Drugs Affecting Cardiovascular System PDF

Summary

This document provides an overview of drugs that affect the cardiovascular system, including their uses, mechanisms of action, side effects, and nursing implications. It covers various types of drugs, such as antihyperlipidemics, antihypertensives, and those used for angina and myocardial infarction. Different classes of each type of drug are detailed, with explanations and examples.

Full Transcript

Drugs that Affect the
Cardiovascular System
NP02L021 ELO A · Version 2.0

Care of the Patient with a Cardiovascular Disorder
Introduction to Clinical Pharmacology, 10th ed., pp. 134 – 138; pp, 140 – 162
Introduction to Critical Care Nursing, 8th ed., pp. 297 – 328
TERMINAL LEARNING OBJECTIVE
Determine nursing care for a patient with a disorder of the
heart without error.
LEARNING STEP ACTIVITIES
1. Explain the use of antihyperlipidemic drugs
2. Explain the use of antihypertensive drugs
3. Explain the use of drugs for angina and myocardial
infarction
5 MOST COMMON TYPES OF
CARDIOVASCULAR DRUGS
Antihyperlipidemics
Antihypertensives
Drugs for angina
Drugs for heart failure
Antidysrhythmics
ANTIHYPERLIPIDEMIC DRUGS
HYPERLIPIDEMIA
High level of lipids, primarily cholesterol and other fatty
acids in the blood- primarily produced by the liver.
HMG-CoA (STATINS)
Action
HMG-CoA is a liver enzyme
Controls cholesterol production

Use
Lower blood LDL levels
Reduces risk
SIDE EFFECTS

Abdominal pain Sore throat
Headache Heartburn
Diarrhea Elevated glucose
Myalgia levels
Joint discomfort
HMG-CoA (Statins)
Adverse Effects
Liver dysfunction
Pancreatitis
Myositis
Rhabdomyolysis

Life Span Considerations
Not used in pregnancy and breastfeeding

Examples
Atorvastatin
Simva statin
Lova statin
Pravastatin
Rosuvastatin
HMG-CoA (Statins)
Drug interactions
Alcohol and acetaminophen
Liver toxicity
Aspirin and antacids
Decrease effectiveness
Grapefruit juice
Risk for toxic effects
NURSING IMPLICATIONS
Monitor liver function tests and CK levels
Assess for signs of rhabdomyolysis
Assess for pregnancy or breastfeeding
Review low-cholesterol diet
Take in the evening for best effectiveness
PATIENT TEACHING
Avoid alcohol
Report severe muscle aches, changes in urine color or
decreased urine output
Avoid grapefruit juice
Follow up care is required for regular lab work
Signs of liver problems
CHECK ON LEARNING
A patient states they can now eat whatever they like because the
medication “will take care of it.” The nurse explains the patient must
follow a low-cholesterol diet because HMG-CoA reductase inhibitors
(Statins) work by_____________________________.

a. Lowering LDL levels by increasing liver cholesterol production
b. Diet change isn’t necessary since the drugs remove dietary
cholesterol
c. Lowering LDL levels by slowing liver cholesterol production
d. Preventing blood clots from forming
NON-STATIN HYPERLIPIDEMIC
Use: Lower LDL levels

Selective Cholesterol Absorption Inhibitors
Action: Limits the absorption of cholesterol from food through
the intestinal wall
Example: ezetimibe

Fibric Acid Derivatives (Fibrates)
Action: Lowers triglycerides and increases HDL levels
Example: gemfibrozil, fenofibrate
Cause liver toxicity and cholelithiasis
NON-STATIN HYPERLIPIDEMIC
Bile Acid Sequestrants
Action: Increase excretion of cholesterol and reduces LDL
levels by bile loss through the feces
Example: cholestyramine, colestipol

Niacin or Nicotinic Acid
Action: Inhibits a hormone-sensitive lipase in adipose tissue
Example: Niacin
Not commonly used due to adverse effects
NON-STATIN HYPERLIPIDEMIC
Nursing Implications
Assess diet history
Assess liver function test and cholesterol
Avoid alcohol
Give supplemental vitamins K, A, D, E
Give at appropriate times
Fibric give 30 minutes before meals BID
Bile sequestrants give 1-2 times a day before meals and mix with water,
milk, or juice
Patient Teaching
Notify healthcare provider that you are taking cholesterol-lowering
drug
CHECK ON LEARNING

True/False:

Liver function tests should be closely monitored for patient
take non-statins.
ANTIHYPERTENSIVE DRUGS
HYPERTENSION
Disorder in which patient’s blood pressure is consistently
elevated
Without treatment may cause organ damage
Heart
Brain
Kidney
Primary
Cause unknown
Secondary
Blood pressure change is due to a specific cause
DIURETICS
Action: Indirectly lowers blood pressure by reducing fluid volume

Thiazide: prevents reabsorption of water, Na, K and Cl and dilates
arterioles
Example: hydrochlorothiazide
Thiazide-like: prevents reabsorption of water, Na, K and Cl and dilates
arterioles
Example: indapamide
Loop diuretics: increase urine output by blocking active transport in Loop
of Henle
Example: furosemide
Potassium-sparing: increase excretion of water and Na
Example: spironolactone
Uses
Treat HTN, heart failure, and cirrhosis of the liver
 SIDE EFFECTS ADVERSE EFFECTS

Urinary urgency and Dehydration
frequency Hypokalemia
Sign of decreased volume Thiazides
Fluid and electrolyte Loop
imbalances Hyperkalemia
Increased uric acid Potassium-sparing
(Thiazide) Hyponatremia
INTERACTIONS
Antibiotics
Lithium
Medications that cause potassium imbalances
NURSING IMPLICATIONS
Assess change in vital signs
Hold with blood pressure < 90/60
Assess for dehydration
Monitor daily weight
Assess lab work
Administer in the morning
Provide bedside commode or urinal
Monitor peripheral edema
Strict intake and output
PATIENT TEACHING
Stand up slowly to prevent orthostatic hypotension
Signs of low or high potassium
Report tinnitus
Diet changes by increasing/decreasing foods high in
potassium
Avoid salt substitutes
Diabetics should monitor glucose levels closely
CHECK ON LEARNING
What laboratory values must be closely monitored while a
patient is taking a diuretic?

a. Glucose
b. Potassium
c. BUN and creatinine
d. All of the above
RENIN-ANGIOTENSIN-ALDOSTERONE
SYSTEM DRUGS
RENIN-ANGIOTENSIN-ALDOSTERONE
SYSTEM DRUGS
Use: Hypertension and heart failure
Actions:
Angiotensin-converting enzyme inhibitor (ACE-I): stops
conversion of angiotensin I to angiotensin II
Examples: captoPRIL, enalaPRIL, lisinoPRIL,

Angiotensin II receptor blocker (ARB): blocks the
vasoconstrictor and aldosterone-secreting effects of
angiotensin II
Examples: loSARTAN, valSARTAN, irbeSARTAN, candeSARTAN
SIDE EFFECTS
Hyperkalemia
Dry cough with ACE-I
Angioedema
Not take during pregnancy
CHECK ON LEARNING

Most ACE-Inhibitors end in ____________, while morse
ARBs end in ______________.
CALCIUM CHANNEL BLOCKERS
CALCIUM CHANNEL BLOCKERS
Uses: Chronic stable angina, hypertension, dysrhythmias
Actions:
Inhibits the calcium influx across the cell membrane which
relaxes coronary artery smooth muscle, dilation of coronary
arteries and peripheral veins (decreases workload)
Slow conduction of electrical impulses through SA & AV nodes
(slows heart rate)
Examples: verapamil, nifedipine, diltiazem, amlodipine
CALCIUM CHANNEL BLOCKERS

SIDE EFFECTS CONTRAINDICATIONS
Dysrhythmias Cardiogenic shock
Fatigue Heart block
Dizziness Hypotension
Headache Heart failure
Flushing
Steven-Johnson Syndrome
Avoid grapefruit and
grapefruit juice
CHECK ON LEARNING
What is the mechanism of action for calcium channel blockers?
(Select all that apply)

a. Inhibits the ability of calcium to enter heart muscle cells, which
slows conduction of electrical impulses through the SA and AV
nodes
b. lower blood pressure by preventing water, sodium, potassium, and
chloride from going through the walls of the nephron to be
reabsorbed into the blood
c. stops the conversion of angiotensin I to angiotensin II
d. Inhibits the calcium influx across the cell membrane reducing the
amount of calcium available for arterial smooth muscle contraction
ADRENERGIC DRUGS
BETA BLOCKERS
Uses: CAD, hypertension, angina pectoris, heart failure,
dysrhythmias, MI, PVCs
Action:
Blocks the beta 1 receptor from the effects of norepinephrine
and epinephrine
Lowers blood pressure
Slows heart rate
Dilates smooth muscle of arteries, increasing oxygen supply to heart
Examples: propranOLOL, metoprOLOL, nadOLOL,
atenOLOL
BETA BLOCKERS

SIDE EFFECTS CONTRAINDICATIONS
Bradycardia Cardiogenic shock
Hypotension Heart blocks
Masks signs of hypoglycemia Bradycardia
Decreased sexual ability
Dizziness
Drowsiness
Difficulty sleeping
Weakness
DO NOT STOP – Rebound
HBP
CHECK ON LEARNING
What is a condition that can be masked by beta blockers?

a. Tachypnea
b. Bleeding
c. Hypoglycemia
d. Stomach irritation
ALPHA 1 ADRENERGIC ANTAGONIST
Alpha Blockers
Uses: Hypertension
Action:
Blocking alpha 1 adrenergic receptor sites leading to
decreased peripheral vascular resistance and decreased blood
pressure.
Examples: doxAZOSIN, prAZOSIN, terAZOSIN
Side effects:
First dose effect – sudden hypotension
Severe orthostatic hypotension – give at night
Fluid retention
CHECK ON LEARNING
Why should a patient not drive or operate machinery after
taking the first dose of an Alpha-1 antagonist (blocker)?
ALPHA 2 ANTAGONIST
Uses: Hypertension that is difficult to manage
Action:
Works in brain to activate alpha 2 receptors causing
vasodilation and decreased blood pressure
Examples: clonidine, clonidine transdermal patch,
methyldopa
Side effects:
Dry mouth and nasal congestion
DO NOT STOP – rebound hypertension
CHECK ON LEARNING
Why are Alpha 2 agonists only used in patients with difficult
to manage HBP?

a. They act centrally on the CNS cause a high risk of side
effects.
b. They are cheaper than all the other drugs.
c. They are given in transdermal patches.
d. They are easier to get than all the other drugs.
VASODILATORS
Uses: Hypertension
Action:
Dilatation of artery and venous systems to decreased PVR,
improving blood flow and decreasing workload of the heart
Examples: hydralazine, minoxidil
Side effects:
Significant hypotension
Daily weights and report swelling of hands or feet – fluid
retention
DO NOT STOP – rebound HBP
NURSING IMPLICATIONS AND
PATIENT TEACHING
Avoid sudden changes in position
Take medication at the same time everyday as prescribed
Avoid alcohol
Avoid OTC meds
Withhold medication HR< 60 BPM or SBP < 90 mm HG
Patient with IV calcium channel blocker needs a cardiac
monitor
Monitor BP
Daily weight
Teach proper techniques for home BP and HR monitoring
ANGINA AND MYOCARDIAL
INFARCTION DRUGS
ANGINA VS. MYOCARDIAL
INFARCTION
Chest pain caused by lack of oxygen to the heart muscle
 Angina

Blood flow to heart muscle significantly reduced and
muscle dies  Myocardial infarction
NITRATES
Uses: chronic stable angina pectoris, prophylaxis for angina pain
Action:
Dilate blood vessels by relaxing smooth muscle in the peripheral venous
system (preload) and reducing resistance to blood flow in the arterial
system (afterload)
Reduces work of the heart
Examples
Nitroglycerine (NTG): only nitrate (SL, lingual spray, IV) may be used form
acute attack of angina
Isosorbide mononitrate: management of angina
 SIDE EFFECTS ADVERSE EFFECTS
Throbbing headaches Severe postural
Slight drop in blood hypotension
pressure Reflex tachycardia
Paradoxical bradycardia
Vertigo
Severe weakness
DRUG INTERACTIONS
Alcohol, antihypertensive drugs, opioids, and diuretics
Caffeine, pseudoephedrine, methylphenidate and antidiabetic
medications
Erectile dysfunction medications
NURSING IMPLICATIONS/
PATIENT TEACHING
Assess BP and HR before and during treatment
Acute attacks give NTG sublingual
Repeat the dose every 5 minutes X 3 doses. If no relief, call 911
Wear gloves
Store NTG is a dark container
Assess for lightheadedness, dizziness and headache
Teach patient to keep nitroglycerin bottle on their person
Place the buccal tablet between check and gum or under the tongue
Place NTG patches on skin in the morning and remove at bedtime
Do not drink alcohol
Change positions slowly
Caution use when taking medication for erectile dysfunction
CHECK ON LEARNING
Why should the nurse wear gloves when applying NTG
ointment (Select all that apply)

a. PPE and hygiene requirement
b. Avoid absorption into skin
c. Wearing gloves is not necessary
d. To auscultate the apical pulse better
ANTIDYSRHYTHMIC DRUGS
DYSRHYTHMIA
Abnormal heart rhythm caused by irregularity of the
cardiac conduction system
Cells do not have enough oxygen or damaged
Disease
Electrolyte imbalance
Result is alteration in cardiac output
ANTIDYSRHYTHMIC DRUGS
Use: Restore the rhythm to normal and maintain adequate cardiac
output
Action:
Class I (Sodium channel blockers)
Examples: quinidine, procainamide)

Class II (Beta blockers)
Example: propranolol

Class III (Potassium channel blockers)
Example: amiodarone

Class IV (calcium channel blockers)
Example: diltiazem, verapamil
Other Drugs
Examples: digoxin, magnesium sulfate
SIDE EFFECTS/ADVERSE EFFECTS
Side Effects
Hypotension
Other dysrhythmias
Adverse Effects
Other dysrhythmias
NURSING IMPLICATIONS/
PATIENT TEACHING
Sodium channel blockers
Monitor the heart rate and BP
Avoid OTC medications
Quinidine can cause significant GI side effects
Give med exactly as scheduled
Monitor patient weight and urine output
Teach family members to assess for confusion
NURSING IMPLICATIONS/
PATIENT TEACHING
Potassium channel blockers
Monitor for common side effects
Monitor the respiratory status
Teach patient about light sensitivity
Side effects may not appear for several days to weeks
May cause bluish discoloration of face, neck and arms
Schedule regular eye exams
Report pain or selling in scrotum to healthcare provider
Assess apical heart rate before giving medication
Obtain EKG before giving medication
Telemetry
CHECK ON LEARNING
Why is it important to assess an apical pulse, instead of a
radial pulse, before administering and antidysrhythmic
medication?
INOTROPIC DRUGS
CARDIAC GLYCOSIDE
PHOSPHODIESTERASE INHIBITORS
Use: Advanced heart failure and in critical care areas to
improve cardiac output
Action:
Decreases the speed of conduction through the AV node
Activates contractile proteins in the heart muscle, increasing
their ability to contract
Example: digoxin, milrinone, dobutamine
DIGOXIN

ADVERSE EFFECTS DRUG INTERACTIONS
Toxicity: anorexia, nausea, Beta blockers, calcium
vomiting, diarrhea, yellow gluconate, calcium chloride,
vision, palpitations succinylcholine and
Anxiety verapamil
Depression Any drug that changes
electrolyte balance
Confusion
Older adults at risk for toxicity
NURSING IMPLICATIONS/
PATIENT TEACHING
Monitor closely for digoxin toxicity
Monitor potassium levels
May be given a loading dose of medication
Monitor therapeutic level of medication
Take apical pulse before administration
Give at the same time every day
Take missed dose within 12-hours of scheduled time, never double
dose
Report signs of toxicity
Report chest pain, dyspnea or peripheral edema
Teach sources of potassium
CHECK ON LEARNING
What electrolyte level can significantly increase the risk of
digoxin toxicity?

a. Low sodium
b. High potassium
c. High sodium
d. Low potassium
REVIEW OF MAIN POINTS
1. Explain the use of antihyperlipidemic drugs
2. Explain the use of antihypertensive drugs
3. Explain the use of drugs for angina and myocardial
infarction
QUESTIONS