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Flashcards in this deck (19)

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  • What is the signaling mechanism and primary locations of Alpha-1 (\alpha_1) receptors?

    • Mechanism: G_q protein \rightarrow \uparrow IP_3/DAG/Ca^{2+}.
    • Locations: Mainly postsynaptic (smooth muscles).
    • Key actions: Vasoconstriction; contraction of dilator pupillae; contraction of sphincters; liver glycogenolysis.
    adrenergic alpha1

  • What is the signaling mechanism and primary actions of Alpha-2 (\alpha_2) receptors?

    • Mechanism: G_i protein \rightarrow \downarrow cAMP.
    • Locations: Pre-synaptic, post-synaptic, and CNS.
    • Key actions: \downarrow sympathetic flow from CNS; \downarrow NE release; \downarrow insulin; \downarrow renin; \downarrow lipolysis; \uparrow platelet aggregation.
    adrenergic alpha2

  • What is the signaling mechanism and cardiac effects of Beta-1 (\beta_1) receptors?

    • Mechanism: G_s protein \rightarrow \uparrow cAMP.
    • Actions: +ve inotropic, chronotropic, dromotropic, and excitability.
    • Other: \uparrow renin production; \uparrow lipolysis.
    adrenergic beta1

  • What are the smooth muscle and metabolic effects of Beta-2 (\beta_2) receptors?

    • Smooth muscle: Relaxation (bronchi, GIT wall, detrusor, uterus).
    • Blood vessels: Vasodilation (coronary and skeletal muscle).
    • Metabolic: \uparrow glycogenolysis; \uparrow insulin; \uparrow K^{+} uptake into cells (can cause hypokalemia/tremors).
    adrenergic beta2

  • Define direct vs indirect sympathomimetics and give examples.

    • Direct: Bind directly to receptors. e.g., Adrenaline, Noradrenaline, Phenylephrine.
    • Indirect: Release stored NE from vesicles. e.g., Amphetamine, Tyramine.
    • Note: Indirect agonists show tachyphylaxis (depletion of stores).
    pharmacology sympathomimetic

  • Contrast catecholamines and non-catecholamines for oral bioavailability and CNS penetration.

    • Catecholamines: Poor oral bioavailability (destroyed by COMT/MAO); poor BBB penetration (minimal CNS effects).
    • Non-catecholamines: Good oral bioavailability (resistant to COMT); good BBB penetration (marked CNS effects).
    pharmacokinetics catecholamine

  • What is 'Adrenaline Reversal' (Dale's Vasomotor Reversal)?

    If adrenaline is given after an \alpha-blocker, the \alpha_1 vasoconstrictor effect is removed, leaving only the \beta_2 vasodilator effect, causing a paradoxical fall in blood pressure.

    adrenaline interaction

  • List five therapeutic uses for Adrenaline (Epinephrine).

    • Anaphylactic shock (drug of choice)
    • Cardiac arrest (resuscitation)
    • Acute asthma (bronchodilation)
    • Epistaxis (local hemostasis)
    • With local anesthetics (to prolong duration)
    adrenaline uses

  • Why is Adrenaline contraindicated in peripheral structures (fingers, toes, ears, nose, penis)?

    Intense \alpha_1-mediated vasoconstriction can cause severe ischemia leading to gangrene.

    adrenaline contraindication

  • Compare the receptor profiles of Adrenaline, Noradrenaline, and Isoprenaline.

    • Adrenaline: \alpha_1, \alpha_2, \beta_1, \beta_2 (non-selective).
    • Noradrenaline: \alpha_1, \alpha_2 >> weak \beta_1 (minimal \beta_2).
    • Isoprenaline: Pure \beta_1, \beta_2 (no \alpha activity).
    receptors comparison

  • Explain the dose-dependent effects of Dopamine infusion.

    • Low dose (2-5 \mu g): D_1 receptors \rightarrow renal/mesenteric vasodilation (\uparrow urine flow).
    • Moderate (5-10 \mu g): \beta_1 \rightarrow \uparrow cardiac output.
    • High (>10 \mu g): \alpha_1 \rightarrow generalized vasoconstriction (\uparrow BP).
    dopamine dose

  • What is the primary clinical indication for Dobutamine?

    Acute heart failure and cardiogenic shock; it is a selective \beta_1 agonist.

    dobutamine indication

  • What is the mechanism of Amphetamine?

    • Indirectly releases NE and Dopamine in the CNS and periphery.
    pharmacology amphetamine

  • What are the primary clinical uses of Amphetamine?

    • Narcolepsy
    • ADHD (as Methylphenidate)
    • Short-term obesity treatment
    pharmacology uses

  • What is the 'Cheese Reaction' in patients on MAO inhibitors?

    When a patient on MAO Inhibitors eats foods high in Tyramine, Tyramine isn't metabolized and causes massive NE release leading to a severe Hypertensive Crisis.

    drug-interactions maoi

  • What is Phenylephrine used for?

    • Selective \alpha_1 agonist used as a nasal decongestant and for mydriasis.
    pharmacology phenylephrine

  • What is a common topical side effect of Phenylephrine with prolonged use?

    Rebound congestion (rhinitis medicamentosa) if used for more than 3-5 days.

    side-effects phenylephrine

  • Name three \beta_2 selective drugs used for tocolysis or vasodilation.

    • Ritodrine (Tocolysis - suppress premature labor)
    • Isoxsuprine (Peripheral vascular disease)
    • Salbutamol (Mainly Bronchodilation)
    beta2 drugs

  • What is Mirabegron used for and its receptor selectivity?

    • Overactive Bladder Syndrome; selective \beta_3 agonist that promotes bladder (detrusor) relaxation.
    mirabegron urology
Çalışma Notları

High-yield summary

  • These notes cover adrenergic receptor signaling, sympathomimetic types, catecholamine drugs and key non-catecholamine agents.
  • Focus is on mechanisms, principal effects, clinical uses and major cautions.

1) Adrenergic receptors — signaling and main actions

Alpha-1 (\(\alpha_1\))

  • Signaling: \(G_q \rightarrow \uparrow IP_3/DAG/\mathrm{Ca}^{2+}\).
  • Location: Mostly postsynaptic on smooth muscle.
  • Key actions: Vasoconstriction (skin/mucosa/splanchnic), pupillary dilator contraction (mydriasis), sphincter contraction (GIT/urinary), hepatic glycogenolysis.

Alpha-2 (\(\alpha_2\))

  • Signaling: \(G_i \rightarrow \downarrow cAMP\).
  • Location: Presynaptic (autoreceptors), postsynaptic, CNS.
  • Key actions: Decreases sympathetic outflow, decreases NE release, reduces insulin, renin, lipolysis; increases platelet aggregation.

Beta-1 (\(\beta_1\))

  • Signaling: \(G_s \rightarrow \uparrow cAMP\).
  • Cardiac effects: Positive inotropy, chronotropy, dromotropy and increased excitability (all cardiac properties up).
  • Other: Increases renin release and lipolysis.

Beta-2 (\(\beta_2\))

  • Smooth muscle: Relaxes bronchi, GI wall, detrusor and uterus.
  • Vessels: Vasodilation in coronary and skeletal muscle beds.
  • Metabolic: Increases glycogenolysis and insulin; increases cellular K+ uptake (can cause hypokalemia and tremor).

Beta-3 (\(\beta_3\))

  • Action: Detrusor relaxation (used in overactive bladder).

2) Sympathomimetic fundamentals

Direct vs Indirect agonists

  • Direct: Bind receptors directly (e.g., adrenaline, noradrenaline, phenylephrine).
  • Indirect: Release stored NE from nerve terminals (e.g., amphetamine, tyramine); cause tachyphylaxis due to depletion of stores.

Catecholamines vs Non-catecholamines

  • Catecholamines: Poor oral bioavailability (rapidly metabolized by COMT/MAO); poor BBB penetration → minimal CNS effects.
  • Non-catecholamines: More orally available (resistant to COMT) and penetrate BBB → greater CNS effects.

3) Important catecholamine drugs & concepts

Adrenaline (epinephrine)

  • Receptor profile: Non-selective: \(\alpha_1,\ \alpha_2,\ \beta_1,\ \beta_2\).
  • Therapeutic uses: 1) Anaphylaxis (drug of choice), 2) Cardiac arrest (resuscitation), 3) Acute severe asthma, 4) Local hemostasis/epistaxis, 5) Added to local anesthetics to prolong duration.
  • Contraindication in peripheral end-artery sites: Avoid fingers, toes, ears, nose, penis — intense \(\alpha_1\) vasoconstriction may cause ischemia/gangrene.
  • Adrenaline (Dale) reversal: If given after an \(\alpha\)-blocker, \(\alpha_1\) vasoconstriction is abolished and \(\beta_2\) vasodilation predominates, producing a paradoxical fall in BP.

Noradrenaline (norepinephrine)

  • Profile: Strong \(\alpha_1,\ \alpha_2\) and weak \(\beta_1\); minimal \(\beta_2\).
  • Effect: Potent vasoconstrictor, increases BP and reflex bradycardia.

Isoprenaline (isoproterenol)

  • Profile: Pure \(\beta_1,\ \beta_2\) agonist; no \(\alpha\) activity.
  • Effect: Powerful cardiac stimulation and vasodilation in skeletal muscle beds.

Dopamine — dose-dependent receptor effects

  • Low dose: \(\mathbf{2\text{--}5\ \mu g}\) → activates \(D_1\) receptors → renal/mesenteric vasodilation, ↑ urine flow.
  • Moderate dose: \(\mathbf{5\text{--}10\ \mu g}\) → activates \(\beta_1\) → ↑ cardiac output.
  • High dose: \(\mathbf{>10\ \mu g}\) → activates \(\alpha_1\) → generalized vasoconstriction and ↑ BP.

Dobutamine

  • Profile/use: Relatively selective \(\beta_1\) agonist used in acute heart failure/cardiogenic shock to increase contractility with minimal peripheral resistance change.

4) Non-catecholamines & selected drugs

Amphetamine (and methylphenidate class)

  • Mechanism: Indirectly causes release of NE and dopamine in CNS and periphery.
  • Uses: Narcolepsy, ADHD (methylphenidate), short-term obesity treatment.

"Cheese reaction"

  • Cause: Patients on MAO inhibitors ingest tyramine-rich foods (aged cheese, wine) → tyramine not broken down → massive NE release → severe hypertensive crisis.

Phenylephrine

  • Profile/use: Selective \(\alpha_1\) agonist used as a nasal decongestant and for mydriasis.
  • Common topical side effect: Rebound congestion (rhinitis medicamentosa) after prolonged use (>3–5 days).

Selective \(\beta_2\) agents (examples)

  • Ritodrine — tocolysis (suppresses premature labor).
  • Isoxsuprine — used in peripheral vascular disease (vasodilation).
  • Salbutamol (albuterol) — primary bronchodilator for asthma.

Mirabegron

  • Profile/use: Selective \(\beta_3\) agonist for overactive bladder; relaxes detrusor muscle.

5) Clinical cautions & common adverse effects

  • Alpha-mediated vasoconstriction: Risk of tissue ischemia if applied locally to end-artery areas; reversible agents preferred.
  • Beta-2 stimulation: May cause tremor and hypokalemia due to increased K+ uptake into cells.
  • Indirect sympathomimetics: Risk of tachyphylaxis and interactions with MAO inhibitors (severe hypertensive episodes).
  • Adrenaline use in uncontrolled hypertension or on \(\alpha\)-blockers: watch for paradoxical BP responses (adrenaline reversal).

6) Quick reference — receptor summary table

Receptor Signaling Principal effects
\(\alpha_1\) \(G_q \rightarrow \uparrow IP_3/DAG/\mathrm{Ca}^{2+}\) Vasoconstriction, sphincter contraction, mydriasis
\(\alpha_2\) \(G_i \rightarrow \downarrow cAMP\) Decrease NE release, lower sympathetic outflow
\(\beta_1\) \(G_s \rightarrow \uparrow cAMP\) ↑ Heart rate & contractility, ↑ renin
\(\beta_2\) \(G_s \rightarrow \uparrow cAMP\) Bronchodilation, vasodilation, ↑ glycogenolysis
\(\beta_3\) \(G_s\) (mainly) Detrusor relaxation (bladder)

7) Memorize these high-yield facts

  • Adrenaline = non-selective (\(\alpha\) + \(\beta\)) — use in anaphylaxis and arrest.
  • Adrenaline reversal occurs if \(\alpha\) blockade already present.
  • Dopamine effects are dose-dependent: \(2\)--\(5\), \(5\)--\(10\), \(>10\ \mu g\) categories.
  • Non-catecholamines are orally active and cross BBB; catecholamines do not.