Hypokalemia & Hyperkalemia PPT (2)
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Transcript of Hypokalemia & Hyperkalemia PPT (2)
Hypokalemia & HyperkalemiaNurs 306 Pharmacology – Group 3
Rebecca HavardElena Ibanez
Gabrielle Javier-FavelaDiana Jones
Corinna KaliszKristi Kimura
What is kalemia?• The presence of potassium in
the blood
• Normal range: 3.5 – 5 mEq/L
• Hypokalemia = low levels of potassium, deficient potassium
• Hyperkalemia = high levels of potassium, excess potassium
Physiology ReviewNa+ / K+ Pump
Helpful mnemonic =
think of the pump as a fishing boat
Sea water (Na+) out / Fish (K+) in
Review PhysiologyNa+ / Ca2+ Exchanger
Helpful mnemonic =
Drink milk after spicy (and salty) food!
Hypokalemia
Hyperkalemia
HypokalemiaResults from•Increased entry of K+ into cells
• Reduced intake of K+ in diet & increased losses of K+ from body
• Diuretics / Diuretic effects
•Decreased gastric fluid in GI from vomiting/diarrhea results in increased renal compensation
Decreased fluid and Na+ stimulates aldosterone = loss of renal K+ (Na+/K+ pump)
• K+ shifts from ECF -> ICF in exchange for H+ to maintain plasma acid-base balance (pH) during respiratory or metabolic alkalosis
K+ in the ICF -> hypokalemia
Serum Potassium concentration < 3.5 mEq/L
HypokalemiaSerum Potassium
concentration < 3.5 mEq/LWe need more potassium!!!
HypokalemiaPossible Causes/Risk Factors
1. Actual total body K+ lossa. excessive use of medications, such as diuretics and corticosteroidsb. increased secretion of aldosteronec. vomiting, diarrhead. wound drainagee. prolonged nasogastric suctionf. excessive diaphoresisg. kidney disease
2. Inadequate K+ intake
3. Movement of potassium from the extracellular fluid to the intracellular fluid
a. Alkalosisb. Hyperinsulinism
4. Dilution of serum potassiuma. water intoxicationb. IV therapy with potassium-deficient solutions
Serum Potassium concentration < 3.5 mEq/L
HypokalemiaPossible Causes/Risk Factors•Certain antibiotics (carbenicillin, gentamicin, amphotericin B)
•Certain drugs, called diuretics, that can cause excess urination
•Diarrhea and vomiting (including the use of too many laxatives, which can cause diarrhea)
•Diseases that affect the kidney's ability to retain potassium (Liddle syndrome, Cushing syndrome, hyperaldosteronism, Bartter syndrome, Fanconi syndrome)
•Eating disorders (such as bulimia)
•Eating large amounts of licorice or using products, such as herbal teas and chewing tobaccos that contain licorice made with glycyrrhetinic acid (no longer used in licorice made in the United States)
•Sweating
Serum Potassium concentration < 3.5 mEq/L
HypokalemiaSerum Potassium
concentration < 3.5 mEq/LClinical Manifestations1. ECG
- Early: Flat or inverted T wave, Prominent U wave, DT segment depression, prolonged QU interval.
- Late: Prolonged PR interval, decreased voltage and widening of QRS interval, increased risk of ventricular dysrhythmias.
HypokalemiaClinical Manifestations
2. Assess: LOC and orientation (Patient may be confused, apathetic, anxious, irritable, or in severe cases, even comatose.)
3. Rate and depth of respirations, color of nail beds and mucous membranes
4. Possible weak and thready pulses, heart rate variability (Apical pulse may be excessively slow or excessively rapid, depending on the type of dysrhythmia present.)
5. Presence of skeletal muscle weakness (AEB bilateral weak hand grasps, inability to stand, hyporeflexia, and profound flaccid paralysis in advanced stages of hypokalemia.)
6. Abdominal distention and hypoactive bowel sounds
Serum Potassium concentration < 3.5 mEq/L
HypokalemiaClinical Manifestations
7. Patient’s blood pressure when she or he is lying down, sitting, and standing (postural hypotension)
Serum Potassium concentration < 3.5 mEq/L
HypokalemiaComplications
Balance of potassium is needed on the intracellular and extracellular levels for muscle contraction, nerve impulses, metabolism, and homeostasis.
Change in levels of potassium change neuromuscular control (nerve and muscle)
Potassium works in the cell to let the muscle know when to relax and contract (Na+/K+ pump). Too much or too little potassium changes muscle control and causes them to weaken.
Serum Potassium concentration < 3.5 mEq/L
HypokalemiaComplications
When there’s too little K+
Arrhythmias: The cardiac heart muscles are affected by the low K+ and cannot contract.
Cardiac Arrest…Death: Decreasing levels of K+ will eventually stop the cardiac heart muscles leading to cardiac arrest and possibly death.
Paralysis: Muscles can continually weaken and damage to paralysis
Serum Potassium concentration < 3.5 mEq/L
HypokalemiaSerum Potassium
concentration < 3.5 mEq/L
Hypokalemia
Hyperkalemia
HyperkalemiaSerum Potassium
concentration > 5 mEq/L
HyperkalemiaSerum Potassium
concentration > 5 mEq/LResul ts f rom
• Mnemonic = AIDS
• Acidosis – Metabolic acidosis: bicarbonate is low, pH become acidic
low blood pH causes H+ to go into the cell and cause lysis so that it releases its potassium content into the blood stream
K+ leaking out to ECF -> hyperkalemia
• Insulin Deficiency – normally insulin binds to the Na+ / K+ pump that causes K+ to flow into the cell and Na+ out of the cell.
when insulin can’t bind, K+ can’t flow into the cell, and stays outside
K+ in the ECF -> hyperkalemia
HyperkalemiaSerum Potassium
concentration > 5 mEq/LResul ts f rom
• Drugs
1. Digitalis or Digoxin: competes with K+ at the Na+ / K+ pump
Takes the place of K+, decreasing cellular K+ and making it stay outside of the cell
K+ in the ECF -> hyperkalemia
HyperkalemiaSerum Potassium
concentration > 5 mEq/LResul ts f rom
• Drugs
2. Succinylcholine: causes up-regulation of nicotinic acetylcholine receptors on the muscle membrane
up-regulation causes the amount of receptors to increase, resulting in K+ efflux into the plasma
3. Beta blockers: take the place of beta agonists
stop activation of cyclicAMP, then protein kinase, and then phosphorylation of the the sodium potassium ATPase pump
Can’t pump out K+, so K+ stays outside of the cell
K+ in the ECF -> hyperkalemia
HyperkalemiaSerum Potassium
concentration > 5 mEq/LPossib le Causes/Risk Factors
1. The body experiences decreased K+ excretion…
• Renal failure - impaired renal function causes electrolyte retention
• Potassium - sparing diuretics (given for HF)cause loss of Na+ & Ca2+ while saving K+
• Adrenal insufficiency - imbalance of K+ when adrenal glands don’t produce the right amount of aldosterone
HyperkalemiaSerum Potassium
concentration > 5 mEq/LPossib le Causes/Risk Factors
2. The body experiences a cellular shift of K+ from cells to ECF…
• Tumor lysis syndrome: massive release of K+ from cells
• Rhabdomyolysis: damaged skeletal muscle releases toxic intracellular constituents into circulation
• Metaboic acidosis: acid-base balance disorder causing electrolyte imbalance
• Diabetic ketoacidosis: severe electrolyte imbalance with dehydration
• Drug-induced diuresis: loss of too much K+ from polyuria (adverse effects of ACE inhibitors)
HyperkalemiaSerum Potassium
concentration > 5 mEq/LCl in ica l Mani festat ions
1. ECG
- Early: Increased T wave amplitude or peaked T waves. Middle: Prolonged PR interval and QRS duration, atrioventricular conduction delay, loss of P waves.
- Late: Progressive widening on QRS complex and merging with T wave to produce sine wave pattern.
HyperkalemiaSerum Potassium
concentration > 5 mEq/LCl in ica l Mani festat ions
2. Assess: Heart rate (may be slowed with or without irregular or extra beats)
3. Significant muscle weakness that progresses upward from legs to trunk
4. Paresthesia of the face, feet, hands, and tongue may occur
5. General anxiety and irritability
6. Low urinary output
7. Nausea and vomiting (due to hyperactivity of GI smooth muscle)
HyperkalemiaSerum Potassium
concentration > 5 mEq/LCompl icat ions
When there’s too much K+
Arrhythmias: The cardiac heart muscles cannot efficiently contract and relax. This alters the rate or rhythm of the heartbeat. Ventricular fibrillation can occur in which the ventricles flutter rapidly instead of pumping blood.
Cardiac Arrest… Death: Imbalance of potassium causes muscles to decrease in efficiency (cramping, fatigue) eventually causing the heart to fail.
HyperkalemiaSerum Potassium
concentration > 5 mEq/L
References
Dugdale, D. C., & (2013, Oct 31). High potassium levels. (2 Feb. 2014) Retrieved from,
http://www.nlm.nih.gov/medlineplus/ency/article/001179.htm
Huether, S. (2012). Understanding pathophysiology, 5th edition. St.
Louis: Elsevier Inc.
MyOptumHealth. Hypokalemia. N.p., n.d. (5 Feb. 2014). Retrieved from,
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view=prelogin.learn.learnLanding&command=DiseasesAndConditions&article=7876d666b1259110VgnVCM
1000005220720a>.
Potter, Patricia, Anne Perry, Patricia Stockert, Amy Hall (2013). Fundamentals of Nursing, 8th Edition. Mosby Inc.
Schambelan, M., Sebastian, A., Biglieri, E.G. (1979). Prevalence, pathogenesis, and functional significance of
aldosterone deficiency in hyperkalemic patients with chronic renal insufficiency. Kidney International, 17,
89-101.
Silvestri, Linda. Saunders Comprehensive Review for the NCLEX-RN Examination. 6th ed. N.p.: Saunders, an
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