Diuretics- Chapter 28.pptx

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Chapter 28

Diuretic Drugs
 Diuretic Drugs
 Drugs that accelerate the rate of urine formation
 Result in the removal of sodium and water
 Used in the treatment of hypertension, heart
failure (HF), and renal failure

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 Role of Kidneys
 Play an important role in the day-to-day
functioning of the body
 Filters toxic waste products
 Conserves essential substances
 This balance is maintained by the nephron.

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 Kidney Structure
 Nephron is main structural unit of the kidney.
 Diuretics exert their effect in the nephron.
 Initial filtering of blood takes place in the
glomerulus.
 Glomerular filtration rate (GFR)
 Afferent arterioles
 Efferent arterioles

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 Kidney Structure (Cont.)
 Proximal convoluted tubule (proximal tubule)
 Returns 60% to 70% of sodium and water from the
filtered fluid back to the bloodstream
 Passive reabsorption of chloride and water
 Loop of Henle (ascending)
 20% to 25% of sodium is reabsorbed here through active
chloride reabsorption.
 Distal convoluted tubule (distal tubule)
 Remaining 5% to 10% of sodium is reabsorbed here.
 Regulated by aldosterone
 Collecting duct
 Final pathway
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 Audience Response System
Question #1
Which location is the area where the highest
percentage of sodium and water are resorbed back
into the bloodstream?

A. Glomerulus
B. Proximal tubule
C. Ascending loop of Henle
D. Distal tubule

NOTE: No input is required to proceed.

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 Answer to System Question #1
ANS: B

The proximal convoluted (twisted) tubule or, more simply,
proximal tubule, anatomically follows the glomerulus and
returns 60% to 70% of the sodium and water from the filtered
fluid back into the bloodstream. Another 20% to 25% of
sodium is resorbed into the bloodstream in the ascending loop
of Henle. The remaining 5% to 10% of sodium resorption
takes place in the distal convoluted tubule, often called simply
the distal tubule, which anatomically follows the ascending
loop of Henle. The glomerulus does not resorb sodium or
water but instead is the point of initial filtration of the blood.

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 Pharmacology Overview
 Diuretics classified according to their sites of
action within the nephron, their chemical
structure, and diuretic potency

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 Types of Diuretic Drugs
 Carbonic anhydrase inhibitors (CAIs)
 Loop diuretics
 Osmotic diuretics
 Potassium-sparing diuretics
 Thiazide and thiazide-like diuretics

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Carbonic Anhydrase Inhibitors (CAIs)

 Chemical derivative of sulfonamide antibiotics
 Inhibit the activity of the enzyme carbonic
anhydrase
 Found in kidneys, eyes, and other parts of the body
 Acetazolamide (Diamox)
 Most commonly used CAI

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 Carbonic Anhydrase Inhibitors:
Mechanism of Action
 The enzyme carbonic anhydrase helps to make
H+ ions available for exchange with sodium and
water in the proximal tubules.
 CAIs block the action of carbonic anhydrase,
thus preventing the exchange of H+ ions with
sodium and water.

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 Carbonic Anhydrase Inhibitors:
Mechanism of Action (Cont.)
 Inhibition of carbonic anhydrase reduces H+ ion
concentration in renal tubules.
 As a result, there is increased excretion of
bicarbonate, sodium, water, and potassium.
 Resorption of water is decreased, and urine
volume is increased.

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 Carbonic Anhydrase Inhibitors:
Indications
 Adjunct drugs in the long-term management
of open-angle glaucoma
 Used with miotics to lower intraocular pressure
before ocular surgery in certain cases
 Also useful in the treatment of
 Edema
 High-altitude sickness

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 Carbonic Anhydrase Inhibitors:
Contraindications
 Known drug allergy
 Hyponatremia
 Hypokalemia
 Severe renal or hepatic dysfunction
 Adrenal gland insufficiency
 Cirrhosis

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 Carbonic Anhydrase Inhibitors:
Adverse Effects
 Acidosis
 Hypokalemia
 Drowsiness
 Anorexia
 Paresthesias
 Hematuria
 Urticaria
 Photosensitivity
 Melena (blood in the stool)

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 Carbonic Anhydrase Inhibitors:
Interactions
 Because CAIs can cause hypokalemia, digoxin
toxicity may occur when CAIs are combined with
digoxin.
 Use with corticosteroids may also cause
hypokalemia.
 Increased effects of amphetamines,
carbamazepine, cyclosporine, phenytoin, and
quinidine with concurrent use of CAIs

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 Loop Diuretics
 Bumetanide (Bumex)
 Ethacrynic acid (Edecrin)
 Furosemide (Lasix)
 Torsemide (Demadex)

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 Loop Diuretics:
Mechanism of Action
 Possess renal, cardiovascular, and metabolic
effects
 Act directly on the ascending limb of the
loop of Henle to inhibit chloride and sodium
resorption
 Increase renal prostaglandins, resulting in the
dilation of blood vessels and reduced peripheral
vascular resistance
 Useful in treatment of edema

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 Loop Diuretics: Drug Effects
 Potent diuresis and subsequent loss of fluid
 Decreased fluid volume causes a reduction in
 Blood pressure
 Pulmonary vascular resistance
 Systemic vascular resistance
 Central venous pressure
 Left ventricular end-diastolic pressure
 Potassium and sodium depletion

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 Loop Diuretics: Indications
 Edema associated with HF or hepatic or renal
disease
 To control hypertension
 To increase renal excretion of calcium in patients
with hypercalcemia
 In cases of HF resulting from diastolic
dysfunction

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 Loop Diuretics: Adverse Effects
Body system Adverse effects

Central nervous system (CNS) Dizziness, headache, tinnitus,
blurred vision

Gastrointestinal (GI) Nausea, vomiting, diarrhea

Integumentary Stevens-Johnson (torsemide)

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Loop Diuretics: Adverse Effects (Cont.)
Body system Adverse effects

Hematologic Agranulocytosis, neutropenia,
thrombocytopenia

Metabolic Hypokalemia, hyperglycemia,
hyperuricemia

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 Loop Diuretics: Interactions
 Neurotoxic
 Nephrotoxic
 Increase serum levels of uric acid, glucose,
alanine aminotransferase, and aspartate
aminotransferase.
 Thiazide (metolazone): sequential nephron
blockade
 Nonsteroidal antiinflammatory drugs (NSAIDs)

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Loop Diuretics: Furosemide (Lasix)
 Most commonly used loop diuretic
 Uses: pulmonary edema and the edema
associated with HF, liver disease, nephrotic
syndrome, ascites, hypertension

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 Audience Response System
Question #2
When administering a loop diuretic to a patient, it is
most important for the nurse to determine if the
patient is also taking which drug?

A. Lithium (Eskalith)
B. Acetaminophen (Tylenol)
C. Penicillin
D. Theophylline

NOTE: No input is required to proceed.

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 Answer to System Question #2
ANS: A

Use of loop diuretics with lithium can increase the risk
of lithium toxicity. Drug interactions with loop diuretic
therapy can occur with concurrent use of nonsteroidal
antiinflammatory drugs (NSAIDs), and vancomycin can
cause increased neuro- and ototoxicity when used with
loop diuretics. There is no associated risk of drug
interaction when taking acetaminophen, penicillin, or
theophylline with loop diuretics.

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 Osmotic Diuretics
 Mannitol (Osmitrol)
 Most commonly used osmotic diuretic
 Urea
 Organic acids
 Glucose

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 Osmotic Diuretics:
Mechanism of Action
 Work mostly in the proximal tubule.
 Nonabsorbable, producing an osmotic effect
 Pull water into the renal tubules from the
surrounding tissues.
 Inhibit tubular resorption of water and solutes,
thus producing rapid diuresis.

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 Osmotic Diuretics:
Drug Effects
 Increases glomerular filtration rate and renal
plasma flow; helps to prevent kidney damage
during ARF
 Reduces intracranial pressure or cerebral edema
associated with head trauma
 Reduces excessive intraocular pressure

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 Osmotic Diuretics:
Indications
 Treatment of patients in the early, oliguric phase
of acute renal failure (ARF)
 To promote excretion of toxic substances
 To reduce intracranial pressure
 Treatment of cerebral edema

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 Osmotic Diuretics:
Adverse Effects
 Convulsions
 Thrombophlebitis
 Pulmonary congestion

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 Osmotic Diuretics:
Mannitol (Osmitrol)
 Intravenous (IV) infusion only
 May crystallize when exposed to low
temperatures
 Use of a filter is required.

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 Audience Response System
Question #3
While preparing an infusion of mannitol (Osmitrol), the nurse
notices small crystals in the IV tubing. What is the most
appropriate action by the nurse?

A. Administer the infusion slowly.
B. Discard the solution and obtain another bag of medication.
C.Obtain a filter and then infuse the solution.
D.Return the fluid to the IV bag to dissolve the crystals.

NOTE: No input is required to proceed.

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 Answer to System Question #3
ANS: B

Even though a filter should always be used with
this medication infusion, a solution with crystals
present in the bag or tubing should never be
infused. The nurse should first discard the solution
and then restart the infusion with a new bag,
ensuring that there is a filter on the IV line.

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 Potassium-Sparing Diuretics
 Amiloride (Midamor)
 Spironolactone (Aldactone)
 Triamterene (Dyrenium)
 Also known as aldosterone-inhibiting diuretics

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 Potassium-Sparing Diuretics:
Mechanism of Action
 Work in collecting ducts and distal convoluted
tubules.
 Interfere with sodium-potassium exchange.
 Competitively bind to aldosterone receptors.
 Block resorption of sodium and water usually
induced by aldosterone.

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 Potassium-Sparing Diuretics:
Drug Effects
 Prevent potassium from being pumped into the
tubule, thus preventing its secretion.
 Competitively block aldosterone receptors and
inhibit their action.
 Promote the excretion of sodium and water.

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 Potassium-Sparing Diuretics:
Indications
 Spironolactone and triamterene
 Hyperaldosteronism
 Hypertension
 Reversing potassium loss caused by potassium-losing
drugs
 Certain cases of HF: prevention of remodeling
 Amiloride
 Similar as spironolactone and triamterene, but
amiloride is less effective in the long term

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 Potassium-Sparing Diuretics:
Adverse Effects
Body system Adverse effects

CNS Dizziness, headache

GI Cramps, nausea, vomiting,
diarrhea

Other Urinary frequency, weakness,
hyperkalemia

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 Potassium-Sparing Diuretics:
Adverse Effects (Cont.)
 Spironolactone (Aldactone)
 Gynecomastia
 Amenorrhea
 Irregular menses
 Postmenopausal bleeding

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 Potassium-Sparing Diuretics:
Interactions
 Lithium
 Angiotensin-converting enzyme inhibitors
 Potassium supplements
 NSAIDs

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 Thiazide and Thiazide-Like Diuretics
 Thiazide diuretics
 Hydrochlorothiazide (Esidrix, HydroDIURIL)
 Chlorothiazide (Diuril)
 Thiazide-like diuretics
 Metolazone (Mykrox, Zaroxolyn)
 Chlorthalidone (Hydone, Thalitone)
 Indapamide (Lozol)

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 Thiazide and Thiazide-Like Diuretics:
Mechanism of Action
 Inhibit tubular resorption of sodium, chloride, and
potassium ions
 Action primarily in the distal convoluted tubule
 Result: water, sodium, and chloride are excreted
 Potassium is also excreted to a lesser extent.
 Dilate the arterioles by direct relaxation

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 Thiazide and Thiazide-Like Diuretics:
Drug Effects
 Lowered peripheral vascular resistance
 Depletion of sodium and water (and potassium)
 Thiazides should not be used if creatinine
clearance is less than 30 to 50 mL/min (normal
is 125 mL/min).
 Metolazone remains effective to a creatinine
clearance of 10 mL/min.

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 Thiazide and Thiazide-Like Diuretics:
Indications
 Hypertension (one of the most prescribed group
of drugs for this)
 Edematous states
 Idiopathic hypercalciuria
 Diabetes insipidus
 Adjunct drugs in management of heart failure
and hepatic cirrhosis

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 Thiazide and Thiazide-Like Diuretics:
Adverse Effects
Body system Adverse effects

CNS Dizziness, headache, blurred
vision
GI Anorexia, nausea, vomiting,
diarrhea
Genitourinary Impotence

Hematologic Jaundice, leukopenia

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 Thiazide and Thiazide-Like Diuretics:
Adverse Effects (Cont.)
Body system Adverse effects
Integumentary Dizziness, headache, blurred
vision
Metabolic Hypokalemia, hyperglycemia,
hyperuricemia, hypochloremic
alkalosis

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 Nursing Implications
 Perform a thorough patient history and physical
examination.
 Assess baseline fluid volume status, intake and
output, serum electrolyte values, weight, and
vital signs (especially postural blood pressure).
 Assess for disorders that may contraindicate or
necessitate cautious use of these drugs.

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 Nursing Implications (Cont.)
 Instruct patients to take the medication in the
morning if possible to avoid interference with
sleep patterns.
 Monitor serum potassium levels during therapy.

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 Nursing Implications (Cont.)
 Teach patients to maintain proper nutritional and
fluid volume status.
 Teach patients to eat more potassium-rich foods
when taking any but the potassium-sparing
drugs.
 Foods high in potassium include bananas,
oranges, dates, apricots, raisins, broccoli, green
beans, potatoes, meats, fish, and legumes.

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 Nursing Implications (Cont.)
 Patients taking diuretics along with a digitalis
preparation should be taught to monitor for
digitalis toxicity.
 Patients with diabetes mellitus who are taking
thiazide or loop diuretics should be told to
monitor blood glucose and watch for elevated
levels.

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 Nursing Implications (Cont.)
 Teach patients to change positions slowly and to
rise slowly after sitting or lying to prevent
dizziness and fainting related to orthostatic
hypotension.
 Encourage patients to keep a log of their
daily weight.
 Remind patients to return for follow-up visits and
lab work.

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 Nursing Implications (Cont.)
 Patients who have been ill with nausea,
vomiting, or diarrhea should notify their primary
care providers because fluid and electrolyte
imbalances can result.
 Signs and symptoms of hypokalemia include
muscle weakness, constipation, irregular pulse
rate, and overall feeling of lethargy.

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 Nursing Implications (Cont.)
 Instruct patients to notify their primary care
providers immediately if they experience rapid
heart rates or syncope (reflects hypotension or
fluid loss).
 Excessive consumption of licorice can lead to
additive hypokalemia in patients taking thiazides.

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 Nursing Implications (Cont.)
 Monitor for adverse effects:
 Metabolic alkalosis, drowsiness, lethargy,
hypokalemia, tachycardia, hypotension, leg cramps,
restlessness, decreased mental alertness
 Monitor for hyperkalemia with potassium-sparing
diuretics.

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 Nursing Implications (Cont.)
 Monitor for therapeutic effects:
 Reduction of edema
 Reduction of fluid volume overload
 Improvement in manifestations of HF
 Reduction of hypertension
 Return to normal intraocular pressures

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 Case Study
A patient with a creatinine clearance of 20 mL/min is
admitted to the medical-surgical unit. The patient is in
need of rapid diuresis.
1. Which class of diuretic does the nurse anticipate
administering?

A. Potassium sparing
B. Thiazide
C. Osmotic
D. Loop
NOTE: No input is required to proceed.

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Answer to Case Study Question #1
ANS: D

The loop diuretics provide rapid diuresis because
of their rapid onset of action. Loop diuretics are
effective for patients with reduced kidney function
(creatinine clearance below 25 mL/min).

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 Case Study
The patient is ordered furosemide (Lasix).
2. Before administering furosemide, it is most
important for the nurse to assess the patient for
allergies to which drug class?

A.Aminoglycosides
B.Sulfonamides
C.Macrolides
D.Penicillins

NOTE: No input is required to proceed.

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Answer to Case Study Question #2
ANS: B

The nurse should assess patients receiving furosemide
(Lasix) for cross-sensitivity to sulfonamides. Although allergy
to sulfonamide antibiotics is listed as a contraindication,
analysis of the literature indicates that cross-reaction with the
loop diuretics is unlikely to occur. Loop diuretics are
commonly given to such patients in clinical practice. The
nurse should closely monitor these patients.

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 Case Study
Two days after admission, the nurse is reviewing laboratory results
of the patient.
3. Which is the most common electrolyte finding resulting from the
administration of furosemide (Lasix)?

A. Hypocalcemia
B. Hypophosphatemia
C. Hypokalemia
D. Hypomagnesemia

NOTE: No input is required to proceed.

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Answer to Case Study Question #3
ANS: C

Of all of the adverse effects of furosemide (Lasix)
administration, hypokalemia is of serious clinical
importance. To prevent hypokalemia, patients often
receive potassium supplements along with
furosemide. The other electrolyte disturbances
listed do not occur as a result of furosemide (Lasix)
therapy.

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 Case Study
The patient is being discharged home with furosemide (Lasix).
4. When providing discharge teaching, which instruction will
the nurse include?

A. Avoid prolonged exposure to the sun.
B. Avoid foods high in potassium content.
C. Stop taking the medication if you feel dizzy.
D. Weigh yourself once a week and report a gain or
loss of more than 1 pound.

NOTE: No input is required to proceed.

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Answer to Case Study Question #4
ANS: A

Patients taking furosemide (Lasix) should avoid prolonged
exposure to the sun because the drug can cause
photosensitivity. Although orthostatic hypotension is a possible
adverse effect of the medication, patients should not stop
taking the medication without consultation with their health
care provider. Patients should weigh themselves once a day
and report a weight gain or loss of approximately 3 pounds.
Patients taking furosemide (Lasix) should be encouraged to
eat foods rich in potassium.

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