NURS 1060 Exam 3 Drug Interactions, Adverse Reactions, and Errors PDF

Summary

This document is an exam review for NURS 1060, focusing on drug interactions, adverse reactions, and errors. It covers various concepts and examples of drug-drug and drug-food interactions, along with measures for reducing adverse effects.

Full Transcript

Drug Interactions,
Adverse Reactions,
and Errors
NURS 1060: Exam 3
Outcome

 Describeprinciples of safe, patient-centered,
evidence- based nursing care to adults at
the basic level, guided by the Caritas
philosophy.
 Describequality improvement measures in
healthcare micro and macro systems that
impact patient care.
Competency

 Describe factors that create a culture of
safety related to medication administration.
 Describequality improvement measures use
to reduce medication errors.
Concept

 Clinical Decision Making: A process used to examine and
determine the best actions to meet desired goals; requires
anticipating, recognizing and organizing patient problems to
respond with urgency and/or importance in a preferential order to
avoid or minimize adverse changes in a patient’s condition.
 Safety: Minimizing risk of human harm through both system
effectiveness and individual performance.
 Cultural & Diversity:
 Culture – patterns of behavior and thinking that people living in social
groups learn, develop, and share.
 Diversity – the array of differences among individuals, groups, and
communities.
Unit Outcomes

 Discuss concepts related to drug-drug
interaction.
 Identify the impact of food on drug absorption.
 Define common adverse drug reactions.
 Explain how to report concerns about drugs,
products or equipment to the FDA
 Identify the purpose of Patient Medication
Guides and Boxed Warnings.
Unit Outcomes

 Identify types and causes of medication
errors.
 Identify methods to reduce medication
errors.
 Identifyfactors that contribute to individual
variation in drug responses.
 Discuss the concept of pharmacodynamic
tolerance.
 Define pharmacogenomics.
Drug Interactions
Drug-Drug Interactions

 Interactionscan occur whenever a patient
takes more than one drug.
 Some interactions are intended and desired or
unintended and undesired.
 Patients frequently take more than one drug.
 Multiple drugs to treat one disorder
 Multiple disorders requiring different drugs
 OTC meds, caffeine, nicotine, alcohol, etc.
Consequences of
Drug-Drug Interactions
 Intensification of effects
 Increased therapeutic effects
 Increased adverse effects
 Reduction of effects
 Reduced therapeutic effects
 Reduced adverse effects
 Cancreate and unknown chemical when
mixing two drugs that will be given
parenteral
 (check a drug compatibility chart)
 Increased therapeutic effects

Drug-Drug Sulbactam and ampicillin two separate
drug combined into one antibiotic PCN
Interactions + Beta Lactamase Inhibitor
Sulbactam = Beta Lactamase Inhibitor
Ampicillin = broad spectrum penicillin
Combination prolongs and intensifies
Intensificatio ampicillin effect

n of Effects Increased adverse effects

Examples Aspirin and Warfarin
Antiplatelet + Anticoagulant = Risk
for ?
Drug-Drug Inhibitory – interactions that result in
reduced drug effects (Reduced
therapeutic effects)

Interactions Propranolol and albuterol
Propranolol = cardiovascular drug
Albuterol = bronchodilator to treat asthma
Propranolol + albuterol = propranolol reduces
albuterol effects

Reduction Reduced adverse effects

of Effects Naloxone to treat morphine overdose
Morphine reduces respirations – give naloxone to
block morphine receptor binding

Examples
Drug-Drug  Creation
of a unique or
Interactions unknown response
 Alcohol with Barbiturate can
be lethal
Examples
Direct Chemical or Physical
Interaction

Never combine
Check the drug
drugs in the same
compatibility
container or
chart or in the
syringe without
Electronic Clinical
establishing
Support system
compatibility.
Basic Mechanisms of Drug-Drug
Interactions
Pharmacokinetic Interaction Examples
 Altered absorption
 Drugs that depress peristalsis
 Drugs that induce vomiting
 Altered distribution
 Competition for protein binding
 Altered metabolism
 Phenobarbital is an inducing agent that increases the
synthesis/production of hepatic cytochrome P450 (CYP) enzymes
responsible for the metabolism of many drugs
 Altered renal excretion
 Drugs can alter Filtration, Reabsorption, Active secretion
Basic Mechanisms of Drug-Drug
Interactions
Pharmacokinetic Interactions
 Interactions that involve P-glycoproteins (PGPs)-
Transmembrane protein that transports a wide variety of drugs
out of cells
 Reduction or increased PGP
 Intestinal epithelium: affects absorption
 Placenta: affects drug export from placental cells to maternal blood
 Blood-brain barrier: affects drug export from cells of brain capillaries
into the blood
 Liver: affects drug export from liver into bile
 Kidney tubules: affects drug export from renal tubular cells into the
urine
  At the same receptor
 Antagonist/agonist
Basic  At separate receptor sites
Mechanisms of  May be potentiative
Drug-Drug  A potentiative effect is one in
Interactions which one drug intensifies the
effects of another.
Pharmacodyna  Both Warfarin and aspirin suppress

mic Interactions blood clotting, and the
combination may increase the risk
of bleeding.
Minimizing Adverse
Drug-Drug Interactions
 Minimize number of drugs a patient receives.
 Take a thorough drug history.
 Adjust
the dosage when metabolizing
inducers are added or deleted.
 Beespecially vigilant when patient is taking
a drug with a low therapeutic index.
 Drug-Food
Interactions
Drug-Food Interactions
Decreased Absorption
 Examples:
 Calcium-containing foods
 Milk and Tetracycline- calcium binds to tetracycline and
is insoluble
 High-fiber foods
 Some drugs must be taken
Drug-Food on an empty stomach.
Interactions The absorption of some drugs
can be significantly reduced by
Timing of food; these drugs should be
taken on an empty stomach,
Drug which is 1 hour before a meal
Administratio or 2 hours after a meal.
n Other drugs should be
taken with food.
Drug-Food Interactions
Impacting Drug Metabolism Example
 The grapefruit juice effect (not occurring with
other citrus fruits or juices) ONLY grapefruit juice
contains 4 compounds that cause this effect
 Inhibits the metabolism of certain drugs
 Inhibits CYP enzyme found in the liver and also in the
intestinal wall
 Major effect is on oral drugs after they have been
absorbed
 Effect can last up to 3 days after the last glass
 Raises the drugs level in blood
Drug-Food Interactions
Impact on Drug Action Example
 Foods high in vitamin K- reduced warfarin
effects
Drug-Herb Interactions

 Prescription and OTC drugs can interact with herbal
preparations.
 Interactions with herbal medicines are just as likely
as with prescription medications.
 Reliable information on drug-herb interactions is
lacking.
 Example of known interaction:
 St. John’s Wort induces drug-metabolizing enzymes and
reduces blood levels of many drugs.
Adverse Drug Reactions
 Adverse drug
reactions (ADRs)
Two Related Also known as adverse
Issues of drug events (ADEs)
Drug Safety
Medication errors
Adverse Drug Reactions

= any unintended or undesired effect that
occurs at doses normally used for
treatment
 Excludes excessive dosages
 Can range from annoying to life-threatening
 Defined by the World Heath Organization
Adverse Drug Reactions
Scope of the Problem
 Mild reactions
 Drowsiness, nausea, itching, and rash
 Severe reactions (potentially fatal)
 Respiratory depression, neutropenia, hepatic
injury, anaphylaxis, hemorrhage
 Most common in the elderly and very young
Terms Related to Adverse
Drug Reactions
Side effect

= A nearly unavoidable secondary drug effect produced
at therapeutic doses
May develop soon after drug is initiated or not until drug
has been taken for weeks or months

Toxicity

= the degree of detrimental physiologic effects caused by
excessive dosing (or decreased metabolism or
excretion, decreased hepatic or renal function)
Terms Related to Adverse
Drug Reactions
Allergic reaction

= Immune response: Occurs with the second dose or later doses
Requires sensitization of the immune system
Patient’s sensitivity to a drug can change over time.
Very few drugs cause severe allergic reaction.
Most common examples: Penicillins, Sulfonamides

Idiosyncratic effect

=An uncommon drug response resulting from a genetic predisposition
Example: Succinylcholine-induced paralysis
Usually brief paralysis like during surgery
Idiosyncratic effect- May last for hours in genetically predisposed
patient
Terms Related to Adverse
Drug Reactions

Iatrogenic disease

Iatrogenic = disease produced by drugs
Example: drugs for antipsychotic
disorders can cause Parkinson’s-like
symptoms)
Teratogenic effect

Drug-induced birth defect
Hepatotoxic Drugs

 Can cause of liver failure
 As some drugs undergo metabolism, they are
converted to toxic products that can injure liver
cells.
 Combining hepatotoxic drugs may increase the risk
for liver damage—for example, acetaminophen and
alcohol.
 Monitor labs: aspartate aminotransferase (AST) and
alanine aminotransferase (ALT) for liver injury.
Nephrotoxic Drugs

 Cancause acute or chronic damage to the
kidneys
 Sometimes caused by IV contrast given for
CT scans or other radiology tests
 Monitor urine output, labs- BUN and Cr
Drugs and Life-Threatening
Dysrhythmias
 Some drugs increase risk to develop life-threatening
dysrhythmias
 Dysrhythmia Examples:
 Torsades - a form of ventricular tachycardia
 V-fibrillation - if Torsade recurs and may degenerate into ventricular
fibrillation.
 Minimizing the risk
 Monitor heart rhythm- EKG, telemetry
 Monitor electrolytes- (low potassium and low magnesium-
risk for dysrhythmias)
Identifying Adverse Drug Reactions

 Did symptoms appear shortly after the drug was
first used?
 Did symptoms stop/decrease when the drug was
discontinued?
 Did symptoms reappear when the drug was
reinstituted?
 Is the illness itself sufficient to explain the event?
 Are other drugs in the regimen sufficient to explain
the event?
Black Boxed Warnings

Strongest safety warning a drug can carry and still
remain on the market

Used to alert providers to potential side effects and to
ways to prevent or reduce harm from these side
effects.

Placed on any drug that, although useful, has serious
side effects; this is a way to keep drugs on the market
while protecting patients.
Black Box Warning
Example
 Fluoroquinolone Antibiotics
According to the FDA, people taking a
fluoroquinolone antibiotic have an increased
risk of tendinitis and tendon rupture, a serious
injury that could cause permanent disability.
The FDA warning includes Cipro
(ciprofloxacin), Levaquin (levofloxacin), Avelox
(moxifloxacin) and other medications
containing fluoroquinolone. (Warning issued
July 2008.)
Medication Errors
Medication Errors

 Risk
for error in hospitals is high because
each medication order is processed by
several people.
 Thenurse is the last person in this
sequence.
 Thus,
the nurse is the last line of defense
against mistakes.
 This
places a heavy responsibility on the
nurse for ensuring patient safety.
Categories of Serious Med Errors

90% percent of fatal or serious medication errors fall into three categories:
 Human factors;
 Giving a drug IV (intravenously) instead of IM (intramuscularly)
 Communication mistakes;
 Writing a prescription so that it is illegible
 A complete order; contains the medication, dose, route, and time.
 Unacceptable abbreviations; QD; it should be written out as “daily”; U
should be units
 Name confusion;
 Giving a drug with a name that sounds like the name of another drug
 Electronic order entry

Encourage patients be active,
Methods to informed members of the healthcare
team
Reduce
Cultivate a just/fair environment
Medication
Address system problems instead of individual
Errors shaming
Institutional culture dedicated to safety
Tools/information needed to prescribe,
dispense, and administer drugs safely
 Case Study

 A patient was
admitted to the
hospital to receive a
regimen of
furosemide.
 A correct order was
written by the
physician and
appropriately sent to
the pharmacy.
Case Study Continued

A pharmacist erroneously
entered twice the written dose of
furosemide into the
computerized medication
administration record (MAR). A
second pharmacist, who was
expected to independently
compare the MAR, to the
physician’s order, initialed the
prepared medication as correct.
Case Study Continued

 The incorrect dose was sent to the
floor. The administering nurse
appropriately checked for the two
pharmacists' signatures, but was
also expected to, along with a
second nurse, to independently
compare the dose on the medication
to the written physician order. Both
nurses initialed the medication as
correct, and the drug administration
was initiated.
Case Study Continued

 Before all of the medication had
infused, there was a change in
nursing shift. The next nurse,
compared the dose on the
medication bag to the written
order, discovered the error,
immediately stopped the
furosemide, assessed the patient,
called the attending physician and
averted an adverse drug event
(ADE) for the patient.
  Who made an error?
 How did they make and error?
Case Study
 What can be done to prevent
Reflection
this error from occurring in the
future to another patient?
Clinical Decision-Making
Question
 Situation:Patient was given a
medication that was not ordered
for them?
 What is the FIRST action of the
nurse after identifying a
medication error has occurred?
 50% of all new drugs have serious ADRs
that are not revealed during Phase II and
Phase III trials.

Adverse
Reactions Be alert for unusual responses when
giving new drugs.
to New
Drugs Drugs that you suspect
of causing a previously MedWatch: the
FDA Medical
unknown adverse Products
effect should be Reporting Program
reported
MedWatch

FDA Medical Products Report online Voluntary reporting by
healthcare professionals of
Reporting Program www.fda.gov/medwat serious harm to a patient
ch Anycaused
drug: newby;
and old
Products : example Baby formula
Medical equipment: example IV pump
Individual Variation in
Drug Response
Individual = Factors that cause
Variation in one patient to respond
Drug to drugs differently than
another patient
Responses
Individual Variation in Drug Responses
Pathophysiology

Liver disease Kidney disease
Reduced metabolism and increased Reduced excretion and increased
toxicity toxicity
Age and Variation in Drug
Responses
 Older adults and infants are the two groups
most sensitive to drugs because of
differences in organs that absorb,
metabolize, and excrete drugs.
 In the older adult, organ degeneration
accounts for these differences, whereas in
infants the differences are related to organ
immaturity.
Biological Sex and Variation in Drug
Responses
 Until 1997, almost all clinical drug trials were
performed on males.
 Females may have more toxic effects with some
drugs and fewer toxic effects with others. Not all
drugs are influenced by hormonal changes. Females
metabolize some drugs more slowly and other drugs
more quickly.
 Unless drug trials are performed in both females
and males, the effects of drugs in women will not be
clear.
Individual Variation in Drug
Responses
Tolerance
 Toleranceis a decreased responsiveness
to a drug as a result of repeated drug
administration
 Higher doses required to get the desired affect
 Common categories of drug tolerance
 Pharmacodynamic tolerance
 Metabolic tolerance
  Results when a patient
takes a drug over a
period of time.
 Adaptive processes occur
in response to chronic
receptor occupation. The
Pharmacodynami result is that the body
c Drug Tolerance requires increased
drug, or an increased
MEC, to achieve the
same effect.
 Often occurs with opioid
narcotic analgesics for
chronic pain
  Resultingfrom
accelerated drug
Metabolic metabolism
Drug  Example:

Tolerance Phenobarbital
increases enzyme
production
Pharmacogenomic
s
= study of how genes
affect individual drug
responses
Pharmacogenomics
Genetics can impact:
 Drug metabolism
 May accelerate or reduce the rate of metabolism
 Drug receptors
 Geneticvariations alter the structure of drug
receptors.
 Individual
may not have the receptor required for
“Lock and Key” fit
Pharmacogenomics

 Individual Pharmacogenomics is the study of
the ways genetic variations cause individual
responses to drugs through a person’s unique
genes that provide their code for drug-
metabolizing enzymes and drug receptors.
 Future Possibilities:
 Pharmacogenomic may be used to determine if a drug
will or will not help an individual
 In theory, stop “trial-and-error” approach of
prescribing