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NEONATAL PULMOMARY DISORDERS

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NEONATAL PULMOMARY DISORDERS. RESPIRATORY DISTRESS SYNDROME. AKA Hyaline Membrane Disease ... Infants less than 37 wks gestation...the preemier the baby, the ... – PowerPoint PPT presentation

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Title: NEONATAL PULMOMARY DISORDERS


1
NEONATAL PULMOMARY DISORDERS
2
RESPIRATORY DISTRESS SYNDROME
  • AKA Hyaline Membrane Disease
  • Occurs more often in boysmore often in whites
    than non-whites
  • Associated with
  • Infants less than 37 wks gestationthe preemier
    the baby, the greater the risk
  • Infants of diabetic mothers
  • Multiple births
  • C-section prior to onset of labor
  • Cold stress
  • Siblings who had RDS

3
RDS - Etiology
  • A deficiency of surfactant and abnormal lung
    surface tensionscar tissue replaces alveolar
    tissue
  • Insufficient surfactant as well as immature cell
    and vascular development of the lungs
  • At about 16 wks gestation, alveolar type II cells
    synthesize and store surfactantincreasing
    amounts are produced as the fetus approaches term
  • Between weeks 28-38, surfactant is secreted into
    the alveoli and migrates into the amniotic fluid
    thru the trachea and esophagus
  • Primitive alveoli form between wks 27-35, with
    true alveoli forming between wks 30-36
  • Infants born before week 28 have structural
    underdevelopment of the terminal airspaces with
    little to no surfactant

4
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5
RDS-Etiology, cont
  • Surfactant deficiency along with the extremely
    compliant chest wall of the preterm infant
    results in an increase in surface forces and lung
    elastic recoil
  • This leads to atelectasis, decreased FRC,
    decreased C, increased Raw, and V/Q mismatch
    resulting in hypoxia, hypercarbia, and
    respiratory acidosis
  • The pulmonary arteries constrict, reducing blood
    flow and damaging the cells that line the alveoli
  • Immature surfactant is affected by hypoxemia,
    hypothermia, and acidosisall are common in
    preemies
  • Within 2 days of birth, immature lungs begin to
    mature while true alveoli and capillaries
    continue to develop in the lung
  • Chronic stress has a protective influence
    conditions such as maternal heroin use and
    toxemia are thought to induce surfactant
    productionpremature rupture of the membranes for
    gt24 hrs also has a protective effect

6
RDS Clinical Presentation
  • Infant is usually preterm
  • Tachypnea and labored breathing
  • Grunting attempting to maintain the FRC
  • Nasal flaring
  • Retractions high insp pressures distort the
    chest wall instead of inflating the stiff lungs
  • May be hypotonic and unresponsive
  • ABG is usually mixed acidosis with hypercarbia
    and hypoxemia

7
RDS on CXR
  • CXR shows diffuse, fine reticulogranular
    densities (ground glass)
  • Stage I fine diffuse reticulogranular pattern
  • Stage II more dense lung/air bronchograms w/i
    heart border
  • Stage III even more dense/air bronchograms all
    over
  • Stage IV white out

8
RDS Disease Progression
  • Mild cases peak in about 72 hours, then a gradual
    improvementfirst sign of improvement is
    spontaneous diuresis
  • Infants with severe RDS die in 2-7 days with
    death most often associated with PIE,
    pneumothorax, or IVH

9
RDS - Diagnosis
  • Based on history, clinical presentation, CXR, and
    lab values
  • LS Ratio Lecithin (dipalmitoylphosphatidyl
    choline) is the most abundant lipid found in
    surfactantwhen the lung is mature, there is
    twice as much lecithin as sphingomyelinan LS
    ratio of 21 is evidence of lung maturity and a
    low risk for RDS
  • PG level phosphatidylglycerol is the 2nd most
    abundant phospholipid in surfactant but isnt
    made until about week 35the presence of PG in
    amniotic fluid indicates a low risk for RDS
  • Foam test/Shake test amniotic fluid is mixed
    with alcohol and shakenif theres surfactant
    present, foam will appear that will last for
    several hoursif theres no surfactant, no foam
    appears or it will appear only briefly

10
RDS - Treatment
  • Prevention delay premature delivery as long as
    possible (terbutaline/albuterol) give
    glucocorticoids at least 2 days prior to delivery
    to accelerate lung development and promote
    surfactant secretion
  • Surfactant replacement can reduce the time on
    mechanical ventilation and pressure/oxygen
    requirements
  • CPAP/Mechanical Ventilation

11
RDS
  • Respiratory Management
  • Maintain adequate alveolar ventilation without
    causing lung damage
  • Use of pressure rather than volume ventilation
  • Maintain acceptable ABGs
  • Early intervention may reduce total support
    needed
  • Other
  • Adequate hydration, fluid balance, electrolytes
  • thermoregulation

12
RDS
  • Complications
  • IVH
  • More common in small babies
  • PPV is transmitted to the cranium causing vessel
    rupture
  • Barotrauma
  • Pneumothorax
  • subQ
  • DIC
  • Patient throws a bunch of clots that uses up the
    clotting factors
  • Result is a tendency to bleed profusely
  • PDA hypoxemia keeps the ductus open

13
Transient Tachypnea of the Newborn
  • AKA RDS Type II and wet lung syndrome
  • More common in males and in term infants,
    especially after C-section
  • Etiology thought to be due to delayed
    absorption of fetal lung fluid by the lymphatics
  • Results in decreased compliance, decreased tidal
    volume/increased rate, and increased dead space

14
TTNB Clinical Presentation
  • Usually has good Apgar scores
  • Tachypnea (60-160/min), cyanosis, grunting,
    flaring, and retractions begin within a few
    hourssymptoms are nearly identical to RDS
  • CXR shows pulm vascular congestion, prominent
    perihilar streaking, fluid in the interlobular
    fissures, hyperexpansion, and a flat diaphragm

15
TTNB - Diagnosis
  • Similar in presentation to RDS, group B
    streptococcal pneumonia, and PPHN
  • Usually diagnosed after these are ruled out
  • Usually resolves after about 24 hours of O2
    therapy
  • Evaluate for infection since sepsis and pneumonia
    present similarly

16
TTNB - Treatment
  • O2/CPAP supplemental oxygen usually only needed
    for about 24-48 hrs
  • Frequent position changes help prevent further
    retention of fluid
  • Bottle feedings are postponed until the tachypnea
    resolves to prevent aspiration

17
BPD
  • BPD bronchopulmonary dysplasia
  • Most cases follow treatment of RDS
    specifically, mechanical ventilation
  • Sort-of like baby COPD

18
BPD
  • Pathophysiology 4 factors lead to BPD
  • Oxygen toxicity
  • High FiO2 leads to edema and thickening of the
    alveolar-capillary membrane
  • Alveolar tissue hemorrhages and becomes necrotic
  • Interstitial spaces become fibrotic
  • Barotrauma from high pressures/long It
  • Presence of a PDA pulm congestion increases
    pressure/FiO2 requirements of ventilator
  • Fluid overload pulmonary edema
  • Studies show babies with BPD have antisurfactant
    protein A antibodies and decreased ability to
    secrete cortisol

19
BPD
  • Diagnosis
  • Chronic O2/Ventilator support
  • CXR
  • Stage 1 RDS ground glass
  • Stage 2 granular infiltrates
  • Stage 3 multiple small cysts
  • Stage 4 large, irregular cysts
  • ABG like a chronic lungers
  • EKG RAD with RVH
  • PFT increased Raw

20
BPD
  • Treatment
  • Prevention avoid high pressures/FiO2
  • Mechanical ventilation
  • Allow a small leak around ETT to avoid stenosis
  • Trach if more than 1 month or so on vent
  • High frequency ventilation
  • Adequate humidification have thick secretions
  • Resp Care Modalities
  • CPT
  • Sx
  • Bronchodilators probably not effective as not
    much bronchial smooth muscle present

21
BPD
  • Treatment, cont
  • Fluid
  • Use diuretics/fluid restriction to control pulm
    edema
  • Watch electrolyte balance
  • Right heart failure
  • Diuretics and digoxin
  • Chemically or surgically close the PDA
  • Nutrition
  • Have to meet metabolic needs as well as needs for
    growth
  • Inadequate nutrition delays growth and may make
    weaning more difficult
  • Too many calories, though, increases VO2 and VCO2
  • Vitamin E
  • Vitamin E deficiency increases incidence of O2
    toxicity
  • Administration of Vit E decreases lung injury
    from O2 toxicity
  • No conclusive evidence that Vit E decreases the
    incidence of BPD, though

22
ROP
  • Physiology
  • Capillaries of the retina begin forming at 16 wks
  • Capillaries start growing out from the optic
    nerve and grow towards the retina
  • They dont reach the retina until about 40 wks

23
ROP
  • Pathophysiology
  • Retinal vessels constrict with PaO2 is high
  • These vessels can then necrose
  • The ones that havent necrosed proliferate to try
    and establish a blood supply to the retina
  • The new vessels can extend too far and cause the
    retina to detach
  • Risk factors immaturity, hyperoxia, hypoxia,
    blood transfusions, IVH, apnea, infection,
    hypercarbia, PDA, vit E deficiency, lactic
    acidosis, prenatal complications, use of
    Indomethicin

24
ROP
  • Diagnosis
  • Opthalmic examination of the internal eye is
    required
  • Only takes 15-20 minutes of hyperoxia to start
    ROP
  • May take several weeks to progress through the
    stages
  • Not all babies progress to stage 5

25
ROP
  • Treatment
  • Prevention Keep PaO2 lt100
  • cryotherapy
  • This basically freezes the retina preventing
    abnormal blood vessel growth
  • Can scar and cause retinal detachment
  • Laser therapy
  • Lasers are used to coagulate the retina, again
    stopping abnormal vessel growth
  • Vitrectomy (removing vitreous part of eye) and
    lensectomy (removing the lens of the eye) are
    surgical treatments

26
INTRAVENTRICULAR HEMORRHAGE
  • AKA Intracranial hemorrhage
  • Intracranial bleeds are common in preemies and
    are also common in term babies with birth trauma
  • In term infants, the choroid plexus (hypothalamus
    area of the brain) is the most common site of
    bleed
  • In preemies, its the subependymal region, closer
    to the cerebellum
  • The inability to regulate blood flow is the usual
    cause

27
IVH
  • Blood flow fluctuates with shock, acidosis,
    hypernatremia, blood transfusions, seizures, and
    rapid infusions
  • Mechanical ventilation and Trendelenberg position
    increase ICP and can trigger hemorrhage
  • Babies of alcoholic mothers have a much higher
    incidence of IVH
  • See the list of risk factors on page 308

28
IVH
  • Signs/Symptoms
  • Apnea
  • Hypotension
  • Drop in hematocrit
  • Flaccidity
  • Bulging fontanelles
  • Tonic posturing
  • There are 4 grades of IVHthe bigger the number,
    the more extensive the bleed

29
IVH
  • Complications
  • Posthemorrhagic hydrocephalus
  • Caused by obstruction of CSF and impairment of
    CSF absorption
  • Use lumbar puncture to draw off CSF to keep ICP
    down
  • May have to place a ventricular-peritoneal shunt,
    which drains CSF into peritoneal cavity
  • Ventriculostomy is a catheter into the brain that
    can be used to drain CSF externally

30
IVH
  • Treatment
  • The best treatment is avoidance minimize the
    risk factors as much as possible
  • Besides shunts, osmotic agents that concentrate
    the blood can be used to draw the fluid from the
    cells back into the blood vessels

31
Asphyxia/Apnea
  • Asphyxia is a combination of hypoxia,
    hypercarbia, and acidosis in the fetus or
    neonatecan start as a lack of oxygen or can be
    from a drop in perfusion
  • Placental insufficiency in utero is most common
    cause of fetal asphyxia but any maternal or cord
    problem that interferes with gas exchange will
    lead to asphyxia (see table 10-4/pg 311)

32
Apnea of Prematurity
  • Cessation of breathing effort for gt20 seconds OR
    any pause long enough to cause bradycardia or
    cyanosis or both
  • Not to be confused with periodic breathing (short
    pauses followed by an increased RR)
  • The most common form of infant apnearelated to
    CNS immaturity/ dysfunction
  • Linked to thermal instability, metabolic
    disorders, PDA, shock, anemia, sepsis, and NEC

33
Apnea - Etiology
  • Primary apnea infant can be manually stimulated
    to start breathing again
  • Secondary apnea requires resuscitation to
    reestablish respirationlasts for more than 30
    seconds as is associated with desaturation,
    bradycardia, and hypotension

34
Asphyxia/Apnea
  • Consequences
  • Anoxic brain injury leading to necrosis of
    neurons and/or hemorrhage
  • Periventricular leukomalacia brain infarct
  • Other organ systems (heart, kidneys, GI tract)
    also suffer from ischemia
  • Can lead to DIC
  • In the lung, increases PVR and decreases
    surfactant production

35
Apnea - Treatment
  • Monitoring and treatment of ineffective
    respiration before it degenerates to apnea
  • Low FiO2 oxygen may reduce apnea episodes
  • Caffeine, theophylline, or doxapram can be used
    to stimulate respiration
  • Oscillating bed

36
Meconium Aspiration
  • Meconium is the green-tinged bowel content of an
    infant which is usually passed within 48 hours
    after delivery
  • Composed of swallowed amniotic fluid, salts,
    mucus, bile, cellular debris
  • If the infant passes meconium into the amniotic
    fluid in utero, it may cause airway obstruction,
    air trapping, and bacterial growth
  • Rarely occurs in infants lt36 weeks

37
Meconium - Etiology
  • Fetal passage of meconium occurs with
    intrauterine stress or hypoxia
  • Hypoxia causes a vagal response that relaxes the
    anal sphincter allowing meconium to pass into
    amniotic fluid
  • Normally, small amounts of amniotic fluid (up to
    5 ml) move into and out of the upper
    airwayshypoxia increases the risk of aspiration
    because of gasping respirations in
    uteroaspiration can also occur at birth
  • Can cause a ball-valve effect in the
    airwaysdilation during inspiration allows air
    past the meconium which then becomes trapped on
    expiration causing hyperinflation and
    predisposing to air leaks
  • The airways also become inflamed and secretion
    production increases
  • Meconium may also hinder surfactant leading to
    atelectasis

38
Meconium Clinical Presentation
  • Usually a term or post-term infant covered with
    meconium at birth
  • History may include prolonged labor, breech
    delivery, late decelerations
  • Signs of resp distress develop quickly
    cyanosis, gasping respirations, grunting,
    retractions, flaring, tachypneathe thicker the
    meconium the more severe the respiratory symptoms
  • AP chest diameter is often increased
  • Diagnosis is made at birth when the meconium is
    seen

39
Meconium - Treatment
  • To prevent aspiration into the lungs, pharyngeal
    suction should be performed when the head is
    delivered and before delivery of the thorax
    (before the first breath is taken)
  • After birth, use the ETT as a suction catheter
    b/c suction catheters are too small and become
    clogged
  • Surfactant replacement since meconium hinders
    surfactant
  • Liquid ventilation meconium can float to the
    top and be removed

40
Barotrauma
  • Pneumothorax
  • Most common type of barotrauma seen in babies
  • Signs/symptoms
  • Increased distress with retractions
  • Tachypnea
  • Bradycardia
  • Cyanosis
  • Hypotension
  • Apnea
  • Asymmetrical chest movement
  • Absent breath sounds on affected side

41
Pneumothorax
  • Diagnosis
  • CXR
  • Transillumination
  • Because skin is so thin, can place a light
    against the area of suspected pneumo and the
    light will spread out highlighting the pneumoyou
    get a uniform circle of light if theres no
    pneumo
  • Treatment
  • Chest tube/needle aspiration
  • If its small and not causing any problems, it
    may be left alone to spontaneously absorb

42
Other Barotraumas
  • Pneumomediastinum
  • Air is in the mediastinum
  • Can compress SVC and IVC and affect blood return
    to the heart
  • Pneumopericardium
  • Air in pericardial sac around the heart
  • Can cause a tamponade effect and drop CO
  • Needle aspiration

43
PIE
  • Pulmonary interstitial emphysema
  • Air is in the interstitial space around the
    alveoli
  • Associated with high PIP, PEEP, and long It
  • Can progress to pneumothorax/ mediastinum/pericard
    ium
  • Best treated by prevention use as low a PIP as
    possible
  • HFV has been used as well
  • Putting baby on 100 oxygen has been done to
    create a nitrogen gradient and reabsorb the air

44
Persistent Pulmonary Hypertension of the Newborn
  • Characterized by increased PVR and occurs most
    often in infants who are term or postterm
  • Associated with MAS, RDS, and birth asphyxia but
    can also be idiopathic
  • Persistent right-to-left shunts (PDA, FO)

45
PPHN - Etiology
  • At birth, when the umbilical cord is cut, the
    lungs make the transition to becoming the organ
    for gas exchange
  • PVR decreases because
  • PaO2 increases
  • pH increases
  • Air expands the lungs
  • Release of vasoactive substances, such as
    prostaglandins, bradykinin, and endothelium-
    derived relaxing factor
  • In infants with PPHN, the decrease in PVR either
    fails to occur or is reversed by pulmonary
    vascular hyperreactivity to irritating stimuli

46
PPHN Clinical Presentation
  • Cyanosis, tachypnea, and hypoxia appear in first
    12 hours of life with signs of respiratory
    distress
  • Hypocalcemia and hypoglycemia may develop rapidly

47
PPHN - Diagnosis
  • Hyperoxia test PO2 is evaluated on room air and
    then after 100 for 20 minlittle to no change
    indicates a R-to-L shunt which may be PPHN or
    congenital heart disease
  • Preductal-Postductal PO2 right radial PO2 is
    compared with umbilical or transcutaneous
    measurements from the upper chest are compared to
    the abdomenR-to-L shunt is present if theres
    gt20 mm Hg differencecan also occur with
    congenital heart defects
  • Hyperoxia-hyperventilation test infant is
    hyperventilated to a PCO2 of 25PPHN is present
    if PO2 increases gt100 mm Hg
  • Doppler/Cardiac Cath show the shunts through
    the ductus arteriosus and foramen ovale

48
PPHN - Treatment
  • Oxygen high FiO2 to vasodilate pulm vessels
  • Mech Vent hyperventilation to 25 mm Hg b/c resp
    alkalosis reduces PVR
  • Infusion of tolazoline to dilate pulm vessels and
    reduce PVR
  • NO reduces PVR
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