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Phrenic nerve injury; (3rd, 4th, 5th cervical nerves) with diaphragmatic paralysis must be considered when cyanosis and irregular and labored respirations.

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Presentation on theme: "Phrenic nerve injury; (3rd, 4th, 5th cervical nerves) with diaphragmatic paralysis must be considered when cyanosis and irregular and labored respirations."— Presentation transcript:

1 Phrenic nerve injury; (3rd, 4th, 5th cervical nerves) with diaphragmatic paralysis must be considered when cyanosis and irregular and labored respirations develop. Facial palsy; is usually a peripheral paralysis that results from pressure over the facial nerve in utero, or from forceps use during delivery.

2 Fractures: The clavicle is fractured during labor and delivery more frequently than any other bone; it is particularly vulnerable with difficult delivery of the shoulder in vertex presentations and the extended arms in breech deliveries. The infant characteristically does not move the arm freely (pseudoparalysis) on the affected side; crepitus and bony irregularity may be palpated, and discoloration. The Moro reflex is absent on the affected side. The prognosis is excellent. Treatment, if any, consists of immobilization of the arm and shoulder on the affected side.

3 A palpable callus develops at the site within a week and may be the initial evidence of the fracture. Fracture of the humerus or brachial palsy may also be responsible for limitation of movement of an arm and absence of a Moro reflex on the affected side. The Moro reflex is often absent from the involved extremity. Femur fracture is associated with shortening, limitation of active motion, painful passive motion, and external rotation.

4 Hypoxia-ischemia Anoxia; is the consequences of complete lack of oxygen. Hypoxia; decreased arterial concentration of oxygen. Ischemia; insufficient blood flow to cells or organs that to maintain their normal function. Asphyxia; inadequate tissue perfusion, which fails to meet the metabolic demands of the tissues for oxygen and waste removal.

5 Hypoxic-ischemic encephalopathy (HIE); Is an important cause of permanent damage to CNS tissues that may result in neonatal death or manifest later as cerebral palsy or developmental delay. Fifteen to 20% of infants with hypoxic-ischemic encephalopathy die in the neonatal period, and 25-30% of survivors are left with permanent neurodevelopmental abnormalities (cerebral palsy, mental retardation).

6 Etiology; A- Fetal hypoxia may be caused by various disorders in the mother, including; (1) Inadequate oxygenation of maternal blood from hypoventilation during anesthesia, cyanotic heart disease, respiratory failure (2) Low maternal blood pressure from acute blood loss

7 (3) Inadequate relaxation of the uterus to permit placental filling as in excessive oxytocin; (4) Premature separation of the placenta (5) Defected umbilical cord circulation as a result of compression or knotting of the cord (6) Placental insufficiency from toxemia or postmaturity.

8 B- After birth hypoxia: may be caused by; (1) Failure of oxygenation as a result of severe forms of cyanotic congenital heart disease or severe pulmonary disease (2) Anemia severe enough to lower the oxygen content of the blood (severe hemorrhage, hemolytic disease) (3) shock severe enough to interfere with the transport of oxygen to vital organs from overwhelming sepsis, massive blood loss, and intracranial or adrenal hemorrhage.

9 Pathophysiology; the injury typically correlates to areas of decreased cerebral blood flow. After hypoxia and ischemia, anaerobic metabolism occurs, which generates lactate and inorganic phosphates. Increased amounts of intracellular sodium and calcium may result in tissue swelling and cerebral edema. There is also increased production of free radicals and nitric oxide in these tissues.

10 The initial circulatory response of the fetus is increased shunting through the ductus arteriosus, and foramen ovale, with transient maintenance of perfusion of the brain, heart, and adrenals in preference to the lungs, liver, kidneys, and intestine. Congestion and petechiae in tissues develop.

11 Prolonged intrauterine hypoxia may result in periventricular leukomalacia(PVL). Pulmonary arterioles smooth muscle hyperplasia may develop, predisposes the infant to pulmonary hypertension. If fetal distress produces gasping, the amniotic fluid contents (meconium, squamous, lanugo) are aspirated into the trachea or lungs.

12 Term infants demonstrate neuronal necrosis of the cortex (later cortical atrophy) and parasagittal ischemic injury. Preterm infants demonstrate periventricular leukomalacia (PVL) (later spastic diplegia), status marmoratus of the basal ganglia, and intraventricular hemorrhage (IVH). So terms more often than preterm infants have focal or multifocal cortical infarcts that clinically manifest as focal seizures and hemiplegia.

13 Clinical manifestations;
Clinical manifestations; *Intrauterine; 1 Growth restriction and 2 Increased vascular resistance may be the 1st manifestation of fetal hypoxia.  *During labor; 1Continuous heart rate recording shows; variable or late deceleration pattern, fetal heart rate slows down, and beat-to-beat variability declines. 2Fetal scalp blood analysis may show a pH <7.20.

14 Action These signs should lead to the administration of high concentrations of 1apply oxygen to the mother and 2immediate delivery to avoid fetal death or CNS damage.

15 *At delivery; 1 the presence of yellow, meconium-stained amniotic fluid is evidence that fetal distress had occurred.   *After birth; these infants are 1 frequently depressed and fail to breathe spontaneously. During the ensuing hours, they 2 may remain hypotonic or change from hypotonic to hypertonic, or their tone may appear normal. 3 Pallor, cyanosis, apnea, a slow heart rate, and unresponsiveness to stimulation.

16 *Later; in next hours Cerebral edema may develop during the next 24 hr and result in profound brain stem depression. During this time, seizure activity may occur; it may be severe and refractory to the usual doses of anticonvulsants. In addition to CNS dysfunction, systemic hypoperfusion occurs in 80% of cases including;

17 Heart failure and cardiogenic shock, hypotension, persistent pulmonary hypertension, respiratory distress syndrome, gastrointestinal perforation, hematuria, and acute tubular or cortical necrosis, adrenal hemorrhage, inappropriate secretion of antidiuretic hormone, and metabolic derangements.

18 After delivery, hypoxia is due to respiratory failure and circulatory insufficiency. During the initial hours after an insult, infants have a depressed level of consciousness. Periodic breathing with apnea or bradycardia is present, but cranial nerve functions are often spared with positive intact papillary responses and spontaneous eye movement. Seizures are common with extensive injury. Hypotonia is also common as an early manifestation.

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20 Decrebrate positioning

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22 Diagnosis; *Diffusion-weighed MRI: is the preferred imaging modality because of its increased sensitivity and specifity. *CT scans: are helpful in identifying focal hemorrhage, diffuse cortical injury, and damage to the basal ganglia; CT has limited ability to identify cortical injury within the 1st few days of life.

23 *Amplitude integrated EEG (aEEG): has a good reliability & positive predictive value of 85% for infants who will have adverse neurodevelopmental outcome. *Ultrasound: has limited utility in evaluation of hypoxic injury in the term infant; it is preferred in evaluation of the preterm infant.

24 Treatment; *Phenobarbital is the drug of choice, is given with an intravenous loading dose (20 mg/kg); additional doses of 5-10 mg/kg (up to mg/kg total) may be needed. Phenytoin (20 mg/kg loading dose) or lorazepam (0.1 mg/kg) may be needed for refractory seizures. Phenobarbital levels should be monitored 24 hr after the loading dose and maintenance therapy (5mg/kg/24 hr) are begun.

25 Seizures in HIE may also be due to; hypocalcaemia, hypoglycemia, or infection. *Systemic or selective cerebral hypothermia for acute management of HIE is promising, as it decrease metabolism and suppress production of mediators known to be neurotoxic. *Others include; supportive care for organ dysfunction, careful ventilation, control of blood pressure, acid-base balance and of possible infection.

26 Cool-cap body hypothermia Cool-Blanket body hypothermia

27 Prognosis; depends on; 1
Prognosis; depends on; 1. Whether the metabolic & cardiopulmonary complication (hypoxia, hypoglycemia, shock) are treated 2. The infant's gestational age (outcome is poorest if the infant is preterm) 3. The severity of the encephalopathy. Severe encephalopathy is characterized by flaccid coma, apnea, and refractory seizures, and is associated with a poor prognosis.

28 *Low Apgar score at 20 min, absence of spontaneous respirations at 20 min of age, and persistence of abnormal neurological signs at 2 weeks of age also predict death or severe cognitive or motor deficit. *Normal MRI and EEG findings are associated with a good recovery, whereas severe MRI and EEG abnormalities predict poor outcome. *Microcephaly and poor head growth during the 1st year of life correlate with injury to the basal ganglia and white matter and adverse developmental outcome at 12 month.

29 THE PRINCIPLES OF NEONATAL RESUSCITATION;   Preparation for Resuscitation Immediate, effective resuscitation of the newborn infant can reduce or prevent morbidity and mortality and to establish adequate spontaneous respiration and cardiac output. Conditions requiring skilled resuscitation to be available at delivery are;

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31 Resuscitation equipment and drugs should always be readily available in resuscitation trolley, functional, and assembled for immediate use in the delivery room. 1. Radiant warmer with procedure table, stopwatch, light 2. Oxygen source (100%), pulse oximetry 3. neonatal resuscitation bag 4. Face mask(s) 5. A bulb syringe for suctioning with feeding tubes 6. Stethoscope

32 7. Transport incubator with battery-operated heat source and portable oxy­gen supply 8. Equipments for continuous monitoring of cardiopulmonary status. 9. Equipped emergency box containing; Laryngoscope, blades, batteries, endotracheal tubes, airways, Drugs(epinephrine, sodium bicarbonate, naloxone, albumin 5% and N/S), Umbilical catheterization tray, Syringes, needles, sutures, gloves, alcohol and tape.

33 Resuscitation equipments Resuscitation trolley

34 Immediate steps after birth in an infant in need of resuscitation; (1) Prevention of heat loss • Place the infant under a radiant heat source. • Dry the infant thoroughly and remove the wet linen. (2) Clearing the airway • Position the infant supine and flat with the neck slightly extended. • Suction the mouth then the nasopharynx to clear the airway. • Turn the head to the side to allow secretions to pool, and then remove with a bulb syringe or suction catheter.

35 Deep pharyngeal suction (in a child not requiring positive-pressure ventilation or intubation) should not be performed during the first few minutes after birth to avoid vagal depression and resultant bradycardia. (3) Initiation of breathing • Provide tactile stimulation by rubbing the back or gently slapping the feet Assess 3; heart rate, respiratory effort and color.

36 The steps of neonatal resuscitation following the standard ABCs of resuscitation: • A- Airway (Establish an airway, Positioning, Suctioning and Endotracheal intubation if necessary). • B- Breathing (Initiate breathing, tactile stimulation, Positive pressure ventilation). • C- Circulation (Maintain circulation, Chest compressions, Medications).


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