Hyperkalemia and its management
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Dec 02, 2014
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About This Presentation
Prepared by:
Dr. Muhammad Asim Fazal
MEEQAT GENERAL HOSPITAL
ALMADINAH ALMUNAWARAH
Slide Content
HYPERKALEMIA AND ITS MANAGEMENT Prepared by: Dr. Muhammad Asim Fazal MEEQAT GENERAL HOSPITAL ALMADINAH ALMUNAWARAH
Definition Brief review of potassium regulation processes Causes Clinical Manifestations Therapy Objectives
Hyperkalemia = plasma K+ concentration > 5.1mmol/L Critical hyperkalemia = plama K+ concentration > 6.5 mmol /L Definition
-The normal serum level of potassium is 3.5 to 5 mmol/L -Daily Requirements 1-1.5 mmol /kg -Dietary sources include dried fruits; legumes; meats; poultry; fish; soy; bananas; citrus fruits; potatoes; tomatoes; broccoli; mushrooms; dark, leafy green vegetables
Intracellular concentration about 150 mmol /L The passive outward diffusion of K+ is the most important factor that generates the resting membrane potential. Maintenance of steady state requires K+ ingestion = K+ excretion Nearly all regulation of renal K+ excretion and total body K+ balance occurs in the distal nephron, via principal cells Potassium secretion regulated by aldosterone and plasma K+ concentration Potassium Regulation Review
Potassium homeostasis T his excess is (10%) excreted through the gut (90%) excreted through the kidneys - The most important site of regulation is the distal nephron , including the distal convoluted tubule, the connecting tubule, and the cortical collecting tubule -Gastrointestinal absorption is complete, resulting in daily excess intake of about 1 mmol/kg/d
Potassium release from cells Excessive Intake Decreased renal loss Iatrogenic (Consider pseudohyperkalemia) Causes of Hyperkalemia
Intravascular hemolysis Tumor Lysis Syndrome Rhabdomyolysis Metabolic acidosis Hyperglycemia Severe Digitalis toxicity Hyperkalemic periodic paralysis Beta-blockers Succinylcholine; especially in case massive trauma, burns or neuromuscular disease Potassium release from cells
- Uncommon cause of hyperkalemia . -The mechanisms for shifting potassium intracellularly and for renal excretion allow a person with normal potassium homeostatic mechanisms to ingest virtually unlimited quantities of potassium in healthy individuals. -Most often, it is caused in a patient with impaired mechanisms for the intracellular shift of potassium or for renal potassium excretion Excessive intake
-Is the most common cause -The causes of decreased renal potassium excretion include: renal failure diabetes mellitus sickle cell disease Decreased excretion M edications ( eg , potassium-sparing diuretics, NSAID, angiotensin -convening enzyme inhibitors)
Causes Shift from (ICF to ECF) Decreased renal excretion Excessive intake Hyperosmolality rhabdomyolysis tumor lysis Succinylcholin insulin deficiency acute acidosis. Diabetes mellitus ( esp diabetic nephropathy Renal failure Congestive heart failure SLE Sickle cell anemia NSAID ACE Inhibitor Potassium sparing Diuretics Multiple Myeloma chronic partial urinary tract obstruction Oral or IV Potassium Supplementation Salt substitute Blood transfusion
Pseudohyperkalemia -It is the term applied to the clinical situation in which in vitro lysis of cellular contents leads to the measurement of a high serum potassium level not reflective of the true in vivo level. -Condition occurs most commonly with red cell hemolysis during the blood draw (tourniquet too tight or the blood left sitting too long),
Weakness, which can progress to flaccid paralysis and hypoventilation . Secondary to prolonged partial depolarization from the elevated K+ , which impairs membrane excitability . Metabolic acidosis, which further increases K+ Secondary to hyperkalemia impairing renal ammoniagenesis and absorption, and thus net acid excretion. Altered electrical activity of heart, cardiac arrhythmias . ECG changes in order of appearance: Tall, narrow-based, peaked T waves Prolonged PR interval and QRS duration AV conduction delay Loss of P waves Progression of QRS duration leading to sine wave pattern Ventricular fibrillation or asystole Clinical Manifestations
W eakness and fatigue(most common) fFank muscle paralysis S hortness of breath Palpitations Symptoms
-Vital signs generally are normal E xcept bradycardia due to heart block or tachypnea due to respiratory muscle weakness. Physical
Lab Assess renal function. Check serum BUN and creatinine levels to determine whether renal insufficiency is present Check 24-hour urine for creatinine clearance Estimate the glomerular filtration rate (GFR)
ECG Changes occur when Serum Potassium >6.0 mmol /L A-Initial T Wave s peaked or Tented B-Next ST depression loss of P Wave QRS widening C-Final Biphasic wave (sine wave) QRS and T fusion
Measure complete metabolic profile -Low bicarbonate may suggest hyperkalemia due to metabolic acidosis. -Hyperglycemia suggests diabetes mellitus.
Treatment The first step -determine life-threatening toxicity. By Perform an ECG to look for cardiotoxicity. - if present Administer Iv Calcium Gluconate to ameliorate cardiac toxicity. -Initial dose: 10 ml over 2-5 minutes Second dose after 5 minutes if no response -Effect occurs in minutes and lasts for 30-60 minutes Anticipate EKG improvement within 3 minutes
The second step -Is to identify and remove sources of potassium intake -Change the diet to a low-potassium diet.
-Measure glucose and potassium every 2 hours -Correct metabolic acidosis with sodium bicarbonate. 50ml I/V bolus - Ventolin Nebulization The third step -Potassium shift from intravascular to intracellular -Glucose and Insulin Infusion Insulin Regular 10 units IV 50 ml 50% of dextrose
The fourth step - I s to increase potassium excretion from the body -in normal kidney function by the administration of parenteral saline accompanied by a loop diuretic, such as furosemide Dose: 20-40 mg IV.
-Discontinue potassium-sparing diuretics, angiotensin -converting enzyme inhibitors, angiotensin receptor blockers, and other drugs that inhibit renal potassium excretion. Monitor volume status and aim to maintain euvolemia . -In patients with hyporeninemia or hypoaldosteronism Renal excretion can be enhanced by administration of an aldosterone analogue, such as 9-alpha fluorohydrocortisone acetate ( Florinef ).
Emergency dialysis I s a final recourse for unresponsive hyperkalemia with renal failure.
A 52-year-old man with hypertension and diabetes complains of weakness, nausea, and a general sense of illness, that has progressed slowly over 3 days. His medications include a sulonylurea, a diuretic, and an ACE inhibitor. On examination, he appears lethargic and ill. His BP is 154/105 mm Hg, HR 70bpm, temperature 98.6° F, and respiratory rate 22 breaths/min. The physical examination reveals moderate jugular venous distension, some minor bibasilar rales, and lower extremity edema. He is oriented to person and place but is able to give further history. The ECG shows a wide complex rhythm. Laboratory studies performed are significant for potassium 7.8 mEq/L, BUN is 114 mg/dL and creatinine is 10.5. Clinical Scenario
Diagnostics/Images: ECG
Easily Distinguished ECG signs: peaked T wave. prolongation of the PR interval ST changes (which may mimic myocardial infarction) very wide QRS, which may progress to a sine wave pattern and asystole. Patients may have severe hyperkalemia with minimal ECG changes, and prominent ECG changes with mild hyperkalemia. ECG Changes of Hyperkalemia
Diagnosis: Hyperkalemia- Severe Classification of Hyperkalemia NORMAL: 3.5 to 5.0 mEq/L. MILD: 5.5 to 6.0 mEq/L SEVERE: Levels of 7.0 mEq/L or greater It is important to suspect this condition from the history and ECG , because laboratory test results may be delayed and the patient could die before those test results become available. Analysis
1 st Line option
Symptoms of hyperkalemia are usually nonspecific, so risk factors must be used to suspect the diagnosis ECG changes consistent with hyperkalemia should be treated immediately as a life-threatening emergency. Do not await laboratory confirmation. Intravenous calcium is the antidote of choice for life-threatening arrhythmias related to hyperkalemia , but its effect is brief and additional agents must be used Clinical Pearls
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