtration 20% of plasma filtered as cell-free and protein-free normal GFR 125 ml/min calculate • most accurate - insulin completely filtered/neither secreted or absorbed • good estimation - creatinine (Cr Urine / Cr Plasma) x urine (ml/min) Glomerular Component Functions Proximal Convoluted Tubule 60-80% reabsoprtion of H2O, Na, Cl, K, HCO3 100% glucose/amino acids Loops of Henle 20% of H2O (descending) 25% Na, Cl, K Large amounts HCO3, Mg, Cl Secretion of H ions Active Na Reabsorption Distal Convoluted Tubule 20% reabsoprtion of H2O Renin/Aldosterone Effect Collecting Ducts reabsoprtion of H2O, ADH effect Renal Physiology after Trauma Class I Hemorrhage (10-15%) autoregulation maintains GFR Class II Hemorrhage (15-30%) exceeds autoregulation vasoconstriction at afferent & efferent GFR decreases by 50-60% Class III Hemorrhage (30-40%) GFR decreases to less than 20% resuscitation relieves vasocontriction over hours to days, afferent then efferent arterioles Oliguria after Trauma Rapid replenishment of the circulatory volume and cardiac output at least 3-4 L for every 1 L of blood loss Factors general anesthetic • loss of renal autoregulation • loss of systemic vasoconstriction Key Management Issue IV Fluid Resuscitation Renal Function and Trauma Postresuscitative oliguria even if MAP and CO restored persistant for several hours secondary to renal arteriole vasoconstriction shifting of fluid from plasma to interstitial space secondary to depletion during hypotension/hypovolemia Postresuscitative polyuria usually transient not excessive (< 250 cc for 30-45 mins, < 3 hrs) “wash out” effect of inner medulla use other parameters ( ie HR, base deficit) Postoperative Fluid Sequestration Obligatory extravascular sequestration Phase II (Lucas, Resuscitation of the Injured Patient: Three Phases of Resuscitation, Surg Clin North Am, 1977) Last 12-36 hours Clinical signs tachycardia reduced pulse pressure oliguria weight gain some respiratory insufficiency Hormoral effect - ADH, aldosterone Fluid Mobilization Phase Phase III - mobilization and diuresis Water added to plasma faster than excreted “Postresuscitation Hypertension” Renal blood flow still remains decreased Caution with diuretics role in post elective surgery in elderly patient with CHF avoid in trauma patients can precipitate oliguria/renal dysfunction Mechanical Ventilation and Fluid Therapy Reduce renal blood flow even if zero PEEP PEEP reduces RBF more additional fluid may be required to maintain UOP Acid-Base Balance Hemorrhagic shock increased lactate acidosis metabolic acidosis persistent after intravascular volume repleted (hours) • cell metabolism • impaired renal excretion of acids Renal acid excretion absorb Na/HCO3, excrete PO, NH3 normal excrete 70-80 mEq /day can excrete 4-5x normal with severe acidosis depends on GFR and RBF Renal Response to Sepsis Hyperdynamic state increased CO, increased RBF, decreased SVR, expanded ECF volume, increased UOP “inappropriate polyuria” • vasodilators of sepsis • “wash out” effect Hypodynamic state later stages of severe sepsis decreased CO, increased SVR, decreased GFR and RBF Key Management Issue IV Fluid Resuscitation PEARL: Check Urine Na. If less than 10 meq/L…??? Acute Renal Failure Mortality in posttrauma = 50- 60% acute oliguric > 90% contrast nonoliguric < 20% Terminology ARF - sudden, severe deterioration • rule of thumb - Cr increasing > 1.0 mg/dL/day Acute tubular necrosis (ATN) - form of ARF Oliguria: UOP less than 400 ml/d • 500 mOsm daily solute concentrated to 1200 mOsm/kg Anuria: UOP less than 50 ml/d Nonoliguric renal failure progressive azotemia despite UOP > 400 ml/d High-output renal failure acute renal insufficiency with UOP > 4 L/d Acute Renal Failure Etiology severe and prolonged hypotension severe sepsis massive blood transfusions compartment syndrome myoglobinuria/hemoglobinuria radiocontrast aortic cross clamping (> 30 minutes) drug-induced postinfectious glomerulonephritis Contributing factors age pre-existing renal vascular disease pre-existing renal insufficiency Myoglobinuria/hemoglobinuria Muscle necrosis or RBC destruction Hypotension significant increase risk of ATN can occur even if renal perfusion well maintained Skeletal muscle (per kg of tissue) 40-45 meg K 730 ml of H2O 23 mmol of PO4 4 g myoglobin ( takes 100-150 mg/dL to discolor urine) Severe crush injury/muscle ischemia causes hyperkalemia, hyperphosphotemia,azotemia, hypocalemia, DIC, hypotension, and myoglobinuria Predictors of ARF ? Vivino G. Antonelli M. Moro ML. Cottini F. Conti G. Bufi M. Cannata F. Gasparetto A. Risk factors for acute renal failure in trauma patients. Intensive Care Medicine. 24(8):808-14, 1998 Aug prospective, consecutive 153 trauma patients CPK > 10,000, PEEP > 6, hemoperitoneum Loun B. Astles R. Copeland KR. Sedor FA. Adaptation of a quantitative immunoassay for urine myoglobin. Predictor in detecting renal dysfunction. American Journal of Clinical Pathology. 105(4):479-86, 1996 Apr. urine assay for myoglobinuria levels > 20,000 mcg/L Key Management Issue Administer IV Fluid Resuscitation and Maintain UOP > 100 cc/hr Rhabdomyolysis Treatment volume, volume, volume!!! • shock and rhabdomyolysis = renal failure maintain UOP > 100 - 200 cc/hr ? role or sodium bicarbonate • precipitation of myoglobin urine pH < 5.6 • check urine pH • consider if UOP marginal or severe hyperkalemia mannitol (avoid lasix if possible) • volume expander, mild diuretic, free radical scavenger follow CPK levels (most sensitive) Drug-Induced ARF Pathogenesis depends on drug Predisposing factors volume depletion age pre-existing renal disease prolonged therapy other nephrotoxic agents Drug-Induced ARF Antibiotics aminoglycosides (most publicized) • however use of cephalosporins and clindamycin potentate nephrotoxicity amphotericin B vancomycin PCN can cause hypersensitivity nephritis Limit nephrotoxicity low trough ? once a day dosing (proven to limit ototoxicity) avoid NSAIDS avoid combination of nephrotoxic antibiotics avoid hypotension Radiocontrast-Induced Nephropathy Incidence as high as 13% Mechanisms direct toxicity renal ischemia (vasoconstriction) intratubular obstruction immunologic abnormality Clinical serum Cr elevation within 24 hours serum Cr peak day 3-5 renal function normally returns by 10 days hemodialysis seldom needed Key Management Issue Administer IV Fluid Resuscitation Only IV fluid hydration has been shown to reduce incidence of IV contrast nephropathy (not lasix or dopamine) Should maintain UOP 12 hours before and 24 hours post procedure Classification of ARF Prerenal azotemia inadequate renal perfusion characterized by low urine Na/high urine Cr Postrenal azotemia complete obstruction bilateral ureteral or lower urinary tact Acute tubular interstitial nephritis usual drug-induced signs of hypersensitivity (check urine eosinophils) renal biopsy ARF - Clinical Changes Increase serum Cr (> 1 to 1.5 mg/dL/d) Increase BUN (exceeds > 25 mg/dL/d) directly related to decreased GFR related to decreased GFR and reabsorption Hyponatremia intake fluids > UOP (particularly hypotonic solutions) increased endogenous water increased loss of urine sodium ARF - Clinical Changes Hyperkalemia Metabolic acidosis reduced excretion from decreased GFR impaired renal tubules secretion faster if muscle protein breakdown due to ischemia or injury accelerated protein catabolism decreased excretion of acid load Other electrolytes hyperPO4, hyperMg hypoCa Differential Diagnosis Postrenal azotemia rule out urinary tract obstruction Prerenal azotemia hypovolemia cardiac failure Hypovolemia Renal response to decreased blood flow normal - conserve H20 and Na ARF - impaired ability to concentrate/conserve Differentiation of Pre-renal vs ARF renal failure index RFI = Urine Cr / Plasma Cr < 1.0 prerenal azotemia fractional excretion of sodium FE = (U Na/P Na) / (U Cr/P Cr) x 100 < 1.0 prerenal azotemia SIMULATANEOUS SPOT PLASMA & URINE SAMPLES Urinalysis Prerenal azotemia Obstructive uropathy unremarkable unremarkable Glomerular disease heavy proteinuria sterile pyuria mild microhematuria casts (granular/WBC) ? eosinophils Key Management Issue Fluid Challenge!!!!! RULE OUT HYPOVOLEMIA 1. test response to fluid challenge at least 500 to 1,000 cc (15-30 minutes) 2. consider CVP or pulmonary artery monitoring Treatment of ARF Diuretics after hypovolemia ruled out if given soon after onset of oliguria may convert to nonoliguric renal dysfunction (better prognosis) types • mannitol osmotic diuretic decrease proximal Na reabsorption dose: 25 g IV bolus • lasix inhibits active Na transport in loop of Henle dose: 20-40 mg IV initial, then double every 30 minutes if no response (max dose 500 mg) • dopamine (low dose, 1-3 ug/kg/min) effects partially due to inhibition of ADH Sodium and Water Balance Fluid restriction is important treatment of ARF careful to maintain perfusion problem sometimes with initial hemodialysis Fluid requirements GI and renal loss plus 500 cc accurate daily weights and I/O’s Metabolic Acidosis Hypercatabolic generation of acid loads Produces anion gap Best treated with reducing catabolism or hemodialysis, not sodium bicarbonate Hemodialysis Indications refractory pulmonary edema A Acidosis hyperkalemic E crisis disturbance Electrolyte uremic complications I Intoxication severe metabolic acidosis O Overload U Uremia Y not Why Hemodialysis Ultrafiltration indicated in hemodynamically unstable patients continuous venovenous (CV VH) or arteriovenous(CAVH) filtrate removal of 500-800 ml/hr require often some heparinization Hemodialysis rapid correction of uremia, fluid overload, electrolyte disturbances, and acidosis “prophylactic” dialysis probably beneficial added benefit by providing for adequate calories and protein ARF - Special Consideration/Complication Adjustment of medications Coagulopathy platelet dysfunction in aggregation • treatment with DDAVP (0.3 ug/kg) low antithrombin III levels • microvascular thrombosis Hyperkalemia increased with blood transfusions, acidosis, and hyperosmolemia (ie treatment with diuretics) usual treatment (glucose + insulin, calcium IV) avoid kayexelate (Na exchange for K) ARF - Special Consideration/Complication Anemia reduced EPO levels contributing factors include GI blood loss and hemodialysis (ie hemolysis) treatment with recombinant EPO/Fe replacement Stress gastritis more than 20% of ARF patients treatment • AlOH antacids (also treats hyperphosphotemia) • H2 blockers ARF - Special Consideration/Complication Pericarditis (uremia) with or without pleuritis presence of chest pain or friction rub some with fever with or without leukocytosis treatment with hemodialysis Nutritional support problems • insulin resistance • negligible free water and urea clearance • ? high energy requirement ARF - Special Consideration/Complication Nutritional support treatment • minimize free water • do not restrict protein if needed unless unable to clear with hemodialysis Outcomes of ARF Oliguric ARF expect return of renal function in 3 weeks if enter diuretic phase, likelihood of survival greatly increased older patients progress to chronic renal failure much more often Non-oliguric ARF increasing secondary earlier and aggressive fluid resuscitation and conversion with diuretics easier to manage than oliguric only few require dialysis much lower mortality Questions ?