Treatment of Pain

Question 1

Pain is difficult to catch up with; (…) are more effective when given (…) pain increases

Answer 1

• analgesics
• before

Question 2

What is the chemical name for acetaminophen and the abbreviation?

Answer 2

• N-acetyl-para-aminophenol
• APAP

Question 3

What is the mechanism of action of acetaminophen?

Answer 3

• not full understood
• possibly blocks central (not peripheral) prostaglandin production

Question 4

What are the uses of acetaminophen?

Answer 4

• antipyretic
• analgesic

Question 5

What are the different formulations of acetaminophen?

Answer 5

• oral: capsule, tablet (chewable and ER), elixir, gel, liquid, solution, suspension, syrup, sachet (tear open and put into water)
• rectal suppository
• IV

Question 6

What are the advantages to using acetaminophen vs other pain medications?

Answer 6

• no GI irritation
• almost no allergy
• no bleeding issues
• very safe at usual doses (TI approx. 10)
• safe in pregnancy

Question 7

What are the disadvantages of using acetaminophen vs other pain medications?

Answer 7

• poor anti-inflammatory action (treats pain/reduces fever but no inflammation)

Question 8

What are the side effects associated with acetaminophen use?

Answer 8

• methemoglobinemia, leukopenia rare (hemoglobin abnormal; cyanosis in babies)
• liver toxicity due to metabolite accumulation (more concerned about)

Question 9

What is the 2nd most common cause of liver disease that requires transplant?

Answer 9

liver toxicity due to acetaminophen use

Question 10

What are the different metabolite forms of acetaminophen?

Answer 10

• sulfate form
• glucuronide form
• N-acetyl-p-benzoquinone imine (NAPQI)

Question 11

What is acetaminophen normally metabolized by?

Answer 11

glucuronidation and sulfation with minor CYP2E1

Question 12

In acetaminophen, (…) is overwhelmed and metabolism shifts to (…), producing the toxic metabolite (…)

Answer 12

• phase II
• phase I
• NAPQI

Question 13

Describe the steps of normal acetaminophen metabolism and what happens when an overdose of acetaminophen occurs.

Answer 13

• acetaminophen is mainly metabolized through glucuronidation and sulfation (phase II) with a little being metabolized by CYP2E1 (oxidation/CYP450)
• when overdose occurs, there isn’t enough molecules for glucuronidation and sulfation to occur so more acetaminophen goes through CYP2E1 (phaseI) to be converted to NAPQI, which is toxic
• usually the small amt of NAPQI is detoxified/eliminated by glutathione conjugation, but there is only a certain amount of this to allow it to occur
• so in overdose, glutathione conjugation is overwhelmed from the large amount of NAPQI and NAPQI remains in the system to interact with cellular macromolecules and cause toxicity

Question 14

Toxic chronic doses of acetaminophen can occur when taken over time in a period longer than (…)

Answer 14

4 hours

Question 15

A normal dose of acetaminophen is (…) in patients with liver impairment

Answer 15

toxic

Question 16

What are risk factors for toxicity with acetaminophen? Explain each.

Answer 16

• malnutrition (decreased glutathione)
• chronic alcohol ingestion (induces 2E1)
• concomitant use of drugs that are CYP2E1 inducers
• young, febrile children (usually less serious, not intentional OD so severity will be less)

Question 17

• Describe adult acetaminophen OD?
• Describe child acetaminophen OD?

Answer 17

• more severe, more fatal
• more frequent, less severe

Question 18

Anything that induces (…) will facilitate acetaminophen to be converted to (…) causing toxicity

Answer 18

• 2E1
• NAPQI

Question 19

What are the different phases of acetaminophen toxicity?

Answer 19

• phase 1: up to 24 hours after intake
• phase 2: 18-72 hours later
• phase 3: 72-96 hours later
• phase 4: 4 days to 3 weeks later

Question 20

What are the symptoms associated with each phase of acetaminophen toxicity?

Answer 20

• phase 1: GI upset or no symptoms at all
• phase 2: RUQ pain +/- tenderness (liver); continued or new onset of GI issues
• phase 3: all of the above continue; hepatic dysfunction begins
• phase 4: resolution of symptoms and organ failure, if patient survives; complete resolution of hepatic damage may take months

Question 21

What is associated with hepatic dysfunction (acetaminophen toxicity)?

Answer 21

• coagulopathy
• jaundice/encephalopathy
• hypoglycemia (failing liver doesn’t product a lot of sugar)

Question 22

What are ways you can treat acetaminophen toxicity?

Answer 22

• activated charcoal (if ingestion occurred w/in an hour and patient is stable)
• n-acetylcysteine/NAC (acetadote) - always use in overdose situations w/ acetaminophen

Question 23

• How does n-acetylcysteine work in acetaminophen toxicity?
• What are the regimens for it?
• Which may be more effective in what time frames?

Answer 23

• provides cysteine group for glutathione synthesis (so NAPQI can be detoxified/eliminated)
  regimens:
• 72-hour oral or 21-hour IV
• oral mixed w/soda or juice and chilled
  effectiveness:
• oral may be more effective for pts presenting > 18 hours after ingestion
• IV is more effective for pts presenting within 12 hours

Question 24

What is the revised Rumack-Matthew Nomogram for the Acute Ingestion of Acetaminophen? (what it is used for)

Answer 24

• used to interpret serum concentrations of acetaminophen in relation to time since ingestion measured from ingestion of first dose, in order to assess potential hepatotoxicity
• acute = under 24 hours
• NAC administration to any patient with a blood level above the treatment line
• above treatment line: treat them; below treatment line: don’t treat them

Question 25

What are the different formulations of acetaminophen and associated doses?

Answer 25

• regular strength: 325 mg
• extra strength: 500 mg
• arthritis formula: 650 mg
• PM or nighttime formulations: tylenol PM contains (per tablet) 500 mg acetaminophen, 25 mg diphenhydramine (benedryl)
• excedrin: APAP 250 mg, ASA 250 mg (aspirin), 65 mg caffeine

Question 26

What is the max daily dose of acetaminophen in children/adults?

Answer 26

• children: 75 mg/kg/day and no more than 4000 mg
• adults: 4000 mg

Question 27

What is the minimum hepatotoxic single dose of acetaminophen in children/adults?

Answer 27

• children: 150 mg/kg
• adults: 7.5-10 grams

Question 28

Describe the arachidonic acid pathway.

Answer 28

• phospholipids are found in cells
• when cellular injury occurs, phospholipase A2 becomes active, releasing arachidonic acid into the system
• COX-1 enzyme can convert arachidonic acid into prostaglandins (PG) for GI mucosal protection and thromboxane (TXA) for platelet aggregation and vasoconstriction
• this pathway is constitutive so it is always on doing something, it just becomes enhanced in cellular injury situations
• COX-2 enzyme can convert arachidonic acid into prostaglandins (PG) to aid in pain, inflammation, fever, uterine contraction, vasodilation, and inhibition of platelet aggregation (decreased clotting)
• this pathway is inducible so it needs to be turned on
• LOX enzyme converts arachidonic acid to leukotrienes

Question 29

Corticosteroids can inhibit the enzymes associated with the (…) pathway, decreasing the amount of (…) produced

Answer 29

• arachidonic acid pathway
• prostaglandins, TXA, and leukotrienes

Question 30

• Cortisol is a (…). Describe this.
• Cortisol enhances the (…) response
• It stimulates the (…) leading to (…)
• Cortisol decreases (…) which can (…) response
• Cortisol can stabilize (…) which can (…)

Answer 30

• endogenous glucocorticoid - “gluco:” increase blood sugar via catabolism of protein and subsequent conversion into sugars and fats; gluconeogenesis
• enhances the sympathetic(stress) response
• stimulates the CNS leading to irritability, insomnia
• decreases WBCs which can lower the immune response
• stabilize intracellular lysosomes which can decrease cell injury

Question 31

What is the MOA of cortisol?

Answer 31

• inhibits synthesis of histamine, kinins, and prostaglandins (inhibit phospholipase A2)
• decrease inflammation and allergy (there are steroidal anti-inflammatory products)

Question 32

In fight/flight situations, the body releases (…) for energy

Answer 32

cortisol (increases blood sugar)

Question 33

• The body doesn’t know the difference between (…) cortisol
• You shouldn’t have cortisol released for (…)

Answer 33

• endogenous and exogenous cortisol
• extended periods of time

Question 34

• What is a prototypical agent glucocorticoids/cortisol?
• This mimics the actions of (…)
• What does this inhibit?

Answer 34

• prednisolone (active form)/prednisone (inactive form) - and every agent after
• mimics the actions of cortisol
• inhibits phospholipase A2

Question 35

What are the uses of prednisolone/prednisone?

Answer 35

• anti-inflammatory
• immunosuppressant
• decrease cell injury
• inhibit collagen synthesis - decrease scar tissue formation

Question 36

Describe the MOA of prednisolone/prednisone?

Answer 36

• inhibits phospholipase A2
• won’t release arachidonic acid
• COX-1 and COX-2 won’t be able to convert arachidonic acid to prostaglandins

Question 37

Prednisolone/prednisone is very (…)

Answer 37

very potent

Question 38

• Should patients with severe liver disease receive prednisolone or prednisone?
• Why?

Answer 38

• prednisolone
• liver will have a harder time breaking down prednisone (inactive) to make it active

Question 39

• Which corticosteroid is most similar to the bodies natural cortisol?
• How is this given?
• What are other corticosteroid drug names?

Answer 39

• hydrocortisone
• topical
  other corticosteroids:
• hydrocortisone
• cortisone (injection)
• prednisolone/prednisone
• methylprednisolone
• triamcinolone
• dexamethasone
• betamethasone

Question 40

What are the anti-inflammatory activity levels of all the corticosteroid drugs?

Answer 40

• hydrocortisone - 1
• cortisone - 0.8
• prednisolone/prednisone - 4
• methylprednisolone - 5
• triamcinolone - 5
• dexamethasone - 25-30
• betamethasone - 25

Question 41

What are the equivalent doses of corticosteroids?

Answer 41

• hydrocortisone - 20 mg
• cortisone - 25 mg
• prednisolone/prednisone - 5 mg
• methylprednisolone - 4 mg
• triamcinolone - 4 mg
• dexamethasone - 0.75 mg
• betamethasone - 0.75 mg

Question 42

Which corticosteroid may be the least potent? Most potent?

Answer 42

• hydrocortisone
• betamethasone

Question 43

• What corticosteroids have the longest duration of effect?
• What are their associated plasma/biologic half-lives?

Answer 43

dexamethasone:
- plasma half-life: 100-300 minutes
- biologic half-life: 36 hours
betamethasone:
- plasma half-life: 100-300 minutes
- biologic half-life: 35 hours

Question 44

What are some examples of corticosteroid uses?

Answer 44

• pulmonology/allergy - asthma, COPD, anaphylaxis
• dermatology - urticaria, contact dermatitis
• endocrinology - adrenal disorders
• GI - IBD
• hematology - hemolytic anemia, leukemia, lymphoma
• rheumatology - rheumatoid arthritis, dermatomyositis, lupus
• others - ophthalmology, organ transplant, lung maturation in newborns, cerebral edema, MS, post-MI

Question 45

• How do corticosteroids assist in post-MI or cerebral edema patients?
• What do corticosteroids do in patients with lymphoma, leukemia, multiple myeloma?
• Corticosteroids can be used as replacement therapy for (…) insufficiency, which is also known as (…) disease

Answer 45

• stabilize cells
• work by decreasing lymphocytes
• glucocorticoid insufficiency; Addison’s disease

Question 46

• What are the different routes of administration of corticosteroids?
• What is the route of administration determined by?
• You should always treat (…) when possible to avoid (…) exposure
• Adverse effects are (…) and (…) dependent in most cases

Answer 46

• oral, inhaled (ocular, intranasal), parenteral (IM, IV, intraarticular, intralesional)
• determined by illness
• locally; systemic exposure
• dose and duration dependent

Question 47

What are some short term adverse effects of corticosteroid use?

Answer 47

• decreased immune response (candidiasis; new or worsening bacterial infection)
• GI bleeding and ulcers
• hyperglycemia (releasing glucose)
• mood changes (irritability/instability; worsening psychiatric problems)
• increased appetite
• insomnia
• mineralocorticoid effects (sodium retention-increased BP; hypokalemia)
• pancreatitis
• electrolyte abnormalities

Question 48

Why are GI bleeds/ulcers a short term adverse effect of corticosteroids?

Answer 48

corticosteroids inhibit phospholipase A2, inhibiting arachidonic acid release and production of prostaglandins, so there is less protection of the stomach from mucosal lining and acid causes damage in the stomach

Question 49

What are some long term effects of corticosteroid use?

Answer 49

• growth suppression in children
• Cushing’s syndrome (moon face, buffalo hump, redistribution of fat on the body)
• adrenal suppression - atrophy of adrenal cortex (weakness, lethargy, anorexia, nausea, myalgia)
• cataracts and glaucoma
• cardiac effects (new onset afib, heart failure, ischemia)
• androgenic effects (amenorrhea, hirsutism-excessive hair growth)
• skin (thinning, bruising, stretch marks, acne)
• obesity
• hyperlipidemia
• muscle atrophy
• osteoporosis

Question 50

Why can corticosteroid use cause osteoporosis?

Answer 50

• inhibits osteoblasts and increases osteoclast activity
• affects collagen in bone
• decreases Ca+2 absorption in gut

Question 51

Corticosteroid use is contraindicated in what conditions/situations?

Answer 51

• systemic fungal infection
• don’t give with live vaccines when using immunosuppressive doses - delay for 3 months after discontinuation of corticosteroid use

Question 52

When should you use corticosteroids cautiously? (individuals with what conditions)

Answer 52

• diabetes
• PUD or active GI bleeding
• osteoporosis
• myasthenia gravis - may worsen symptoms (weakness in skeletal mm)
• cataracts/glaucoma
• pregnancy (cleft palate, hypoadrenalism-close to birth, baby will become dependent on corticosteroids)
• CNS disorders
• uncontrolled viral/bacterial infections

Question 53

What should you give to patients taking corticosteroids who have PUD?

Answer 53

proton pump inhibitor

Question 54

Why does adrenal suppression happen if taking corticosteroids long-term?

Answer 54

• glucocorticoids suppress pituitary release of ACTH
• zona fasciculata (cells that produce cortisol in adrenal gland) do not receive stimulation
• adrenal atrophy occurs

Question 55

How long does adrenal suppression take when using corticosteroids?

Answer 55

• several weeks of treatment are required
• long-acting and high dose products have highest risk
• topical and inhaled products are not a concern

Question 56

What can we do to decrease adrenal suppression in corticosteroid use?

Answer 56

• do not abruptly discontinue
• gradually taper doses over weeks to months (consider 6-15 months and monitor)

Question 57

What is the preferred treatment for adrenal insufficiency (corticosteroids)? Why?

Answer 57

hydrocortisone is preferred treatment for adrenal insufficiency as it more closely acts like endogenous cortisol (will probably be on for life)

Question 58

• Patients taking corticosteroids for (…) can stop abruptly?
• (…) often occurs even in short courses to avoid flare

Answer 58

• one week or less
• tapering

Question 59

• Abrupt discontinuation of corticosteroids when taking (…) can lead to adrenal suppression or flare of disease that was being treated
• Treatment over (…) can be tapered quickly to physiologic dose then weaned slowly
• (…) and (…) therapies require longer tapers over months in most cases
• (…) of patients is important

Answer 59

• for one week or less
• over 3 weeks
• long-term and high dose therapies
• close monitoring

Question 60

If a patient have a systemic fungal infection, what should they not receive/take?

Answer 60

corticosteroids

Question 61

What is the MOA of NSAIDS?

Answer 61

• block the production of prostaglandins via cyto-oxygenase inhibition (COX)
• COX converts arachidonic acid to other things, so when it is inhibited, you just have arachidonic acid sitting in your system

Question 62

What is the general function of NSAIDS?

Answer 62

• antipyretic
• anti-inflammatory
• analgesic
• inhibit platelet congregation

Question 63

What is the original, prototypical NSAID?

Answer 63

Aspirin

Question 64

What is another prototype for NSAID (other than aspirin)?

Answer 64

ibuprofen

Question 65

Efforts to decrease side effects and increase efficacy have led to the development of several (…)

Answer 65

NSAIDs

Question 66

What are the different types of NSAIDs?

Answer 66

• aspirin
• magnesium salicylate, diflunisal, salsalate, tolmetin
• fenoprofen, flurbiprofen, ketoprofen
  ibuprofen
• naproxen
• oxaprozin, meclofenamate, mefanamic acid, diclofenac, etodolac, indomethacin, sulindac, ketoralac
• nabumetone
• meloxicam, piroxicam
• celecoxib

Question 67

What is more potent the acetaminophen?

Answer 67

corticosteroids

Question 68

• Celecoxib is an NSAID that is selective for only (…)
• Low-dose Aspirin is an NSAID that is selective for (…)

Answer 68

• COX-2
• COX-1

Question 69

What is the general pharmacokinetics of NSAIDs:
- absorption
- metabolism
- excretion

Answer 69

• absorption: well absorbed; no interference from food
• metabolism: undergoes phase I, II, or both
• excretion: mostly renal; some undergo enterohepatic recycling; some may be excreted through bile

Question 70

• Repeated dosing of NSAIDs produces detectable levels in (…)
• Shorter half-life drugs stay present in (…) longer than would be expected, which could be important in ortho surgeries

Answer 70

• synovial fluid
• synovial fluid

Question 71

What are some general NSAID indications?

Answer 71

• headache
• fever
• rheumatoid arthritis
• osteoarthritis
• gout
• spondylitis
• soft-tissue injuries
• menstrual pain
• tendonitis

Question 72

Why would you not use corticosteroids instead of NSAIDs?

Answer 72

many of the indications for NSAIDs are long-term conditions and corticosteroids can cause severe effects if used for a long-amount of time

Question 73

• Aspirin specifically irreversibly binds (…) inhibiting (…), having (…) benefits
• All other NSAIDs are (…) bound

Answer 73

• COX-1
• inhibiting platelet aggregation
• cardiac benefits
• reversibly bound

Question 74

Indomethacin (NSAID) is used to close what?

Answer 74

PDA (patent ductus arteriosis)

Question 75

Describe the use of Ketorolac (NSAID)? (how long it is used, why it isn’t used longer)

Answer 75

• short-term use (5 days total) for opioid-level pain
• very high rate of GI events and renal toxicity
• poor inflammatory effects

Question 76

What are general NSAID side effects?

Answer 76

• GI
• Renal
• Cardiovascular

Question 77

What are the GI NSAID side effects? Why?

Answer 77

• ulcers, bleeding
• because COX-1 is inhibited, so there is less mucosal protection

Question 78

What are the renal NSAID side effects?

Answer 78

• prevents afferent arteriolar vasodilation
• hypertension
• acute kidney injury
• decreased sodium excretion

Question 79

What are the cardiovascular NSAID side effects?

Answer 79

increased risk of stroke or MI

Question 80

What is the mechanism of NSAIDs preventing afferent arteriolar vasodilation causing renal damage?

Answer 80

• NSAIDs don’t allow afferent arteriolar vasodilation so when it clamps down, afferents can open it back up
• efferent arterioles take fluid out, so when afferent arterioles are clamped down, there is less fluid in the glomerulus which you want it to be full
• causes renal damage

Question 81

You should use NSAIDs with caution in patients with what conditions?

Answer 81

• MI/CHF
• HTN
• renal disease
• anticoagulant or antiplatelet meds

Question 82

If you use NSAIDs in patients on anticoagulants or antiplatelets, what do you run the risk of?

Answer 82

patient developing an uncontrollable bleed

Question 83

What are some more general side effects and cautions of NSAID use?

Answer 83

• GI issues (nausea, vomiting, GI bleed, ulceration)
• bleeding
• fluid retention
• allergy
• anemia/dyscrasias
• tinnitus (esp. w/ high doses)

Question 84

Why do NSAIDs cause nausea and vomiting?

Answer 84

drug itself is acidic

Question 85

What side effects of NSAID use are more common in chronic and/or high dose administration?

Answer 85

• fluid retention
• anemia/dyscrasias
• tinnitus

Question 86

What are the NSAID black box warnings?

Answer 86

• cardiovascular risk: can increase thrombotic events, can be fatal; ibuprofen contraindicated in setting of coronary artery bypass graft surgery
• GI risk: bleeding, ulceration, perforation of stomach or intestine, can be fatal; elderly patients are at greater risk for serious GI events

Question 87

• Ibuprofen is contraindicated in the setting of what?
• (…) patients are at a greater risk for serious GI events with NSAID use

Answer 87

• coronary artery bypass graft surgery
• elderly patients

Question 88

• Aspirin irreversibly inhibits (…) and (…)
• At low doses, aspirin is selective for (…)
• Platelets cannot make new enzymes; it takes (…) to reverse the effects of ASA on platelet inhibition
• Platelets cannot be (…)

Answer 88

• COX-1 and COX-2
• COX-1
• 7-10
• activated

Question 89

What are the uses of aspirin?

Answer 89

• inflammation
• pain
• fever

Question 90

What can you use aspirin for at low doses?

Answer 90

• MI prophylaxis
• transient ischemic attack

Question 91

When using aspirin for cardioprotection, what should you not do?

Answer 91

do not take other NSAIDs within 2 hours of ASA

Question 92

Why can you use ASA for MI prophylaxis and transient ischemic attacks in low doses?

Answer 92

• prevents platelets from aggregating

Question 93

Why does it take 7-10 days to reverse the effects of ASA on platelet inhibition?

Answer 93

because binding of ASA is irreversible, so the body needs to make new platelets not bound to ASA

Question 94

If you take ASA with other NSAIDs, what do you increase the risk of?

Answer 94

increase the risk of bleeding

Question 95

• What are the most common side effects of aspirin use?
• Aspirin is contraindicated in patients with a history of what? Why?

Answer 95

• GI upset and ulcers
• patients with a history of GI bleed, hemophilia, and other bleeding disorders
• Because ASA side effects include bleeding

Question 96

Which NSAID is the only one considered an antiplatelet?

Answer 96

aspirin

Question 97

How many patients will develop a bleed within 1 year of taking ASA regularly?

Answer 97

1 in 1000

Question 98

• (…) can occur with long term use or high doses of ASA.
• This can cause what to happen?
• ASA use increases risk of (…) attack
• You should use ASA with caution in patients who have (…)

Answer 98

• salicylism (increased salicylate)
• vomiting, tinnitus, hearing loss, vertigo
• gout attack
• asthma - can cause asthmatic attack

Question 99

If aspirin is being used with another NSAID and we want the effects of aspirin to occur, what do we need to do and why?

Answer 99

• give ASA first: there is a binding site on COX-1 and we want aspirin to get there first and irreversibly bind
• if another NSAID is given first, it will get there before ASA so ASA cannot bind

Question 100

Aspirin overdose is commonly seen at (…) tablets of (…) each

Answer 100

• 20-35 tablets
• 325 mg each

Question 101

What are aspirin overdose symptoms?

Answer 101

• respiratory alkalosis and metabolic acidosis
• hyperthermia
• seizures, coma, death

Question 102

How is aspirin overdose treated?

Answer 102

• treated with activated charcoal (if ingestion is recent)
• hemodialysis if very severe or worsening
• no antidote, only supportive care and hope they get better

Question 103

Why should you not have children and teens take aspirin?

Answer 103

reye’s syndrome (swelling in the brain and liver)

Question 104

• Celecoxib blocks (…)
• It is preferable to use after (…) because there is no risk of (…)
• This is also good for (…) therapy

Answer 104

• COX-2
• surgery; no risk of bleeding
• long term therapy

Question 105

Celecoxib is a safe alternative with patients on (…)

Answer 105

anticoagulants

Question 106

What is the process of choosing an NSAID?

Answer 106

• illness (consider FDA approval)
• response to different NSAID varies among patients; ask if anything has worked for them in the past
• consider comorbidities
• bleeding risk
• pain level
• side-effects
• drug interactions
• dosing frequency
• cost
• length of therapy
• availability

Question 107

• What is the dosing of ibuprofin,ASA, and naproxin for inflammation?
• Why is this important?

Answer 107

• Ibuprofen: 600 mg QID
• ASA: 1200-1500 mg TID
• Naproxen: 375 mg BID
• importance: bottle instructions do not tell you this, so it may be better to write a prescription for this rather than having pt go by it OTC

Question 108

Crude resin from opium poppy seeds containing several alkaloids, one of which is morphine (10%)

Answer 108

opium

Question 109

Naturally occurring compounds: morphine, codeine, thebaine, and papaverine

Answer 109

opiate

Question 110

All agents with the same functional and pharmacological properties of opiates

Answer 110

opioid

Question 111

Per DEA: “refers to opium, opium derivatives, and their semi-synthetic substitutes”

Answer 111

narcotic

Question 112

What is 10% of what comes out of opium?

Answer 112

morphine

Question 113

(…) are endogenous morphine

Answer 113

endorphins

Question 114

What is the background of opioids?

Answer 114

• used for 1000s of years to treat pain
• 1803: morphine isolated from opium
• 1973: radioactive morphine showed specific areas of uptake in mice - morphine receptors

Question 115

• When researchers found that there was uptake of morphine in mice, they found (…)
• They discovered that physiologic receptors bind to (…)
• Looking for endogenous ligand led to the discovery of (…) in the 1980s
• What were some of these endorphins?

Answer 115

• morphine receptors
• endogenous substances
• endorphins
• enkephalins, endorphins, dynorphins

Question 116

• After the discovery of morphine receptors and endorphins, we now know that there are many (…) in the body
• Opioids primarily act on which receptors (each have subtypes)?
• (…) are the most important analgesic receptors

Answer 116

• receptors
• mu, kappa, delta
• mu receptors

Question 117

• What was the opioid prototype?

Answer 117

morphine

Question 118

• Morphine is a very strong (…) agonist
• What is the primary target for opioids?
• Other opioids have been compared against (…) to determine potency
• Why is the structure of morphine important?

Answer 118

• mu receptor agonist
• mu-receptor
• morphine
• changing the structure can change things like efficacy, potency, side-effects, etc.

Question 119

What are therapeutic uses of opioids?

Answer 119

• pain
• adjunct to anesthesia (improve sedation; provide pain control)

Question 120

(…) is inactive until it is broken down in the body to (…) which is its prodrug

Answer 120

• codeine
• morphine

Question 121

• Long-term use of opioids can lead to (…)
• Short-acting opioids are more likely to be (…)

Answer 121

• dependence
• addictive

Question 122

As analgesics, opiates can control (…) pain, but (…) doses will be needed over time depending on frequency of dosing. Sharp, intermittent pain may be best controlled with (…), but only treat when treatment is needed

Answer 122

• severe, chronic pain
• increased doses
• short-acting opiates

Question 123

• Fentanyl is a (…) agonist
• Codeine is a (…) agonist
• Buprenorphine is a (…) agonist
• Butorphanol, Nalbuphine, and Pentazocine are (…)
• Which opioids are used as reversal agents or deterrents and are antagonists?

Answer 123

• strong
• moderate/low
• partial
• mixed agonists/antagonists
• Naloxone, Naltrexone

Question 124

What are the different classes of opioids?

Answer 124

• phenanthrenes
• benzomorphans
• phenylpiperidines
• dephenylheptanes
• phenylpropylamines

Question 125

What drugs are phenanthrenes?

Answer 125

• morphine
• codeine
• oxycodone
• oxymorphone
• hydromorphone
• hydrocodone
• levorphanol
• buprenorphine
• nalbuphine
• butorphanol
• naloxone
• naltrexone

Question 126

What drugs are benzomorphans?

Answer 126

pentazocine

Question 127

What drugs are phenylpiperidines?

Answer 127

• fentanyl
• alfentanil
• remifentanil
• sufentanil
• meperidine

Question 128

What drugs are diphenylheptanes?

Answer 128

methadone

Question 129

What drugs are phenylpropylamines?

Answer 129

• tramadol
• tapentadol

Question 130

• Transmission of pain occurs via the (…) pathway
• Once the pain message is received by the brain, the (…) pathway releases (…) to modulate pain

Answer 130

• ascending pathway
• descending pathway
• endorphins

Question 131

• Ascending pain transmission pathway: (…) painful stimuli
• Descending pain transmission pathway: (…) pain

Answer 131

• transmits painful stimuli
• modulates pain

Question 132

• What is the MOA in pain control?
• In the spinal cord, pain information is (…) to the brain
• In the brain, the (…) is activated (as if painful stimuli were received); inhibitory neurons are (…) and (…) are released

Answer 132

• bind opioid receptors promoting K+ conductance and inhibiting Ca+2 conductance
• not transmitted to the brain
• descending pathway
• inhibited
• endorphins

Question 133

• What do opioid agonists do?

Answer 133

• stimulate the receptor (block pain receptors and release endorphins)

Question 134

What has high affinity but low efficacy at the mu receptor?

Answer 134

partial agonists

Question 135

• Partial agonists may act as an (…) in the presence of an (…)
• This precipitates withdrawal but to a lesser-extent than (…)

Answer 135

• antagonist
• agonist
• agonist/antagonist

Question 136

• Partial agonists have (…) bioavailability due to (…); formulations avoid the (…)
• Partial agonists exhibit a (…) effect
• Antagonists can be found at the (…) receptor

Answer 136

• very poor bioavailability
• high first-pass effect
• gut
• ceiling effect
• kappa receptor

Question 137

If someone is overdosing on opioids, what can you give them?

Answer 137

partial agonists - can make some of the drug jump off

Question 138

• Agonists-antagonists have (…) at the mu receptor, so essentially it blocks more (…) from binding, which may cause (…)
• Agonists at (…) receptor; may cause (…) and (…)
• These can exhibit a (…) effect

Answer 138

• poor efficacy
• efficacious opioids
• withdrawal
• kappa receptor
• dysesthesias
• dysphoria
• ceiling effect

Question 139

Describe the ceiling effect

Answer 139

you can only attain a certain amount of pain relief with opioids, so once you give too much, it can lead to toxicity

Question 140

What has high affinity for the mu receptors but no efficacy so it will block anything that binds to the mu receptors?

Answer 140

antagonists

Question 141

• Uptake of opioids is primarily determined by (…) and (…)
• Most opioids are well absorbed via the (…)
• What are exceptions to this?
• Distribution of opioids will depend on what?

Answer 141

• efflux transporters (like P-gp)
• solute carrier influx transporters (SLCs)
• GI tract
• fentanyl (and its cousins), buprenorphine
• will depend on whether the drug is a substrate for efflux transporters or SLCs

Question 142

What do SLCs do?

Answer 142

help bring drugs into the nervous system

Question 143

What do efflux transporters do?

Answer 143

• spit drug out from where it is supposed to go
• harder to cross a barrier and get into the nervous system
• may only work peripherally, not centrally

Question 144

• Phenylpiperidines are metabolized via (…)
• Phenanthrenes are metabolized primarily via (…) as well as others
• Those with free hydroxyl groups undergo (…)
• Active and toxic metabolites are possible with some opioids in the (…) class

Answer 144

• CYP3A4
• CYP2D6
• glucuronidation
• phenanthrenes

Question 145

• Ultimately, it is possible that not all opioids will (…) or be (…) for all patients
• Because of extensive (…) metabolism, IV doses of opioids are often (…) than oral doses
• How are opioids excreted?

Answer 145

• relieve pain or be safe
• hepatic
• smaller
• mostly renally

Question 146

What is an active metabolite?

Answer 146

metabolizes into another form that does the same thing

Question 147

Describe tolerance of opioids?

Answer 147

• decrease in apparent effectiveness of a drug with repeated exposure
• patient is given opioid, says pain is back, have to increase dose to get same effect

Question 148

Is tolerance reversible?

Answer 148

yes, it is reversible and surmountable

Question 149

Describe dependence of opioids?

Answer 149

• neuronal adaptation to repeated exposure resulting in withdrawal syndrome upon cessation
• body starts to depend on drug to do its function of daily life

Question 150

What is inevitable with continuous and extended use of opioids?

Answer 150

dependence

Question 151

What are effects of opioids that we have high tolerance to and can adjust to?

Answer 151

• analgesia
• euphoria/dysphoria
• mental clouding
• sedation
• respiratory depression
• antidiuresis
• nausea/vomiting
• cough suppression

Question 152

What are effects of opioids that we have moderate tolerance to and can adjust to?

Answer 152

• bradycardia

Question 153

What are effects of opioids that we have minimal or no tolerance to and can never adjust to?

Answer 153

• miosis
• constipation
• convulsions

Question 154

What is a behavioral pattern characterized by compulsive use of a drug and overwhelming involvement with its procurement and use?

Answer 154

addiction

Question 155

• Addiction effects the (…) in the brain
• It can be caused by (…) or (…) of withdrawal

Answer 155

• reward center in the brain
• avoidance or alleviation

Question 156

• What is not an end result for all patients on opioids?
• What should you not mistake this for?
• Substances with (…) lives have greatest risk for this due to frequent ups and downs

Answer 156

• addiction
• dependence
• short half-lives

Question 157

What are the effects of opioids?

Answer 157

• analgesics
• nausea/vomiting
• euphoria/dysphoria
• sedation w/o amnesia; disrupted sleep architecture
• respiratory depression
• constipation d/t decreased GI motility
• hyperalgesia
• miosis
• cough suppression
• urinary retention
• truncal rigidity
• minor bradycardia

Question 158

The more opioids you give a person (specifically a naive opioid user), the more likely it is they will have (…)

Answer 158

respiratory depression

Question 159

• Why do opioids cause respiratory depression?
• What is this dependent on?
• How do you overcome this?

Answer 159

• inhibit respiratory drive in the brainstem
• dose-dependent
• can be overcome by external stimuli

Question 160

• Miosis caused by opioids is (…) dependent
• No (…) develops
• Miosis is useful in identifying (…)

Answer 160

• dose dependent
• tolerance
• OD

Question 161

• Truncal rigidity is seen with (…) doses of drugs like (…)
• How is this prevented?

Answer 161

• high doses
• fentanyl
• administering a neuromuscular blocker

Question 162

What should you give to patients who have constipation due to opioids?

Answer 162

a stimulant, not a stool softener

Question 163

What is the drug that is the exception of the opioid bradycardia effect in that it may cause tachycardia due to antimuscarinic effects?

Answer 163

meperidine

Question 164

Why should you not use opioids in patients who have COPD or cystic fibrosis?

Answer 164

• allows cough suppression but does not allow mucus excretion

Question 165

In what patients should you use opioids cautiously?

Answer 165

• pts w/ history of drug/alcohol abuse
• pts w/ depression or other psychiatric illnesses (d/t dysphoria)
• pts using other narcotics or CNS depressants (increased risk of respiratory depression)
• pts with respiratory disease
• pts with gallbladder disease
• pts with epilepsy
• pregnant pts

Question 166

In patients with gallbladder disease, opioids may cause (…) or (…)

Answer 166

• biliary stasis
• constriction of sphincter of oddi

Question 167

Why should you use caution giving opioids to pts with seizures?

Answer 167

opioids may lower seizure threshold in some pts

Question 168

Why should you use caution giving opioids to pregnant patients?

Answer 168

• birth defects
• restricted intrauterine growth
• preterm birth
• still birth
• neonatal abstinence syndrome

Question 169

• Since 1999, (…) people have died as a result of OD
• When opioids bind to (…) receptors, it can cause OD pieces, especially respiratory distress
• Not all synthetic opioids will cause (…)

Answer 169

• 165,000
• mu receptors
• miosis

Question 170

How many MME should you avoid using?

Answer 170

> 50 MME

Question 171

When a pt is at an increased risk of opioid related harm, what should you consider offering?

Answer 171

naloxone

Question 172

What are the numbers associated with these:
- 50-99 MME/day: (…) increased risk of OD
- > 100 MME/day: (…) increased risk of OD

Answer 172

• 3.7
• 8.9

Question 173

What is the MOA of naloxone?

Answer 173

• high affinity for mu receptor (higher than opioids)
• displaces opioids to reverse respiratory depression; opioids still circulate body
• no dependence/tolerance (can use again)
• no clinical effects in absence of opioids (very safe)

Question 174

How can naloxone be given?
- What are the associated time to onset and half-lives?

Answer 174

• IM: 2-3 mins; 30-90 mins
• intranasal: 2-3 mins; 120 mins

Question 175

• Naloxone is poorly absorbed via the (…) route
• Why is the half-life of naloxone important to note?

Answer 175

• oral route
• shorter half-life than opioids so when they jump off mu receptors, opioids can hop back on and cause respiratory depression

Question 176

What are symptoms of opioid acute wthrawal?

Answer 176

• HA
• watery eyes
• runny nose
• sweating
• craving opioids
• MSK pain
• abdominal pain
• N/V/D
• tremors
• restlessness/irritability

Question 177

What are product specific reactions to naloxone?

Answer 177

• nasal dryness
• IM site discomfort

Question 178

You will only use naloxone when?

Answer 178

when patient is not breathing

Question 179

• Naloxone can cross (…) in pregnancy and precipitate (…) withdrawal
• Naloxone can cause (…) in neonates
• During lactation, it is (…) if naloxone gets into lactate to be transported to the baby
• What can naloxone cause in geriatrics and why?

Answer 179

• placenta; fetal withdrawal
• seizures
• unclear
• increased systemic exposure due to hepatic/renal/and cardiac function