Anti-Inflammatory, Antipyretic & Analgesic Pharmacology PDF

Summary

This document provides an overview of anti-inflammatory, antipyretic, and analgesic pharmacology. It covers topics such as inflammation, its signs, and different phases. The document also explains various molecular mediators of inflammation and related pathways. Finally, it discusses different types of anti-inflammatory agents and their effects.

Full Transcript

Anti-Inflammatory,
Antipyretic &
Analgesic
Pharmacology
DONE BY: MOHAMMAD ALLAHIB
Inflammation

 Inflammation is the body's protective response to injury, infection, or harmful stimuli
 It involves immune cells, blood vessels, and molecular mediators
 Signs of Inflammation:
 Redness (Rubor): Due to increased blood flow
 Heat (Calor): From increased blood flow and metabolic activity
 Swelling (Tumor): Due to fluid accumulation
 Pain (Dolor): From pressure on nerves and release of inflammatory mediators
 Loss of Function (Functio Laesa): Result of pain and swelling
Phases of Inflammation

Acute Inflammation Chronic Inflammation
 Rapid onset, short duration  Characteristics: Prolonged duration,
ongoing tissue destruction and repair
 Eliminate the initial cause of cell injury,
remove dead cells, and initiate tissue  Purpose: Persistent inflammation due to
repair an ongoing stimulus or unresolved acute
inflammation
 Vascular Changes: Increased blood
flow (vasodilation) and increased  Cellular Infiltration: Predominantly
vascular permeability macrophages, lymphocytes, and plasma
cells
 Cellular Events: Migration of
leukocytes, primarily neutrophils, to the  Tissue Destruction: By inflammatory cells
site of injury
 Repair: Attempted by connective tissue
replacement and angiogenesis
Molecular Mediators of
Inflammation
Histamine Cytokines
► Source:  Examples:
► Mast cells  IL-1
► Basophils  TNF-α
► Platelets  Effect:

► Effect:  Modulate immune response

► Vasodilation  Promote leukocyte recruitment

► Increased vascular
permeability
Molecular Mediators of
Inflammation
Prostaglandins
 Source: Arachidonic acid metabolism
 Effect:
 Vasodilation
 Fever
 Pain
Molecular Mediators of
Inflammation
Chemokines Complement System
 Effect: Attract leukocytes to the  Effect:
site of inflammation
 Enhances phagocytosis
 Recruits immune cells
 Directly lyses pathogens
Pathways of Inflammation

1. Vascular Response:
 Vasodilation: Increases blood flow
to the area
 Increased Permeability: Allows
plasma proteins and leukocytes to
enter the tissue
2. Cellular Response:
 Leukocyte Recruitment: Neutrophils
and later macrophages migrate to
the site of injury
 Phagocytosis: Engulfment and
destruction of pathogens and
debris by leukocytes
Outcomes of Inflammation

 Resolution: Clearance of the injurious
stimuli, removal of inflammatory cells,
and repair of tissue
 Chronic Inflammation: If the injurious
stimulus persists, leading to ongoing
tissue damage and repair
 Fibrosis: Excessive connective tissue
deposition leading to scar formation
 Abscess Formation: Localized
collection of pus due to infection
Introduction

 Anti-Inflammatory Agents: Drugs that reduce inflammation
 Types of Anti-Inflammatory Agents:
 Non-Steroidal Anti-Inflammatory Drugs (NSAIDs)
 Corticosteroids
 Disease-Modifying Anti-Rheumatic Drugs (DMARDs)
 Analgesic Agents: Drugs that relieve pain
Non-Steroidal Anti-Inflammatory
Drugs (NSAIDs)
 Mechanism of Action:
 Inhibition of Cyclooxygenase (COX)
Enzymes:
 COX-1: Found in most tissues; involved in
maintaining gastric mucosa, renal blood
flow, and platelet aggregation
 COX-2: Induced during inflammation;
responsible for the synthesis of
inflammatory prostaglandins
 Effect: Reduces the synthesis of prostaglandins
and thromboxanes, leading to decreased
inflammation, pain, and fever
Non-Steroidal Anti-Inflammatory
Drugs (NSAIDs)
Ibuprofen
 Brand Names: Advil, Profinal, Captain,
Brufen
 Uses: Pain relief for mild to moderate
pain, inflammation, fever
 Dosage: Typically 200-800 mg every 6-8
hours
 Side Effects: GI irritation, nausea,
dizziness, renal impairment
Non-Steroidal Anti-Inflammatory
Drugs (NSAIDs)
Naproxen
 Brand Names: Napreben, Nopain DS &
Proxen
 Uses: Longer-lasting relief for arthritis,
gout, menstrual pain
 Dosage: 250-500 mg every 8-12 hours
 Side Effects: Similar to ibuprofen;
increased cardiovascular risk with
long-term use
Non-Steroidal Anti-Inflammatory
Drugs (NSAIDs)
Aspirin
 Brand Names: Aspicor, Aspicot
 Uses: Pain relief, anti-inflammatory,
antipyretic, anti-platelet for
cardiovascular protection
 Dosage: 325-650 mg every 4-6 hours for
pain; low dose (81-325 mg) daily for
heart protection
 Side Effects: GI bleeding, Reye's
syndrome in children, tinnitus at high
doses
Non-Steroidal Anti-Inflammatory
Drugs (NSAIDs)
Diclofenac
 Brand Names: Voltaren, Cataflam, Voltfast, Dicloftil,
Diclogesic, Voldic-K
 Uses: Pain relief, anti-inflammatory, osteoarthritis,
rheumatoid arthritis, dysmenorrhea & acute migraine
 Dosage:
 Pain/Arthritis: 50 mg 2-3 times daily or 75 mg twice
daily
 Menstrual Pain: 50 mg 3 times daily
 Migraine: 50 mg at onset
 Side Effects:
 Common: Stomach pain, nausea, indigestion
 Serious: GI bleeding, heart risks, liver damage,
kidney issues
Non-Steroidal Anti-Inflammatory
Drugs (NSAIDs)
Celecoxib
 Brand Names: Celebrex
 Uses: Selective COX-2 inhibitor; used
for osteoarthritis, rheumatoid arthritis,
acute pain
 Dosage: 100-200 mg once or twice
daily
 Side Effects: Lower GI risk but potential
cardiovascular risk; contraindicated in
patients with sulfa allergy
Non-Steroidal Anti-Inflammatory
Drugs (NSAIDs)
Rofecoxib
 Brand Names: Vioxx
 Uses: Selective COX-2 inhibitor; used for osteoarthritis,
rheumatoid arthritis, acute pain, dysmenorrhea
 Dosage:
 Osteoarthritis: 12.5-25 mg once daily
 Rheumatoid Arthritis: 25 mg once daily
 Acute Pain: 50 mg once daily as needed
 Menstrual Pain: 25-50 mg once daily
 Side Effects:
 Common: Stomach pain, nausea, headache
 Serious: Increased risk of heart attack and stroke, GI
bleeding, kidney issues
Corticosteroids

 Mechanism: Mimic cortisol, suppressing inflammation and immune response
 Effects:
 Bind to Glucocorticoid Receptors: Corticosteroids enter cells and bind to glucocorticoid
receptors in the cytoplasm
 Regulate Gene Expression: The corticosteroid-receptor complex moves to the nucleus
and influences the transcription of anti-inflammatory genes and suppression of pro-
inflammatory genes
 Membrane Stabilization: Corticosteroids stabilize lysosomal and cell membranes,
reducing the release of inflammatory mediators.
 Decrease Capillary Permeability: This reduces edema and swelling
 Side Effects: Weight gain, osteoporosis, hypertension, diabetes,
immunosuppression
Corticosteroids

Prednisone Hydrocortisone Dexamethasone
► Commonly used for ► Used for adrenal ► Potent anti-inflammatory effects, used
inflammatory and insufficiency and in severe inflammatory conditions and
autoimmune inflammatory skin as an adjunct in cancer therapy
conditions conditions
Disease-Modifying Anti-Rheumatic
Drugs (DMARDs)
 Mechanism: Modify the underlying disease process, not just symptoms
 Examples: Methotrexate, Sulfasalazine, Hydroxychloroquine, Biologics (e.g.,
Etanercept, Infliximab)
 Uses: Rheumatoid arthritis, other autoimmune diseases
 Side Effects: Immunosuppression, liver toxicity, risk of infections
Traditional DMARDs

Methotrexate
 Examples: Ebetrexat, Methotrexate
Ebewe & Metoject
 Mechanism: Inhibits dihydrofolate
reductase, reducing DNA synthesis
and cell replication
 Uses: First-line treatment for
rheumatoid arthritis (RA).Side Effects:
Liver toxicity, bone marrow
suppression, gastrointestinal upset
 Monitoring: Regular blood tests to
monitor liver function and blood cell
counts
Traditional DMARDs

Sulfasalazine
 Examples: Azulfidine, Azulfidine EN-
Tabs
 Mechanism: Suppresses inflammatory
responses by inhibiting prostaglandin
and leukotriene synthesis
 Uses: RA and inflammatory bowel
disease (IBD).Side Effects: Rash,
gastrointestinal issues, liver toxicity
 Monitoring: Regular blood tests for liver
and kidney function
Traditional DMARDs

Hydroxychloroquine
 Examples: Corvaquine & Dolquine
 Mechanism: Modulates immune
system activity and has anti-
inflammatory properties
 Uses: Mild RA, lupus
 Side Effects: Retinal toxicity,
gastrointestinal upset
 Monitoring: Regular eye exams to
monitor for retinal damage
Biologic DMARDs

Tumor Necrosis Factor (TNF) Inhibitors
 Examples: Etanercept, Infliximab, Adalimumab
 Mechanism: Bind to and neutralize TNF-alpha, a pro-inflammatory cytokine
 Uses: Moderate to severe RA, psoriasis, ankylosing spondylitis
 Side Effects: Increased risk of infections, injection site reactions
 Monitoring: Regular screening for infections, including tuberculosis
Tumor Necrosis Factor (TNF)
Inhibitors
Etanercept Infliximab Adalimumab
Biologic DMARDs

Interleukin Inhibitors
 Examples: Tocilizumab (IL-6 inhibitor),
Anakinra (IL-1 receptor antagonist)
 Mechanism: Block specific interleukins
involved in the inflammatory process
 Uses: RA, juvenile idiopathic arthritis
 Side Effects: Increased risk of infections,
elevated liver enzymes
 Monitoring: Regular blood tests for liver
function and signs of infection.
Biologic DMARDs

B-Cell and T-Cell Targeting Agents
 Examples: Rituximab (targets B-cells),
Abatacept (modulates T-cell activity)
 Mechanism: Rituximab depletes B-
cells; Abatacept inhibits T-cell
activation
 Uses: RA, particularly in patients
unresponsive to TNF inhibitors
 Side Effects: Infusion reactions,
increased risk of infections
 Monitoring: Screening for infections,
regular monitoring during infusion.
Antipyretic Agents
Fever

 Fever is an elevation in body temperature often due to infection,
inflammation, or other medical conditions
 Common Causes:
 Bacterial Infections: Examples include pneumonia, urinary tract infections,
and sepsis
 Viral Infections: Examples include influenza, common cold, COVID-19
 Inflammatory Diseases: Autoimmune diseases such as rheumatoid arthritis,
lupus
 Other Causes: Cancer, heatstroke, certain medications, and immunizations
Antipyretic Agents

 Drugs that reduce fever
 Target hypothalamus, the body’s thermostat
 Mechanism: Reduce the production of prostaglandins in the
hypothalamus, lowering the set point of body temperature
 Main Agents: Acetaminophen (Paracetamol) and Non-Steroidal Anti-
Inflammatory Drugs (NSAIDs)
Antipyretic Agents

1. Acetaminophen (Paracetamol):
 Central Action: Inhibits cyclooxygenase (COX) enzymes in the brain,
particularly COX-3, leading to a decrease in prostaglandin E2 (PGE2)
in the hypothalamus
 Effect: Reduces the hypothalamic set point for temperature control,
leading to heat dissipation (sweating, vasodilation)
2. NSAIDs (e.g., Ibuprofen, Aspirin):
 Peripheral and Central Action: Inhibit COX-1 and COX-2 enzymes,
reducing the synthesis of prostaglandins which are involved in fever
production
 Effect: Decrease the production of pyrogenic cytokines that act on
the hypothalamus, lowering the set point temperature
Acetaminophen (Paracetamol)

 Common Brands: Tylenol, Panadol
 Use: Safe for use in all ages, including
infants, children, and pregnant
women
 Dosage: 500-1000 mg every 4-6 hours
(maximum 4 grams per day for adults)
 Onset of Action: 30-60 minutes
 Duration of Action: 3-4 hours
 Side Effects: Generally well-tolerated;
potential for hepatotoxicity at high
doses or with chronic use
 Special Considerations: Safe in
pregnancy and breastfeeding;
caution in patients with liver disease
Ibuprofen

 Common Brands: Advil, Profinal, Captain, Brufen
 Uses: Effective for reducing fever, especially in
conditions accompanied by inflammation (e.g.,
arthritis)
 Dosage: 200-400 mg every 4-6 hours (maximum
1200 mg per day for over-the-counter use)
 Onset of Action: 30 minutes
 Duration of Action: 4-6 hours
 Side Effects: Gastrointestinal irritation, renal
impairment, increased bleeding tendency
 Special Considerations: Avoid in patients with
peptic ulcer disease, chronic kidney disease, or
aspirin allergy
Aspirin

 Common Brands: Bayer, Aspicot, Aspicor
 Uses: Used less frequently as an antipyretic
due to side effects and risk of Reye's
syndrome in children
 Dosage: 325-650 mg every 4-6 hours
(maximum 4 grams per day)
 Onset of Action: 1-2 hours
 Duration of Action: 4-6 hours
 Side Effects: Gastrointestinal bleeding,
tinnitus, Reye's syndrome in children
 Special Considerations: Not recommended
for children or teenagers with viral
infections; caution in patients with bleeding
disorders or asthma
Antipyretic Agents

Pediatrics Geriatrics Pregnancy
► Preferred Antipyretic: ► Considerations: ► Preferred Antipyretic: Acetaminophen
Acetaminophen and Monitor for renal is considered safe; NSAIDs are
ibuprofen are function and generally avoided in the third trimester
preferred; avoid gastrointestinal due to risk of premature closure of the
aspirin due to risk of tolerance; lower ductus arteriosus
Reye's syndrome doses may be
needed
► Dosage Adjustments:
Dosages must be
adjusted according
to weight and age
Analgesic Agents
Pain

 Pain is an unpleasant sensory and emotional experience associated
with actual or potential tissue damage
 Types of Pain:
 Acute Pain
 Chronic Pain
 Pain Pathways:
 Nociceptive Pain
 Neuropathic Pain
Types of Pain

Acute Pain Chronic Pain
 Short duration  Lasts longer than 3-6 months
 Sudden onset  Persistent or recurrent
 Often linked to a specific injury or  Examples:
illness
 Arthritis
 Examples:
 Back pain
 Post-surgical pain
 Neuropathic pain (e.g.,
 Fractures diabetic neuropathy)
 Burns
Pain Pathways

Nociceptive Pain Neuropathic Pain
 Caused by damage to body tissue  Caused by damage to the
nervous system
 Activation of nociceptors (pain
receptors)  Often described as burning or
shooting pain
 https://www.ypo.education/neuro
logy/neuropathic-pain-
t458/video/
Assessment of Pain

Pain Scales
 Numeric Rating Scale (NRS): 0 (no
pain) to 10 (worst pain)
 Visual Analog Scale (VAS): Line scale
where patients mark their pain level
 Faces Pain Scale: Used for children or
those with communication difficulties
Analgesic Agents

Non-Opoid Paracetamol
Analgesics
Naproxen
NSAIDs Ibuprofen
Aspirin

Morphine
Opoid Analgesics Oxycodone
Fentanyl

Adjuvant Antidepressants

Analgesic Anticonvulsants
Non-Opioid Analgesics (Strongest
to Weakest)
Lower risk of gastrointestinal irritation compared to nonselective NSAIDs
Celecoxib 100-200 mg once or twice daily, Maximum daily dose: 400 mg

Diclofenac
Effective for more severe inflammatory conditions
50-75 mg two to three times daily, Maximum daily dose: 150 mg

Naproxen
Longer duration of action compared to Ibuprofen
250-500 mg every 12 hours, Maximum daily dose: 1000-1250 mg

Ibuprofen
Effective and widely used NSAID
200-400 mg every 4-6 hours, Maximum daily dose 1200-2400 mg

Aspirin
Effective for pain & inflammation, cardiovascular protection at low doses
325-650 mg every 4-6 hours, 81-325 mg daily for antiplatelet effect

Paracetamol
Well-tolerated, minimal gastrointestinal effect
325-1000 mg every 4-6 hours, Maximum daily dose: 1000-4000 mg
Opioid Analgesics

Morphine
 Mechanism: Binds to mu-opioid receptors in
the CNS, altering the perception and
response to pain
 Uses: Moderate to severe pain, particularly
post-operative and cancer pain
 Benefits: Effective for severe pain
 Side Effects: Sedation, constipation,
respiratory depression, risk of dependence
and overdose
 Dosing: Typically 5-30 mg every 4 hours for
immediate release; long-acting
formulations available.
Opioid Analgesics

Oxycodone
 Mechanism: Similar to morphine, binds
to mu-opioid receptors
 Uses: Moderate to severe pain
 Benefits: Available in immediate and
extended-release formulations
 Side Effects: Similar to morphine, with
high potential for abuse
 Dosing: Typically 5-15 mg every 4-6
hours for immediate release;
extended-release formulations dosed
every 12 hours
Opioid Analgesics

Fentanyl
 Mechanism: Binds to mu-opioid receptors;
highly potent
 Uses: Severe pain, often used in chronic
pain management and anesthesia
 Benefits: Rapid onset, available in various
formulations (transdermal patches,
lozenges)
 Side Effects: Similar to other opioids, but
with increased potency and risk of
overdose
 Dosing: Transdermal patches typically
applied every 72 hours.
Adjuvant Analgesics

Antidepressants
 Examples: Amitriptyline (tricyclic antidepressant),
Duloxetine (SNRI)
 Mechanism: Modulate neurotransmitters
(serotonin and norepinephrine) involved in pain
pathways
 Uses: Neuropathic pain, fibromyalgia, chronic
pain conditions
 Benefits: Can improve pain and associated
mood disorders
 Side Effects: Sedation, dry mouth, weight gain
(TCAs); nausea, insomnia (SNRIs).Dosing:
Amitriptyline typically 10-50 mg at bedtime;
Duloxetine 30-60 mg daily.
Adjuvant Analgesics

Anticonvulsants
 Examples: Gabapentin, Pregabalin
 Mechanism: Modulate calcium channels,
reducing neuronal excitability
 Uses: Neuropathic pain, postherpetic neuralgia,
fibromyalgia
 Benefits: Effective for certain types of chronic
pain
 Side Effects: Dizziness, sedation, peripheral
edema
 Dosing: Gabapentin typically 300-600 mg three
times daily; Pregabalin 75-150 mg twice daily
Combining Therapies
Combining Therapies

 Enhanced Efficacy: Combining drugs with different mechanisms can
provide better symptom control
 Reduced Side Effects: Lower doses of each drug can be used,
minimizing the risk of side effects associated with higher doses of a
single drug
 Broader Coverage: Address multiple pathways involved in pain,
inflammation, or fever
Special Considerations in Specific
Populations
Patients with
Elderly Patients Comorbidities Pediatric Patients
► Increased sensitivity ► Consider impact on ► Adjust dosages based
to drug effects and existing conditions on age and weight
higher risk of side (e.g., cardiovascular,
► Consider
effects renal, hepatic)
developmental
► Careful dose ► Comprehensive factors in drug
adjustments and approach to minimize metabolism and
monitoring risks and maximize excretion
benefits
NSAIDs + Acetaminophen

 Mechanism:
 NSAIDs: Inhibit COX enzymes, reducing prostaglandin
synthesis and inflammation
 Acetaminophen: Inhibits central COX enzymes, reducing
pain and fever
 Benefits:
 Synergistic pain relief
 Reduced inflammation with NSAIDs
 Enhanced overall pain management
 Considerations:
 Monitor for gastrointestinal issues from NSAIDs
 Avoid excessive acetaminophen to prevent liver toxicity
 Example: Combining ibuprofen with acetaminophen
for acute pain relief, such as dental pain or
musculoskeletal injuries
Corticosteroids + DMARDs

 Mechanism:
 Corticosteroids: Suppress the immune response and reduce
inflammation
 DMARDs: Slow disease progression by targeting underlying
mechanisms of autoimmune diseases
 Benefits:
 Rapid symptom relief from corticosteroids
 Long-term disease control with DMARDs
 Considerations:
 Corticosteroids for short-term use to avoid severe side effects
 Regular monitoring of blood counts, liver function, and infection signs due to
DMARDs
 Example: Prednisone combined with methotrexate for rheumatoid
arthritis management.
Opioids + Non-Opioids

 Mechanism:
 Opioids: Bind to opioid receptors in the CNS, altering pain perception
 Non-Opioids (NSAIDs/Acetaminophen): Reduce peripheral
inflammation and pain signaling
 Benefits:
 Enhanced pain relief for severe pain
 Lower doses of opioids required, reducing the risk of dependence and
side effects
 Considerations:
 Monitor for sedation, respiratory depression, and constipation from
opioids
 Use multimodal analgesia to minimize opioid dosage
 Example: Combining oxycodone with acetaminophen (Percocet)
for postoperative pain management
Clinical Applications: Inflammatory
Conditions
Arthritis
Osteoarthritis
1. Symptoms: Joint pain, stiffness, reduced mobility.
2. Treatment:
 NSAIDs: Ibuprofen, Naproxen, Diclofenac
 Mechanism: Reduce inflammation and pain by inhibiting COX enzymes
 Benefits: Effective in reducing pain and inflammation
 Side Effects: Gastrointestinal irritation, renal impairment
 Topical Analgesics: Diclofenac gel
 Mechanism: Localized COX inhibition
 Benefits: Fewer systemic side effects
 Acetaminophen: For pain management, especially in patients with contraindications to NSAIDs
 Mechanism: Central inhibition of COX enzymes
 Benefits: Good safety profile for long-term use
 Side Effects: Hepatotoxicity at high doses
 Rheumatoid Arthritis

1. Symptoms: Symmetrical joint inflammation, pain, swelling, morning stiffness
2. Treatment:
 NSAIDs: To manage pain and inflammation
 Examples: Ibuprofen, Diclofenac
 Corticosteroids: Prednisone, Dexamethasone
 Mechanism: Potent anti-inflammatory effects
 Benefits: Rapid relief of symptoms
 Side Effects: Long-term use can cause osteoporosis, hyperglycemia, and adrenal
suppression
 Rheumatoid Arthritis

2. Treatment:
 DMARDs: Methotrexate, Sulfasalazin
 Mechanism: Modulate the immune response to prevent joint damage
 Benefits: Slow disease progression
 Side Effects: Liver toxicity, bone marrow suppression
 Biologics: Etanercept, Infliximab
 Mechanism: Target specific components of the immune system (e.g., TNF-alpha).Benefits:
Effective in patients not responding to traditional DMARDs
 Side Effects: Increased risk of infections, injection site reactions
Tendonitis

1. Symptoms: Pain, swelling, tenderness around tendons
2. Treatment:
 NSAIDs: Oral (Ibuprofen, Naproxen, Diclofenac) or topical (Diclofenac gel)
 Mechanism: Reduce inflammation and pain
 Benefits: Effective relief of symptoms
 Side Effects: GI irritation (oral NSAIDs), skin irritation (topical NSAIDs)
 Corticosteroid Injections: For severe cases
 Mechanism: Potent local anti-inflammatory effect
 Benefits: Rapid symptom relief
 Side Effects: Tendon weakening, risk of rupture with repeated use
Bursitis

1. Symptoms: Pain, swelling, warmth around affected bursae (fluid-filled sacs cushioning joints)
2. Treatment:
 NSAIDs: Ibuprofen, Naproxen, Diclofenac
 Mechanism: Reduce inflammation and pain
 Benefits: Alleviate symptoms
 Side Effects: GI irritation, renal issues with prolonged use
 Corticosteroid Injections: For persistent inflammation
 Mechanism: Strong local anti-inflammatory effect
 Benefits: Effective in reducing swelling and pain
 Side Effects: Risk of infection at the injection site, weakening of surrounding tissues
 Rest and Physical Therapy: To prevent recurrence and promote healing.
 Benefits: Reduces strain on the affected area and enhances recovery
Rhinitis

1. Symptoms: Runny nose, Nasal congestion, Sneezing, Itchy nose, eyes, or throat, Postnasal drip
2. Treatments:
 Antihistamines (Loratadine, Cetirizine):
 Benefits: Relieve sneezing, itching, runny nose
 Side Effects: Drowsiness (depends on type)
 Corticosteroid Nasal Sprays (Fluticasone, Mometasone):
 Benefits: Decrease congestion, sneezing
 Side Effects: Nasal irritation, nosebleeds
 Decongestants (Pseudoephedrine, Phenylephrine):
 Benefits: Alleviate congestion
 Side Effects: Increased BP, insomnia
Sinusitis

1. Symptoms: Pain, swelling, tenderness around sinuses, Nasal congestion, Thick nasal discharge,
Headache, Reduced smell and taste, Fever, Cough
2. Treatment:
 NSAIDs (Ibuprofen, Naproxen, Diclofenac):
 Benefits: Alleviate symptoms
 Side Effects: GI irritation, renal issues
 Corticosteroid Nasal Sprays (Fluticasone, Budesonide):
 Benefits: Decrease swelling, relieve congestion
 Side Effects: Nasal irritation, nosebleeds
Sinusitis

 Antibiotics (Amoxicillin, Doxycycline):
 Benefits: Resolve infection
 Side Effects: GI upset, allergic reactions
 Decongestants (Pseudoephedrine, Phenylephrine):
 Benefits: Alleviate congestion
 Side Effects: Increased BP, insomnia
 Rest and Hydration:
 Benefits: Enhance recovery
 Side Effects: None
Clinical Applications: Pain
Conditions
Postoperative Pain Management
 NSAIDs:
 Examples: Ibuprofen, Naproxen, Diclofenac, Aspirin
 Mechanism: Inhibit COX enzymes, reducing prostaglandin synthesis
 Benefits: Effective in reducing mild to moderate pain and inflammation
 Considerations: Can cause gastrointestinal irritation and increased bleeding risk
 Opioids:
 Examples: Morphine, Oxycodone.
 Mechanism: Bind to opioid receptors in the central nervous system (CNS), altering the perception of pain
 Benefits: Effective for moderate to severe pain
 Side Effects: Sedation, constipation, risk of dependence and respiratory depression
 Administration: Often given intravenously or orally in the postoperative setting
 Multimodal Analgesia:
 Strategy: Combining different types of pain medications to enhance pain relief and reduce opioid
requirements
 Examples: NSAIDs or acetaminophen combined with opioids
 Benefits: Improved pain control, reduced opioid side effects
Chronic Pain Conditions
1. Non-Opioid Analgesics:
 Examples: Acetaminophen, NSAIDs.
 Uses: First-line treatment for conditions like osteoarthritis and chronic low back pain.
 Benefits: Generally well-tolerated, especially acetaminophen.
2. Opioids:
 Examples: Long-acting formulations like Oxycodone CR (controlled release), Fentanyl
patches.
 Uses: Reserved for severe chronic pain not responsive to other treatments.
 Considerations: Risk of tolerance, dependence, and side effects necessitate careful
monitoring
Chronic Pain Conditions
3. Adjuvant Analgesics:
 Antidepressants:
 Examples: Amitriptyline, Duloxetine.
 Mechanism: Enhance pain relief through modulation of serotonin and norepinephrine.
 Uses: Effective for neuropathic pain, fibromyalgia.
 Side Effects: Sedation, dry mouth, weight gain.
 Anticonvulsants:
 Examples: Gabapentin, Pregabalin.
 Mechanism: Stabilize nerve membranes, reducing neuropathic pain.
 Uses: Diabetic neuropathy, postherpetic neuralgia.
 Side Effects: Dizziness, somnolence.
4. Topical Analgesics:
 Examples: Lidocaine patches, Capsaicin cream.
 Uses: Localized pain, especially neuropathic pain.
 Benefits: Minimal systemic side effects.
Cancer Pain Management
1. Strong Opioids:
 Examples: Morphine, Hydromorphone.
 Mechanism: Bind to opioid receptors in the CNS.
 Benefits: Effective for severe pain, commonly used in palliative care.
 Administration: Oral, intravenous, subcutaneous, or transdermal.
2. Adjuvant Therapies:
 Examples: Bisphosphonates for bone pain, corticosteroids for inflammation-related pain.
 Mechanism: Target specific pain pathways and underlying causes of pain.
 Benefits: Enhances overall pain management and patient quality of life.
3. Non-Pharmacological Interventions:
 Examples: Physical therapy, psychological support, nerve blocks.
 Uses: Complementary approaches to reduce pain and improve function.
 Benefits: Holistic approach to pain management, addressing physical and emotional aspects of
pain.
Clinical Applications: Fever
Reduction
Fever

Acetaminophen (Paracetamol) NSAIDs
 Uses: First-line treatment for fever in  Common Examples: Ibuprofen, Aspirin, Naproxen,
children and adults Diclofenac
 Dosage:  Uses: Effective in reducing fever and providing
 Adults: Typically 500-1000 mg every 4-6
additional anti-inflammatory and analgesic benefits
hours, not exceeding 4000 mg per day  Dosage:
 Children: Dosed based on weight,  Ibuprofen:
typically 10-15 mg/kg every 4-6 hours
 Adults: 200-400 mg every 4-6 hours, not exceeding
 Side Effects: Generally well-tolerated, but 3200 mg per day
high doses can cause hepatotoxicity
 Children: 5-10 mg/kg every 6-8 hours
(liver damage)
 Aspirin:
 Liver Function: Monitor in patients using
high doses of acetaminophen or with  Adults: 325-650 mg every 4-6 hours, not exceeding
preexisting liver conditions 4000 mg per day. Not recommended for children
due to the risk of Reye’s syndrome
Fever

NSAIDs
 Side Effects: Gastrointestinal irritation, risk of bleeding, renal impairment
 Renal Function: Monitor in patients using NSAIDs, especially long-term use
 Drug Interactions: Be aware of potential interactions with other medications,
such as anticoagulants with NSAIDs
Clinical Applications: Autoimmune
Disorders
Systemic Lupus Erythematosus (SLE)

1. Anti-Malarial Drugs:
 Hydroxychloroquine:
 Mechanism: Modulates immune system activity
 Uses: Reduces flares, improves long-term outcomes, and reduces cardiovascular risk
 Side Effects: Retinal toxicity (requires regular eye exams), gastrointestinal issues
2. Corticosteroids:
 Mechanism: Powerful anti-inflammatory effects
 Uses: Acute management of severe disease flares
 Examples: Prednisone, Methylprednisolone
 Side Effects: Same as in rheumatoid arthritis; long-term use should be minimized
Systemic Lupus Erythematosus (SLE)
3. Immunosuppressants:
 Azathioprine:
 Mechanism: Inhibits purine synthesis, reducing immune cell proliferation
 Uses: Maintenance therapy to reduce disease activity
 Side Effects: Bone marrow suppression, liver toxicity, increased infection risk
 Mycophenolate Mofetil:
 Mechanism: Inhibits inosine monophosphate dehydrogenase, affecting lymphocyte proliferation
 Uses: Severe lupus nephritis and other severe manifestations
 Side Effects: Gastrointestinal disturbances, increased infection risk, teratogenicity
4. Biologics:
 Belimumab:
 Mechanism: Inhibits B-cell activating factor (BAFF), reducing B-cell survival
 Uses: Active, autoantibody-positive lupus with inadequate response to standard therapies
 Side Effects: Nausea, diarrhea, fever, increased risk of infections
Inflammatory Bowel Disease (IBD)

1. Corticosteroids:
 Mechanism: Reduce inflammation by suppressing immune response.
 Uses: Induction of remission in moderate to severe IBD (Crohn's disease and ulcerative
colitis).
 Examples: Prednisone, Budesonide, Dexamethasone
 Side Effects: Similar to other autoimmune uses; focus on minimizing long-term use.
2. Aminosalicylates:
 Examples: Mesalamine, Sulfasalazine.
 Mechanism: Anti-inflammatory effects in the gastrointestinal tract.
 Uses: Induction and maintenance of remission in mild to moderate ulcerative colitis.
 Side Effects: Headache, nausea, rash, rare nephrotoxicity
Inflammatory Bowel Disease (IBD)

3. Immunosuppressants:
 Thiopurines (e.g., Azathioprine, 6-Mercaptopurine):
 Mechanism: Inhibit purine synthesis, reducing immune cell proliferation.
 Uses: Maintenance therapy in IBD.
 Side Effects: Bone marrow suppression, liver toxicity, increased infection risk.

4. Biologics:
 TNF Inhibitors (e.g., Infliximab, Adalimumab):
 Mechanism: Inhibit TNF, reducing inflammation.
 Uses: Moderate to severe Crohn's disease and ulcerative colitis not responding to other
treatments.
 Side Effects: Increased infection risk, potential risk of malignancies