Gq receptor
↑ Phospholipase C → ↑ IP3, DAG, Ca2+
- A1
- M1, M3, M5
- V1
- H1
Gi receptor
↓ adenylate cyclase → ↓ cAMP
- A2
- M2, M4
- D2
Gs receptor
↑ adenylate cyclase → ↑ cAMP
- B1, B2
- D1
- V2
- H2
B1 receptor
- myocardium, conduction system → ↑ HR, contractility, conduction speed
- kidneys → renin release
B2 receptor
Bronchial tree → bronchodilation
Myocardial and skeletal muscle vascular beds → vasodilation
Ciliary muscle relaxes (far vision)
Gallbladder and ducts relax
Pancreas islet beta cells release MORE insulin
Liver ↑ serum glucose
Uterus relaxes
Bladder: destrusor relaxes
A1 receptor
Vasoconstriction (arteries > veins, but both)
EYES: radial muscle (iris) → contracts → MYDRIASIS
GI: sphincters contract
LIVER: serum glucose ↑
UTERUS: contracts
BLADDER: trigone + sphincter contract
Sweat glands ↑ secretion
A2 receptor
- vasoconstriction (veins > arteries, but both)
- Kidney: renal tubules → ADH inhibition → DIURESIS
- pancreas: Islet beta cells ↓ insulin release → hyperglycemia
- Salivary glands: dries out
- antishivering
- promotes platelet aggregation
SNS receptors in kidneys
A2 (renal tubules, diuresis via ADH inhibition)
B1 (↑ renin release)
DA receptors
-renal and mesenteric vasodilation
M2 receptors
-HEART: myocardium, conduction system: → ↓ HR, contractility
M3 receptor
BRONCHIAL TREE → bronchoconstriction
Phosphodiesterase III
- metabolizes cAMP to AMP which basically “turns off” a specific protein kinase, the cell is no longer instructed to perform that specific function.
- If you inhibit PDEIII, the “turn off” mechanism is inhibited and it indirectly ↑ cAMP, maintaining the protein kinases in the “turned on” state.
Lusitropy
Increasing the rate of relaxation by speeding up the return of calcium to the SR
Adrenal medulla
80% epi, 20% norepi
At rest secretes:
- 2mcg/kg/min epi
- 05mcg/kg/min norepi
Remember catecholamines in the bloodstream last 5-10X longer than they do in the synaptic cleft
Baroreceptor reflex monitoring locations and innervation: AFFERENT
- ) carotid sinus —> carotid sinus nerves (nerves of Hering) + CN IX (glossopharyngeal) converge to send afferent impulses to nucleus tractus solitarus in the medulla
- ) Transverse aortic arch sends afferent signal via vagus nerve.
Baroreceptor reflex location and innervation: EFFERENT
Vasomotor center in medulla and pons
Afferent traffic to nucleus tractus solitarus stimulates rostral ventrolateral medulla and intermediolateral nucleus.
SNS output is ↓ via inhibition of T1-T4 cardio accelerator nerves, neural network to vasculature, and at the same time a reciprocal rise in vagal tone. The net effect is ↓ HR, inotropy, and SVR.
Clinical examples of baroreceptor reflex
CEA: carotid sinus may cause bradycardia
Mediastinoscopy: pressure from scope on transverse aortic arch may cause bradycardia
Phenylephrine!
Drugs that preserve baroreceptor reflex
TPL, etomidate, hydralazine, SNP, NTG, norepi
ANS receptors: eye
A1: contraction radial muscle → mydriasis
B2: relaxation ciliary muscle → far vision
ANS receptors: pancreas
A2: ↓ insulin release
B2: ↑ insulin release
ANS receptors: liver
A1: ↑ serum glucose
B2: ↑ serum glucose
ANS receptors: uterus
A1: contraction
B2: relaxation
ANS receptors: bladder
A1: trigone + sphincter contraction (facilitates urination)
B2: detrustor relaxation (facilitates retention/storage)
Vasopressin receptors
V1: Gq
V2: Gs
