M.Noori-Shadkam, MD-MPH Neonatologist
Cessation of airflow for at least 20 seconds or accompanied by bradycardia or cyanosis. Bradycardia and cyanosis are usually present after 20 sec. of apnea. After 30 to 45 sec., pallor and hypotonia are seen, and infant may be unresponsive to tactile stimulation.
V Vickers 2006 Apnea is Associated with Many Clinical Conditions: Intraventricular bleed May see hypoventilation, apnea or respiratory arrest Subtle seizures Along with fluttering eyelids, drooling or sucking, tonic posturing Sepsis l Bacterial (GBS, staph. Proteus, Listeria, Coliforms l Viral (RSV, paraflu, herpes, CMV l Chlamydial l NEC
V Vickers 2006 Congestive Heart Failure – PDA and CHD – Due to decreased lung compliance – Respiratory muscle fatigue – Chest wall distortion – Hypoxemia Respiratory Distress Syndrome l Due to atelectasis, work of breathing, fatigue l May lead to chronic lung disease Anemia l oxygen carrying capacity of blood l Arterial pressure perfusing CNS Polycythemia l blood viscosity and blood flow to CNS l begins at 2-4 hours of age
V Vickers 2006 High temperature of environment Feeding problems l overdistention of stomach l aspiration l GER (gastroesphogeal reflux) with or without aspirations due to laryngospasm stimulation of irritant receptors in lower esophagus causing ‘reflux apnea’ some reflux is common (laundry issue only?) Metabolic conditions l Hypoglycemia l Hypocalcemia l Hypernatremia l Alkalosis Others l Myelomeningocele l Meningitis
Causes CNS: (Abnormality,Encephalitis,Meningitidis,ICH,…) Upper & lower Air way: (choanal A.,congestion, RDS,pneumonia,…) Cardiovascular: (Malformation,hypotention,hypertention,…) Digestive system:(GER,NEC,Distention,…) Other:(Sepsis,Anemia,Hypothermia,Hypertherm ia,pain,metabolic disorder,…)
Recurrent sequences of pauses in respiration lasting for 5-10 seconds and followed by seconds of rapid respiration.
As many as 25% of all preterm infants who weigh <1800 g (34 Week) have at least one apneic episode. Essentially all infants <28 Week have apnea.
PREMATURITY Impaired Inhibitory Oxygenation Reflexes APNEA Infection CNS pathology Metabolic disorders Specific causes of apnea
Preterm infants respond to a fall in inspired oxygen with a transient hyperventilation followed by hypoventilation and sometimes apnea.
The Respiratory Pump The neonatal diaphragm The ribcage and chest wall muscles
The Neonatal Diaphragm In the relaxed state is located higher in the Thorax Inc. insp. pressure
Muscle fibers Type I: fast-oxidative, 20% fatigue resistant Type IIa: fast-oxidative, fatigue sensitive Type IIb: slow oxidative, fatigue resistant The Neonatal Diaphragm
Is attached to a more pliable chest wall Distortion Dec. tidal volume The Neonatal Diaphragm
The Newborn is Predisposed to Fatigue of Resp. Muscles Because of: The reduced number of fatigue resistant fibers in the diaphragm A pliable chest wall The rapid RR, which minimizes relaxation time for perfusion of the diaphragm The work of breathing associated with C L and C W
Consequences of Apnea Gas exchange is compromised due to: PA CO2, PAO2 Extrapulmonary shunting Muscle relaxation
Types of Neonatal Apnea 1.Central (diaphragmatic) 2.Peripheral (obstructive) 3.Mixed
All preterm infants below 35 WG must be monitored for at least the first week after birth. Monitoring should continue until no significant apneic episode has been detected for at least 5 days.
Because impedance apnea monitors may not distinguish respiratory efforts during airway obstruction from normal breaths, heart rate should be monitored in addition to, or instead of, respiration.
BP should be measured frequently and hypotension with oliguria< 2 mL/kg/h should be treated accordingly Hct should be> 45% ???
1.Prevent hyperflexion of the neck 2.Nurse the baby in prone position 3.Set the thermal environment to obtain a central temperature of ⁰ C 4.Minimize the duration and rate of pharyngeal suction cont’d
5. Place the orogastric tube carefully 6. Avoid sudden gastric distension 7. Continuous gastric feeding if apnea occurs with gavage 8. Warm air and oxygen to incubator temperature
Nursing Management During Apneic Episode 1.Check infant at once 2.Cancel alarm 3.Stimulate if there is no obvious vomit 4.Suction cont’d
Nursing Management During Apneic Episode 5. Give O2 via face mask in same concentration as infant had been receiving 6. Summon help if infant does not respond 7. Document and report 8. Intubation if indicated
Management of Idiopathic Apnea When apneic spells are repeated and prolonged, (i.e., more than 2 to 3 times/h.) or when they require frequent bag and mask ventilation, treatment should be initiated. cont’d
Management of Idiopathic Apnea Diagnosis and treatment of specific causes Nursing care Nasal CPAP (4-6 cm H2O) Methylxanthine therapy Increased environmental O2 only as necessary to maintain adequate baseline O2 saturation. Often associated with treatment of anemia Assisted ventilation if all else fails
Management of Idiopathic Apnea A.General measures 1. Diagnosis and treatment of specific causes 2. SO2 : 85-95% 3. Avoid reflexes that may trigger apnea. Suctioning of the pharynx should be done carefully, and oral feeding should be avoided. cont’d
Management of Idiopathic Apnea 4. Position of extreme flexion or extension of the neck should be avoided, to reduce the likelihood of airway obstruction. 5. Avoid swings in environmental temperature. cont’d
Management of Idiopathic Apnea 6. Consider a transfusions of PRBCs if the Hct is <25% and the infant has episodes of apnea and bradycardia that are frequent or severe while methylxanthine levels are therapeutic. cont’d
Management of Idiopathic Apnea B. Nasal CPAP (4-6 cm H2O) can reduce the number of mixed and obstructive apneic spells. C. Methylxanthine (caffeine of theophylline) therapy, commencing with a loading dose followed by maintenance therapy, and serum level monitoring, especially for theophylline. D. Assisted ventilation if all else fails
PaO2 with increased lung volume & C Work of breathing Splitting of the upper airways Elimination of the intercostal inspiratory- inhibitory reflex
Pharmacologic Mechanisms for Methylxanthine Competitive effect on adenosine receptors Sensitivity of respiratory center to CO2 Afferent nerve traffic to brain stem Catecholamine response Central stimulation (inspiratory drive) Improved skeletal muscle contraction Improved metabolic homeostasis Improved oxygenation via increased cardiac output and decreased hypoxic episodes
Signs of Toxicity in Infants Receiving Theophylline Failure to gain weight10-20 µg/mL Sleeplessness Irritability Tachycardia Hyperglycemia Vomiting20 µg/mL Diuresis/dehydration Jitteriness> 20 µg/mL Hyperreflexia Cardiac arrhythmias> 40 µg/mL Seizures