1. The Autonomic Nervous System (Ch 13)

2. Two Major Divisions of the Nervous System
Central Nervous System (CNS)
Brain and spinal cord
Peripheral Nervous System
all nervous tissue outside the CNS, including sensory and motor neurons 2

3. Basic Functions of the Nervous System
Recognizing changes in
Internal environment
External environment
Processing and integrating environmental changes
Reacting to environmental changes by producing and action or response 3

4. Figure 13.1 Functional divisions of the peripheral nervous system.

5. Divisions of the Peripheral Nervous System
Somatic nervous system
Voluntary control over skeletal muscles
Autonomic nervous system
Involuntary control over smooth and cardiac muscle and glands 5

6. Autonomic Nervous System: Sympathetic Nervous System
Activated under stress
Fight-or-flight response
Ready the body for an immediate response to a potential threat 6

7. Autonomic Nervous System: Parasympathetic Nervous System
Activated under nonstressful conditions
Rest-and-digest response
Digestive processes promoted, heart rate and blood pressure decline 7

8. Autonomic Nervous System: Sympathetic and Parasympathetic Divisions
Branches produce mostly opposite effects
Homeostasis – proper balance of the two branches
achieved by changing one or both branches
Branches do not always produce opposite effects 8

9. Figure Effects of the sympathetic and parasympathetic nervous systems. Source: Biology Guide to the Natural World, 2nd ed (p. 558) by David Krogh, 2002 Upper Saddle River, NJ, Prentice Hall. Reprinted by permission.

10. Synaptic Transmission
Synapse – juncture of neurons
Connection of two neurons outside CNS – ganglionic synapse
Preganglionic neuron
Postganglionic neuron
Many drugs affect autonomic function by altering neurotransmitter activity at the second synapse 10

11. Five Mechanisms by Which Drugs Can Affect Synaptic Transmission
1. Affect the synthesis of the neurotransmitter in the presynaptic nerve
2. Prevent storage of the neurotransmitter in vesicles within the presynaptic nerve
3. Influence release of the neurotransmitter from the presynaptic nerve
4. Prevent the normal destruction or reuptake of the neurotransmitter
5. Bind to the receptor site on the postsynaptic target tissue 11

12. Drugs Not Given to Correct Autonomic Nervous System
System is relatively free of disease
Drugs used to stimulate or inhibit target organs of the autonomic nervous system 12

13. Figure 13.3 Basic structure of the autonomic pathway.

14. Figure Receptors in the autonomic nervous system: (a) sympathetic division; (b) parasympathetic division 14

15. Primary Neurotransmitters of Autonomic Nervous System
Norepinephrine (NE)
Acetylcholine (Ach) 15

16. Norepinephrine Released by most postganglionic nerves
Class of agents called natural catecholamines, all involved in neurotransmission
Adrenergic receptors - receptors at the ends of postganglionic sympathetic neurons 16

17. 17

18. Two Types of Adrenergic Receptors
Alpha-receptors and Beta-receptors
Hugely important to pharmacology
Drugs are selective and activate only one type of adrenergic receptor, whereas others affect all receptor subtypes 18

19. 19

20. Alpha1-adrenergic Receptors
In all sympathetic target organs except heart
Response
Constriction of blood vessels
Dilation of pupils 20

21. Alpha2-adrenergic Receptors
At presynaptic adrenergic neuron terminals
Activation inhibits release of norepinephrine 21

22. Beta1-adrenergic Receptors
In heart and kidneys
Response
Activation increases heart rate and force of contraction of heart.
Increases release of renin 22

23. Beta2-adrenergic Receptors
In all sympathetic target organs except the heart
Inhibit smooth muscle 23

24. Prototype Drug: Phenylephrine (Neo-Synephrine)24

25. Prototype Drug: Phenylephrine (Neo-Synephrine)25

26. Norepinephrine (NE) is synthesized
In the nerve terminal
Requires the amino acids phenylalanine and tyrosine
Conversion of dopamine to norepinephrine
NE in nerve terminal may be returned to vesicles for future use, or destroyed enzymatically by monoamine oxidase 26

27. Adrenal Medulla
Anatomic and physiologic arrangement much different from rest of sympathetic branch 27

28. Other types of adrenergic receptors
Dopamine serves a larger role as a neurotransmitter 28

29. Acetylcholine Released by cholinergic nerves
Two types cholinergic receptors
Muscarinic receptors
Nicotinic receptors 29

30. Nicotinic Receptors
In sympathetic and parasympathetic divisions at the ganglionic synapse
Response
Stimulate smooth muscle
Stimulate gland secretion 30

31. Muscarinic Receptors In parasympathetic target organs except the heart
Response
Stimulate smooth muscle
Stimulate gland secretion
In heart: decreased heart rate and force of contraction 31

32. Physiology of Acetylcholine
Affords several mechanisms by which drugs may act
Synthesized in presynaptic nerve terminal from choline and acetyl coenzyme A
Ach in the synaptic cleft is rapidly destroyed by the enzyme acetylcholinesterase (AchE) 32

33. Classification and Naming of Autonomic Drugs
Based on four possible actions of sympathetic and parasympathetic nervous systems
Stimulate sympathetic nervous system
Adrenergic agents or sympathomimetics
Inhibit sympathetic nervous system
Adrenergic-blocking agents, adrenergic antagonists, or sympatholytics 33

34. Classification and Naming of Autonomic Drugs (cont'd)
Stimulate parasympathetic nervous system
Cholinergic agents or parasympathomimetics
Inhibit parasympathetic nervous system
Cholinergic-blocking agents, anticholinergics, parasympatholytics, or muscarinic blockers 34

35. One of Four Drug Classes is Most Important to Learn
If the fight-or-flight actions of the sympathomimetics are learned, the other three groups can be deduced
Mastering the actions and terminology of autonomic drugs early will pay dividends later 35

36. Role of Nurse Monitor patient’s condition
Provide education on drug therapy
Note adverse effects of drug therapy
Identify possible interactions
Identify contraindications of drug therapy 36

37. Sympathomimetic
Monitor vital signs, urinary and cardiac output as appropriate
Monitor breathing patterns
Observe patient’s responsiveness to light
Monitor for rhinorrhea and epistaxis 37

38. Nursing Process Focus: Patients Receiving Adrenergic (Sympathomimetic Therapy)38

39. Nursing Process Focus: Patients Receiving Adrenergic (Sympathomimetic Therapy)39

40. Nursing Process Focus: Patients Receiving Adrenergic (Sympathomimetic Therapy)40

41. Nursing Process Focus: Patients Receiving Adrenergic (Sympathomimetic Therapy)41

42. Anticholinergics Monitor for signs of anticholinergic crisis
Report changes in heart rate, blood pressure, or development of dysrhythmias
Provide comfort measures for dry mouth 42

43. Anticholinergic (cont'd)
Minimize exposure to heat or cold or strenuous exercise
Monitor intake and output
Monitor patient for abdominal distension, and auscultate for bowel sounds 43

44. Nursing Process Focus: Patients Receiving Anticholinergic Therapy44

45. Nursing Process Focus: Patients Receiving Anticholinergic Therapy45

46. Nursing Process Focus: Patients Receiving Anticholinergic Therapy46

47. Nursing Process Focus: Patients Receiving Anticholinergic Therapy47

48. Adrenergic Blockers
Monitor urinary hesitancy, incomplete bladder emptying, interrupted urinary stream
Monitor vital signs, level of consciousness, and mood
Monitor for dizziness, drowsiness, or light-headedness
Observe for side effects
Monitor cardiac output 48

49. Nursing Process Focus: Patients Receiving Adrenergic-Blocker Therapy49

50. Nursing Process Focus: Patients Receiving Adrenergic-Blocker Therapy50

51. Nursing Process Focus: Patients Receiving Adrenergic-Blocker Therapy51

52. Nursing Process Focus: Patients Receiving Adrenergic-Blocker Therapy52

53. Parasympathomimetics
Monitor for adverse effects
Monitor liver enzymes
Calculate and monitor doses
Assess and monitor for appropriate self-care administration 53

54. Direct Acting Monitor intake and output ratio
Monitor for blurred vision
Monitor for orthostatic hypotension 54

55. Cholinesterase Inhibitors
Monitor muscle strength and neuromuscular status
Monitor ptosis, diplopia, and chewing
Schedule medication around mealtimes
Schedule activities to avoid fatigue
Monitor for muscle weakness 55

56. Nursing Process Focus: Patients Receiving Parasymptathomimetic Therapy56

57. Nursing Process Focus: Patients Receiving Parasymptathomimetic Therapy57

58. Nursing Process Focus: Patients Receiving Parasymptathomimetic Therapy58

59. Nursing Process Focus: Patients Receiving Parasymptathomimetic Therapy59

60. Nursing Process Focus: Patients Receiving Parasymptathomimetic Therapy60

61. Adrenergic Agents (Sympathomimetics)
Prototype drug: phenylephrine (Neo-Synephrine)
Mechanism of action: to stimulate the sympathetic nervous system directly/indirectly
produce many of the same responses as the anticholinergics 61

62. Adrenergic Agents (Sympathomimetics) (cont'd)
Primary use: depends on receptors activated
Alpha1-receptors: nasal congestion, hypotension, dilation of pupils for eye examination
Alpha2-receptors: hypertension
Beta1-receptors: cardiac arrest, heart failure, shock
Beta2-receptors: asthma and premature-labor contractions 62

63. Adrenergic Agents (Sympathomimetics) (cont'd)
Adverse effects: tachycardia, hypertension, dysrhythmias, CNS excitation and seizures, dry mouth, nausea and vomiting, anorexia 63

64. Adrenergic-Blocking Agents
Prototype drug: prazosin (Minipress)
Mechanism of action: to inhibit the sympathetic nervous system
Primary use: hypertension, dysrhythmias, angina, heart failure, benign prostatic hypertrophy, narrow-angle glaucoma
Adverse effects: dizziness, drowsiness, headache, loss of energy and strength, palpitations, dry mouth 64

65. Prototype Drug: Prazosin (Minipress)65

66. Adrenergic-Blocking Agents
Primary use of beta blockers is in the treatment of hypertension
Beta-adrenergic antagonists have several other important therapeutic applications
angina pectoris
Migranes
Heart failure 66

67. 67

68. Cholinergic Agents (Parasympathomimetic)
Prototype drug: bethanechol (Urecholine)
Mechanism of action: to activate the parasympathetic nervous system directly/indirectly, induce rest/digest response
Uses: glaucoma, urinary retention, myasthenia gravis, Alzheimer’s disease
Adverse effects: profuse salivation, sweating increased muscle tone, urinary frequency, bradycardia 68

69. Prototype Drug: Bethanechol (Duvoid,Urecholine)69

70. 70

71. Cholinergic Agents (Parasympathomimetic)
Divided into two classes
direct acting
bind to cholinergic receptors to produce the rest-and-digest response
indirect acting
inhibit the action of AchE
High potential for serious adverse effects 71

72. Cholinergic-Blocking Agents
Prototype drug: atropine (Atropair, Atropisol)
Mechanism of action: to inhibit the parasympathetic nervous system
Primary use: peptic ulcers, irritable bowel syndrome, mydriasis and cycloplegia during eye examination, bradycardia, preanesthetic, asthma
Adverse effects: tachycardia, CNS stimulation, urinary retention, dry mouth, dry eyes, decreased sweating, photophobia 72

73. 73

74. Prototype Drug: Atropine (Atro-Pen, Atropair,Atropisol)74

75. Prototype Drug: Atropine (Atro-Pen, Atropair,Atropisol)75

76. Drugs Affecting the Autonomic Nervous System
Assessment
Potential nursing diagnoses
Reason for drug
Monitoring vital signs
Doing complete health history 76

77. Drugs Affecting the Autonomic Nervous System (cont'd)
Cautions and contraindications for drug
Allergies
Drug history
Possible drug interactions
Evaluating lab findings
Assess for therapeutics effect
Watch for adverse effects 77

78. Drugs Affecting the Autonomic Nervous System (cont'd)
Nursing Diagnosis
Knowledge deficient, related to drug therapy
Risk for injury, related to side effect of drug therapy
Disturbed sleep pattern 78

79. Drugs Affecting the Autonomic Nervous System (cont'd)
Planning
Patient will exhibit therapeutic outcome based on specific drug
Patient will demonstrate an understanding of drug’s activity
Patient will accurately describe drug side effects and precautions
Patient will demonstrate proper administration technique 79

80. Drugs Affecting the Autonomic Nervous System (cont'd)
Implementation
Administration of drug
Observing for adverse effects
Patient education/discharge planning
Providing additional information as needed to encourage compliance
Doing home-health visits 80

81. Drugs Affecting the Autonomic Nervous System (cont'd)
Evaluation
Evaluating effectiveness of drug therapy
Confirming that patient goals and expected outcomes have been met 81

82. NCLEX-RN Review Question 1
1. Following administration of an adrenergic (sympathomimetic) drug, the nurse would assess for which adverse drug effects?
Insomnia, nervousness, and hypertension
Nausea, vomiting, and hypotension
Nervousness, drowsiness, and dyspnea
Bronchial dilation, hypotension, and bradycardia 82

83. NCLEX-RN Review Question 1 – Rationale
Rationale: Adrenergic agonists stimulate the sympathetic nervous system and produce symptoms of the fight-or-flight response. Nausea, vomiting, nervousness, bronchial dilation, and hypertension are potential adverse reactions related to the use of adrenergic agonists. Hypotension is a potential adverse reaction related to the use of adrenergic antagonists. 83

84. NCLEX-RN Review Question 2
2. Adrenergic-blocking (antagonist) drugs may include all of the following adverse reactions except:
Bronchodilation
Tachycardia
Edema
Heart failure 84

85. NCLEX-RN Review Question 2 – Rationale
Rationale: Potential adverse reactions associated with the use of adrenergic antagonists include tachycardia, edema, and heart failure. Bronchodilation is associated with the use of adrenergic agonists. Cognitive Level: Analysis Nursing Process: Assessment Patient Need: Physiological Integrity 85

86. NCLEX-RN Review Question 3
3. Elderly patients taking bethanechol (Urecholine) need to be assessed more frequently because of which of the following side effects?
Diaphoresis
Hypertension
Dizziness
Urinary retention 86

87. NCLEX-RN Review Question 3 – Rationale
Rationale: The nurse should monitor elderly patients for episodes of dizziness caused by CNS stimulation from the parasympathomimetic. Diaphoresis and dizziness are potential side effects related to the use of bethanechol. Bethanechol is used to treat nonobstructive urinary retention. Cognitive Level: Application Nursing Process: Implementation Patient Need: Physiological Integrity 87

88. NCLEX-RN Review Question 4
The patient taking benztropine (Cogentin) should be assessed for:
Heartburn
Constipation
Hypothermia
Increased gastric motility 88

89. NCLEX-RN Review Question 4 – Rationale
Rationale: Anticholinergic medications slow intestinal motility; therefore, constipation is a potential side effect. Heartburn and hypothermia are not associated with the use of benztropine. Cognitive Level: Application Nursing Process: Assessment Patient Need: Physiological Integrity 89

90. NCLEX-RN Review Question 5
5. The patient taking tacrine (Cognex) should be observant for which of the following adverse effects that may signal a possible overdose has occurred?
Excessive sweating, salivation, and drooling
Extreme constipation
Hypertension and tachycardia
Excessively dry eyes and reddened sclera 90

91. NCLEX-RN Review Question 5 – Rationale
Rationale: Overdosage of parasympathomimetics (cholinesterase inhibitors) may produce excessive sweating, drooling, dyspnea, or excessive fatigue. These symptoms should be promptly reported. Cognitive Level: Comprehension Nursing Process: Assessment Patient Need: Physiological Integrity 91