Anti-Inflammatory Agents PDF

Summary

This document provides an overview of anti-inflammatory agents. It notably discusses the roles of COX enzymes and prostaglandins in inflammatory responses. Further, it profiles different types of anti-inflammatory agents and their respective mechanisms of action.

Full Transcript

Inflammation: a complex protective response to injury caused by damaging agents
It is aimed at the inactivation or removal of these agents and promoting healing

COX-1: exists in the tissue as a constitutive isoform

COX-2: produced by cytokines stimulation as part of an inflammatory response

PGE2 (pro-inflammatory): vasodilation, bronchodilation, inhibition of gastric acid secretion,
stimulation of gastric mucus secretion, sensitization of pain receptors to chemical and
mechanical stimuli, promotion of anterior pituitary hormones release

PGF2α: uterus contraction, bronchoconstriction, decrease in intraocular tension

TXA2(thromboxane): produced by platelets induction of platelet aggregation, vasoconstriction

PGI2: inhibition of platelet aggregation, potent vasodilation
Balancing act of thromboxane

Prostaglandins: Are not initiators for pain, they are mediators for pain; not in the pathway of
pain they just sensitize the nociceptors that DO cause the pain sensation
Naciceptors convey the pain signal to brain
When you reduce the sensitization = no signal for pain

MOA of NSAIDS:
Act by inhibiting Cyclooxygenases (COX) => decreased PG production
COX-1: Constitutively expressed => “house-keeping” function
COX-2: Induced by pro-inflammatory factors (TNHα, IL-1)
PGs do not cause pain, but sensitize nociceptors to stimulation (e.g. by 5-HT,
bradykinin, capsaicin, …)
NSAIDs have antipyretic effects (reduce fever)
 ○ IL1 is released by macrophages; IL1 is expressed from macrophages which are
apart of innate immune system and defends our body from bacteria, foreign
material
IL-1 release from activated macrophages (bacteria, etc.) induces COX-2 in the brain =>
PG E produced => affects thermoregulation => fever

Aspirin (ASA):
Therapeutic use:
○ Antipyretic, analgesic, anti-inflammatory activity at high doses (325 mg)
○ Cardiovascular threshold dose 81 mg (inhibits platelet aggregation), but maybe
dose dependant
○ Low doses (81 mg/ day) diminish risk of recurrence of MI, of stroke and of colon
cancer
Platelet effect
○ Physiologically TXA2 enhances platelet adhesion while PGI2 depress it
○ At low doses (81 mg/day) aspirin irreversibly inhibits TXA2
○ Lack of TXA2 persists for the entire lifetime of the platelet (3-7 days)
○ As a result thrombus formation decreases (anticoagulant effect)
Kidney effects
○ Prevents synthesis of PGE 2 and PGI 2 responsible for maintaining renal blood
flow
The net effect is vasoconstriction of these two
Pressure goes up and kills our kidneys so patients with longterm kidney
disease are highly contraindicated
If a patient has a glomerular filtration rate < 30, give tylenol instead
○ May cause Na+ retention, edema, and hyperkalemia
○ Doesn’t cause interstitial nephritis as the rest of the NSAIDs
Adverse effects
○ GI: epigastric distress (the lining of stomach that is always on by COX-1 and
because COX-1 is inhibited in ASA, will experience gastric distress), nausea,
vomits, and microscopic bleeding (inhibition of TXA2)
○ Hematologic: prolongs bleeding time and as anticoagulant doses must be
adjusted
○ Due to prolonged effect should be discontinued 1 week prior to surgery
○ Respiratory: toxic doses of respiratory depression combination of respiratory and
metabolic acidosis
Hypersensitivity
○ 15% of patients will have any kind of reaction but anaphylactic shock is
uncommon
Reye Syndrome
○ Fatal fulminating hepatitis with cerebral edema and liver dysfunction; specially
encountered in children
○ CI after viral infection
Toxicity
 ○ Mild (salicylism): nausea, vomits, hyperventilation, headache, dizziness, and
tinnitus
○ Severe (salicylate intoxication): vasomotor collapse, combined respiratory and
metabolic acidosis, and coma

Propionic acid derivatives
Anti-inflammatory, analgesic and antipyretic action
○ Ibuprofen (Motrin ®)- has more effect on kidney
The same mechanism & pharmacological actions of aspirin except that it
is reversible inhibitor for COX enzymes
More potent as anti-inflammatory than aspirin!!!
Rapidly absorbed after oral ingestion
Half-life 1-2 hours
Highly bound to plasma proteins
Protein binding = no effect; need to give 400 mg Ibuprofen for an
effect
Excreted through the kidney as metabolites
CI in kidney dysfunctions
Clinical uses:
Analgesic
Antipyretic
Anti-inflammatory
Acute gouty arthritis
Patent ductus arteriosus
Formulations:
Oral preparations
Topical cream for osteoarthritis
A liquid gel for rapid relief of postsurgical dental pain
Intravenous route for patent ductus arteriosus
Adverse effects
Gastric upset (less frequent than aspirin)
Fluid retention
Hypersensetivity reactions
Ocular disturbances
Rare hematologic effects (agranulocytosis & aplastic anemia)
Contraindications
Peptic ulcer
Allergic patients to aspirin
Kidney impairment
Liver diseases
Pregnancy
Hemophilic patients
The concomitant administration of ibuprofen antagonizes the irrevesible
platelet inhibition of ASPIRIN (limit cardioprotective effect of aspirin)
 ○ Naproxen (Naprosyn ® )
○ Fenporofen (Nalton ® )
○ Ketoprofen (Ketoprofen®)
○ Flurbiprofen (Ansaid®)
○ Oxaprozin (Daypro®) (strongest derivative used once a day)
○ Widely used agents for rheumatoid arthritis and ankylosing spondylitis because
GI effects are less toxic than aspirin
All are reversible inhibitors of cyclooxygenase
Most common SE include dyspepsia due to gastric bleeding, headache, tinnitus, and
dizziness

Heteroaryl Acetic Acids: Diclofenac
More potent than Indomethacin and Naproxen
More potent as an anti-inflammatory than analgesics and antipyretics
Clinical applications
○ 1. Any inflammatory conditions
○ 2. Musculoskeletal pain
○ 3. Dysmenorrhea
○ 4. Acute gouty arthritis
○ 5. Fever
○ 6. Ophthalmic to prevent or treat ophthalmic inflammation (Acular)
Diclofenac is supplied as either the sodium or potassium salt, most often supplied as the
sodium salt
Diclofenac sodium has a tendency to retain salt & water in the body, predisposing to
cardiovascular events
○ Less likely to use in patients w/ HBP, cardiovascular disease
○ Water will follow sodium and more blood volume = higher pressures
Diclofenac potassium is preferred in patients with cardiovascular diseases
Topical gel (OTC) and ophthalmic formulation available
Combo Preparations
○ Diclofenac with Misoprostol (PGE1) decreases upper gastrointestinal ulceration,
but results in diarrhea
○ Diclofenac with Omeprazole to prevent recurrent bleeding
Side Effects
○ Gastric upset
○ Renal impairment
○ Elevation of serum aminotransferase (hepatic enzymes- liver)
○ Salt & water retention which can lead to elevated BP

Heteroaryl Acetic Acids: Ketorolac (Toradol/Acular)
Antipyretic, analgesic, and anti-inflammatory properties
Indicated for short-term management of acute pain that requires the caliber of pain
management offered by opioids
 May be used to initiate tx of post-operative pain, spinal and soft tissue pain, rheumatoid
arthritis, osteoarthritis, ankylosing spondylitis, menstrual disorders, and headaches
Better analgesic than anti-inflammatory
Oral and ophthalmic formulations available (used post-op cataract surgery)
Should use the lowest possible dose, and avoid using ketorolac for an extended period
of time (ideally < 5 days)
Common SE
○ Headache
○ Upset stomach
○ Nausea
○ Vomiting
○ Diarrhea
○ Stomach pain
○ Bloating

Acetic acid derivatives
Indometacin
○ An indole-acetic acid derivative
○ Used for symptomatic management of chronic musculoskeletal pain conditions
and to induce closure of a hemodynamically significant patent ductus arteriosus
in premature infants
○ More potent than aspirin as anti-inflammatory agent but as toxic dose
○ Effective as analgesic for uveitis and post-operative ophthalmic procedures
○ Antipyretic for Hodgkin’s lymphoma
○ Abortive treatment gout
High levels of uric acid in the system
○ Treatment of scleritis
○ Delay labor by suppressing uterine contractions
○ Absorbed PO and largely bound to plasma proteins
Sulindac (Clinoril): indene acetic acid class of NSAIDs (oral NSAIDs can be used for
uveitis) and is chemically related to indomethacin
○ Not DJ’s choice; derivative of indomethacin which is better but he did not talk
about it due to MOA being confusing
○ Used to treat osteoarthritis, rheumatoid arthritis, ankylosing spondylitis, acute
subacromial bursitis or supraspinatus tendinitis, and acute gouty arthritis
○ A prodrug, derived from sulfinyl indene, that is converted to an active sulfide
compound by liver enzymes
○ May be associated with fewer gastrointestinal side effects than other NSAIDs,
except for the COX-2 inhibitor drug class
○ The sulfide metabolite undergoes enterohepatic circulation thus maintaining
constant blood levels of the compound without inducing gastrointestinal effects,
where the drug is excreted in the bile and then reabsorbed from the intestines
 ○ The full mechanism of action is not fully understood, sulindac is thought to
primarily mediate its action by inhibiting prostaglandin synthesis by inhibiting
COX-1 and COX-2

COX-2 Selective NSAID: Celecoxib (Celebrex)
Selective irreversible COX-2 inhibitor at therapeutic doses; it is approved for
osteoarthritis and not as an analgesic agent
It does not interfere with platelet function
Well absorbed orally and metabolized in liver in CYP450 and excreted in feces and urine
Characteristics
○ Highly selective inhibitors to COX-2 enzyme
○ Potent anti-inflammatory
○ Have analgesic & antipyretic properties
○ Highly bound to plasma proteins
○ Lower incidence of gastric upset
○ No effect on platelet aggregation (COX1)
○ Renal toxicities (not recommended for patients w/ severe renal insufficiency)
○ High incidence of cardiovascular thrombotic events with some of them as
ROFECOXIB
Side effects
○ GI disturbances Duodenal ulcer
○ Displaces other drugs metabolized by CYTP450
○ *Contraindicated in patients allergic to sulfonamides

○

SAIDs- Steroidal Anti-Inflammatory Drugs
Short-acting glucocorticoids (natural)
○ Hydrocortisone
○ Cortisone
Intermediate-acting glucocorticoids
○ Prednisone
 ○ Prednisolone
○ Methylprednisolone
○ Triamcinolone
Long-acting
○ Betamethasone
○ Dexamethasone
○ Paramethasone
Topically acting glucocorticoids
○ Beclomethasone dipropionate
○ Budesonide flucinolone
○ Acetonide flucortolone

Clinical uses
○ Adrenal insufficiency
○ Arthritis
○ Collagen disease (systemic lupus erythematosus, scleroderma)
○ Bronchial asthma
○ Severe allergic reactions
○ Autoimmune diseases
○ Skin diseases
Main SE of SAIDs
○ Susceptibility to infections wounds
○ Delayed healing of wounds
○ Osteoporosis
○ Growth retardation in children
○ Muscular weakness
○ Hyperglycemia
○ Cushing habitus
○ Peptic ulceration

Autacoids-Histamine/Anti-histamines 1 & 2
Autacoids Overview
 ○ Histamine, serotonin, prostaglandins, & some vasoactive peptides belong to a
group of compounds called autacoids
○ They all have the common feature of being formed by the tissues on which they
act; thus, they function as local hormones
○ The autacoids also differ from circulating hormones in that they are produced by
many tissues rather than in specific endocrine glands
Histamines
○ 1st autacoid to be discovered
○ Is a chemical messenger that mediates a wide range of cellular responses,
including:
Allergic and inflammatory reactions
Gastric acid secretion
Neurotransmission in parts of the brain
○ Involved in inflammatory and anaphylactic reactions
○ Histamine storage
In mast cells, histamine (+ charged) is held by acidic proteins and heparin
(- charged) within intracellular granules
When the granules are extruded by exocytosis, Na+ ions in e.c.f.
exchange with histamine to release it free
○ Histamine conditions causing release
Tissue injury
Any physical (mechanical) or chemical agent that injuries tissue,
skin or mucosa will cause the immediate release of histamine from
mast cells
Chemical and mechanical mast cell injury causes degranulation
and histamine release
Allergic reactions
Exposure of an antigen to a previously sensitized (exposed)
subject can immediately trigger allergic reactions
Sensitized by IgE, antibodies attached to their surface
membranes, causing mast cell degranulation and release of
histamine, and other mast cell component
○ Histamine receptor and their function(s)
H1
Modulate circadian cycle
Itching
Systemic vasodilation
Bronchoconstriction
Ileum contraction
H2
Speed up sinus rhythm
Stimulation of gastric secretion
Smooth muscle relaxation
Inhibit antibody synthesis, T-cell proliferation & cytokine production
 H3
Decrease acetylcholine, serotonin and norepinephrine
neurotransmitter release in the CNS
Presynaptic autoreceptors
H4
Mediate mast cell chemotaxis
○ Histamine antagonists- Epinephrine
The effects of histamine released in the body can reduced in several
ways
Physiologically, endogenous epinephrine (adrenaline) have
smooth muscle actions opposite to those of histamine, by acting at
different receptors
Clinically, by injection of exogenous injection of epinephrine,
agonist activity causes smooth muscle relaxation, like observed in
the treatment for bronchoconstriction that occurs in systemic
anaphylaxis and other conditions in which massive release of
histamine
Use of epinephrine in anaphylaxis
Adrenoreceptor agonists (sympathomimetic)
○ Epinephrine is the DOC for the immediate treatment of
anaphylactic shock
○ It is an effective physiologic antagonist of many of the
mediators of anaphylaxis
○ Sometimes supplemented with antihistamines and
corticosteroids, but these agents are neither as efficacious
as epinephrine nor as rapid-acting
○ Histamine antagonists- mast cell stabilizers (release inhibitors)
Reduce the degranulation of mast cells that results from immunologic
triggering by antigen
IgE interaction
Cromolyn and Nedocromil have this effect and have been used in the
treatment of asthma, although the molecular mechanism underlying their
action is not fully understood
Therapeutic uses:
Mild to moderate bronchial asthma
○ To prevent acute attacks
○ Effective in children
○ Reduces need of steroids or bronchodilators
○ Ineffective for an acute attack
○ Becomes effective overtime (e.g., 2-3 weeks)
Allergic rhinitis
Atopic diseases of the eye
Giant papillary conjunctivitis
○ Histamine receptor blockers
 These compounds do not influence the formation or release of histamine;
rather, they block the receptor-mediated response of a target tissue
H1 blockers:
First generation (diphenhydramine)
○ Still widely used because they are effective and
inexpensive
○ They block H1 receptors and muscarinic receptors
○ Most penetrate the CNS, some used off-label for sedation,
dizziness, vertigo, motion sickness

○
○ Other effects
Sedation
A common effect, effect varies among
chemical subgroups
Second generation have little or no sedative
or stimulant actions; also have far fewer
autonomic effects than the first-generation
antihistamines
Antinausea and antiemetic actions
Several first-gen H1 antagonists have
significant activity in preventing motion
sickness
They are less effective against an episode
of motion sickness already present
Anticholinoceptor actions
First generation like ethanolamine
subgroup, have significant atropin-like
effects on peripheral muscarinic receptors
Benefits reported for nonallergic rhinorrhea
May also cause urinary retention and
blurred vision
Second generation (Cetirizine)
○ Are specific for H1 receptors because do not cross BBB;
they show less CNS side effects
 ○ Among these agents,
Ioratadine/desloratadine/fexofenadine produce the least
sedation

○
H2 blockers (Cimetidine)
○ H1 Antihistamines MOA:
Action of all the H1-receptor blockers is qualitatively similar (block H1
receptors)
But most of these blockers have additional other related blocking receptor
activity
Antagonists to cholinergic, adrenergic, or serotonin receptors
○ Antihistamines- PK
Absorption
These agents are rapidly absorbed after oral administration
Peak blood concentrations occur in 1-2 hours
Distribution
Widely distributed throughout the body
First-generation drugs enter CNS readily
Metabolism
Some of them are extensively metabolized, primarily by
microsomal systems in the liver
Several of the second-generation agents are metabolized by the
CYP3A4
○ Antihistamines Therapeutic uses
Allergic and inflammatory conditions
Useful in treating allergies caused by antigens acting on
immunoglobulin E antibody–sensitized mast cells
DOC for controlling the symptoms of allergic rhinitis and urticaria,
because histamine is the principal mediator
Are ineffective in treating bronchial asthma, because histamine is
only one of several mediators of that condition (LTs are the main
mediators)
Motion sickness/nausea
Along with the antimuscarinic agent scopolamine, certain
H1-receptor blockers, such as diphenhydramine, dimenhydrinate,
cyclizine, meclizine, and hydroxyzine, are the most effective
agents for the prevention of the symptoms of motion sickness
 Prevent or diminish vomiting and nausea mediated by both the
chemoreceptor and vestibular pathways
The antiemetic action of these medications seems to be due to
their blockade of central muscarinic receptors
Somnifacients
Although not the DOC, many first-generation antihistamines, such
as diphenhydramine hydroxyzine, have strong sedative properties
and are used in the treatment of insomnia
Contraindicated in the treatment of individuals working in jobs
where wakefulness is critical
Nausea and vomiting during pregnancy
Several agents have been studied for possible use in treating
"morning sickness"
The piperazine derivatives were withdrawn from such use when it
was demonstrated that they have teratogenic effects in rodents
○ Antihistamines- adverse effects/toxicity
Sedation
First-generation H1 antihistamines, such as chlorpheniramine,
diphenhydramine, hydroxyzine, and promethazine, bind to H1
receptors and block the neurotransmitter effect of histamine in the
CNS
The most frequently observed adverse reaction is sedation
Dry nose/eyes/mouth
Oral antihistamines also exert weak anticholinergic effects, leading
not only to a drying of the nasal passage but also to a tendency to
dry eye and dry mouth
Other CNS actions
Other central actions include tinnitus, fatigue, dizziness, lassitude
(a sense of weariness), incoordination, blurred vision, and tremors
○ H2 Antihistamines
Physiology of acid secretion
Parietal cells are located in the body of the stomach and secrete
hydrochloric acid(HCl) into the lumen
Water and CO₂ are combined to produce hydrogen (H+) ions and
HCO₃ ions by the action of the carbonic anhydrase enzyme
H+is transported to the lumen of the stomach via the
H+/K+ATPasepump
HCO₃ is exchanged for chloride(Cl−) ion
H+and Cl−combine to form the final product: HCl
Types of H2 blockers
There are different names and brands of H2 blockers
All are available over the counter without a prescription
Most work equally as well
Side effects may vary from drug to drug
 Famotidine (Pepcid AC, Pepcid Oral, Zantac 360)
Cimetidine (Tagamet, Tagamet HB)
Nizatidine Capsules (Axid AR, Axid Capsules, Nizatidine
Capsules)
Ranitidine (Zantac) has been removed from the US market due to
concerns about safety
Competitive H2 receptor antagonists
Markedly inhibits basal acid secretion including nocturnal
secretion
MOA
H2RAs decrease gastric acid secretion by reversibly binding to
histamine H2 receptors located on gastric parietal cells, thereby
inhibiting the binding and activity of the endogenous ligand
histamine, H2 blockers thus function as competitive antagonists
Clinical indications
Gastritis
GERD
Gastric and duodenal ulcer and esophageal reflux disease
Stress ulcers prevention
Metabolism
Metabolized in the liver by the cytochrome P450 system
Among the agents, cimetidine is distinctive in its potent inhibition
of the P450 system (CYP 1A2, 2C9, and 2D6), which can result in
significant drug interactions
Side effects
SE from H2 blockers is rare
Famotidine: the most common side effect is headache
Cimetidine: rare but diarrhea, dizziness, rashes, headaches, and
gynecomastia may occur; CYP450 inhibitor
Nizatidine: rare