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APNEA

APNEA. Understand the control and maturation of breathing in the fetus and newborn. Review the basic definitions of abnormal breathing in the newborn. Discuss evaluation and management of apnea and explore the reasons for home monitoring. OBJECTIVES. RESPIRATORY CONTROL. Normal Physiology

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APNEA

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  1. APNEA

  2. Understand the control and maturation of breathing in the fetus and newborn. Review the basic definitions of abnormal breathing in the newborn. Discuss evaluation and management of apnea and explore the reasons for home monitoring. OBJECTIVES

  3. RESPIRATORY CONTROL • Normal Physiology • central generation/maintenance of resp. rhythm • modulation of rhythm by central and peripheral feedback loops • recruitment of respiratory muscles appropriate for the task • Not entirely an “autopilot” process

  4. Receptor Response Importance Facialcutaneous receptors inhibitory newborn nasal mucosal receptors inhibitory infants laryngeal receptors inhibitory most potent Airway smooth muscle receptors inhibitory Hering-Breuer reflex Lung parenchyma stretch receptor inhibitory delay inspiration Lung J receptors excitatory pulmonary edema Bronchial irritant receptors inhibitory shorten inspiration Central chemoreceptors (?medulla) excitatory H Pco2, L pH (H high, L low) inhibitory L Pco2, H pH Carotid body (peripheral chemoreceptor) excitatory L Po2, H Pco2, L pH inhibitory H Po2, L Pco2, H pH Aortic body (peripheral chemoreceptor) excitatory L Po2, H Pco2, L pH inhibitory H Po2, L Pco2, H pH

  5. NEUROMODULATION • List goes on and on… • amino acids, neuropeptides, substance P, somatostatin, adenosine, prostaglandins….. • Effects are most pronounced in least mature infants • Inhibitory effects tend to predominate

  6. Maturation of Breathing • Fetal Breathing • well documented as early as 11 weeks • functions include • exercise • lung development • preparation • reflexes present (e.g. Hering-Breuer) • Sleep State • REM vs NREM

  7. CONTINUOUS BREATHING • Mechanism of transition to continuous breathing is not entirely clear • Not dependent on chemical stimuli • Not dependent on external stimuli • Once established, PO2 is important in maintaining it.

  8. POSTNATALMATURATION • Extensive development of synapses and increase in neuronal size • Increase in concentrations of neurotransmitters • Further dendritic elaboration continues for years

  9. DEFINITIONS

  10. APNEA • Cessation of respiratory airflow • Pathologic apnea is a respiratory pause > 20 seconds or of any duration if associated with cyanosis or significant desaturation, pallor, hypotonia, or bradycardia

  11. CENTRAL APNEA Apnea due to absent inspiratory effort (10-25% of all apnea)

  12. CENTRAL APNEA

  13. OBSTRUCTIVE APNEA Chest wall motion without air flow (12-20% of all apnea)

  14. MIXED APNEA Combination of central and obstructive (50-70% of all apnea in premature)

  15. PERIODIC BREATHING A breathing pattern in which there are > 3 respiratory pauses > 3 seconds in duration with < 20 seconds of respiration between pauses. This is not considered pathologic.

  16. Age (weeks) Term Infants Preterm Infants 0 - 4 0 - 3.5 % 0 - 5 % 4 - 8 0 - 2.5 % 0 - 3.5 % 8 - 20 0 - 1.5 % 0 - 2.5 % > 20 0 - 1.0 % 0 - 1.5 % PERIODIC BREATHING

  17. PERIODIC BREATHING

  18. APNEA OF PREMATURITY Pathologic apnea in a premature infant usually ceasing at > 37 weeks gestation • Premature infants (<34 weeks) have immature/inappropriate responses; e.g. apnea in the face of hypoxia. Phrenic neurons are more mature than upper airway neurons leading to persistence of obstructive apnea

  19. < 30 weeks GA 80%30 - 31 weeks GA 50%32 - 33 weeks GA 14%34 - 35 weeks GA 7%

  20. CNS Systemic Metabolic Thermal Anatomical IVH Sepsis Hypoglycemia Hyperthermia Choanal atresia Seizures Shock (hypovol.) Hyponatremia Hypothermia Micrognathia Hydrocephalus Heart failure Hypocalcemia Macroglossia Drug depression Acidosis Inborn errors Tracheomalacia Malformations

  21. APNEA OF INFANCY Unexplained episode of pathologic apnea with onset at > 37 weeks gestation

  22. ALTE An episode that is frightening to the observer and that is characterized by some combination of apnea, color change, marked change in muscle tone, choking or gagging, especially when CPR is required.

  23. Digestive (47%) Neurological (29%) Respiratory (15%) GER, aspiration Vasovagal response Infection (RSV, Pertussis) Infection Seizure disorder Airway abnormality Malformations Infection Alveolar hypoventilation Dumping Subdural hematoma Malformations Cardiovascular(3.5% Metabolic (2.5%) Miscellaneous (3%) Cardiomyopathy Hypoglycemia Accidents Infection Hypocalcemia Sepsis Arrythmia Food intolerance Munchausen by proxy CHD Inborn errors Drug effect

  24. ALVEOLAR HYPOVENTILATION SYNDROMES • Congenital • CHS, Arnold-Chiari II, Leigh Disease, Pyruvate Dehydrogenase def., Carnitine def., Mobius Syndrome • Acquired • CNS injury, infection, asphyxia, tumor, infarction • Transient • Obstructive Sleep Apnea Syndromes

  25. EVALUATION • History • GA; perinatal complications; drug exposure;concern for infection • Physical • complete, but concentrate on cardiorespiratory and neurologic • Laboratory/Radiology • sepsis; sugar; acidosis, hypoxia, hemorrhage

  26. MANAGEMENT • Acute management…….ABC’s • Further management depends on results of evaluation • Goals • prevent further severe episodes • reassure parents

  27. TREATMENT • Pharmacologic • methylxanthines • theophylline • caffeine • doxapram (continuous infusion) • CPAP (3-5cmH2O)

  28. METHYLXANTHINES • Proposed mechanisms of effect • increase minute ventilation • shift of CO2 response curve to left • efficiency of diaphragmatic contraction • improved pulmonary mechanics • decreased hypoxic ventilatory depression • Many potential complications (overdose)

  29. Management: In absence of any underlying problems, these are some helpful guidelinesa) Infants born at <35 weeks of GA (and not on ventilatory support) should be monitored for the first week of life, at least. b) Infants with less than 10 apneic episodes a day, without profound hypoxemia or bradycardia and with quick response to stimulation should be simply watched.c) Infants with several episodes during the day, with prolonged episodes associated with hypoxemia and/or bradycardia, with slow response to stimulation, requiring bag-and-mask ventilation to recover, should go through a trial of xanthines (caffeine, theophylline). d) Infants who fail on xanthines could be tried on CPAP. IV Doxapram infusion has been advocated by some, with variable success.e) Infants with refractory apnea and severe episodes should be considered for long term, low-setting mechanical ventilation

  30. HOMEMONITORING

  31. INDICATIONS • Persistent episodes of significant apnea/bradycardia when otherwise ready for discharge (5 day rule) • Sibling/Twin of SIDS • Technology-dependent infant

  32. REQUIREMENTS FOR HOME MONITORING • Parental understanding of plan • Parental/guardian knowledge of infant CPR • Knowledge of monitoring capabilities • Technical support • Documented monitoring • Physician follow-up

  33. PROBLEMS • False alarms • Monitor malfunction • Alternate caretaker difficulties • Skin irritation/breakdown • Sibling jealousy • Overdependence/difficulty weaning • Lack of compliance

  34. DISCONTINUATION • Depends on reason for monitoring • Most can be weaned within 2-3 months of discharge • No indication for monitoring of a normal child > 1 year of age.

  35. AAP RECOMMENDATIONS • Home cardiorespiratory monitoring should not be prescribed to prevent SIDS.

  36. Home cardiorespiratory monitoring may be warranted for premature infants who are at high risk of recurrent episodes of apnea, bradycardia, and hypoxemia after hospital discharge. The use of home cardiorespiratory monitoring in this population should be limited to approximately 43 weeks' postmenstrual age or after the cessation of extreme episodes, whichever comes last.

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