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European Consensus Guidelines on the Management of Neonatal Respiratory Distress Syndrome

European Consensus Guidelines on the Management of Neonatal Respiratory Distress Syndrome. Dr. Ezzedin A Gouta Consultant Paediatrician, BHNFT, UK Honorary Senior Lecturer, Sheffield University, UK RCPCH (UK) Director to the Middle East. Objectives.

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European Consensus Guidelines on the Management of Neonatal Respiratory Distress Syndrome

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  1. European Consensus Guidelines on the Management of Neonatal Respiratory Distress Syndrome Dr. Ezzedin A Gouta Consultant Paediatrician, BHNFT, UK Honorary Senior Lecturer, Sheffield University, UK RCPCH (UK) Director to the Middle East

  2. Objectives • Neonatal Respiratory Distress Syndrome (RDS) • Evidence based recommendations • The European Consensus Guidelines

  3. Respiratory distress syndrome (RDS) Difinition • Pulmonary insufficiency commences at or shortly after birth and increases in severity over the first 2 days of life. • If left untreated death can occur from progressive hypoxia and respiratory failure. • In survivors resolution begins between 2&4 days. • RDS is due to a lack of alveolar surfactant along with structural immaturity of the lung and it is mainly confined to preterm babies.

  4. Clinical Signs of RDS • Presents with early respiratory distress comprising cyanosis, grunting, retraction, and tachypnea. • Respiratory failure may develop and is indicated by blood gas analysis. • The diagnosis can be confirmed on chest X-ray with a classical ‘‘ground glass’’ appearance and air bronchograms.

  5. The Aim of Management of RDS • To provide interventions that will maximize the number of survivors whilst minimizing potential adverse effects. • Over the past 40 yrs many strategies & therapies for prevention & treatment of RDS have been developed & tested in clinical trials. • Controversies still exist.

  6. European Consensus Guidelines • This presentation reports the findings of a panel of experts from Europe who have developed consensus guidelines after critical examination of the most up-to-date evidence in early 2007. • The levels of evidence and grades of recommendation used are shown in Table on next slide.

  7. Grades of recommendation and levels of evidence.

  8. RDS Guidelines • Prenatal care • Delivery room stabilization • Surfactant therapy • Oxygen suppl. beyond stabilization • The role of CPAP in management of RDS • Mechanical ventilation strategies • Prophylactic treatment for sepsis • Supportive care

  9. Prenatal care Treatment for RDS should begin before birth • One Course of Steroids • Second Course of steroids • Antibiotics • Tocolytic drugs

  10. Antenatal Steroids • Betamethasone is the corticosteroid of choice to enhance fetal lung maturity because of an associated reduced risk of cystic periventricular leukomalacia when compared with dexamethasone • The optimal treatment to delivery interval is more than 24 h and <7 days after the start of steroid treatment.

  11. One Course of Prenatal Steroids • Single course does not appear to be associated with significant maternal or fetal adverse effects and should be offered to all women at risk of preterm delivery (< 35 weeks’ gestation) • There is significant reductions in rates of RDS, neonatal death, IVH & NE(A).

  12. Second Course of Prenatal Steroids • In animal studies-changes in brain myelination following repeated exposure to prenatal steroids • In a large cohort study a decrease in newborn OFC observed with increasing prenatal steroid exposure. • Although there may be a benefit in reducing RDS from giving a 2nd course no other clinically important benefits have been identified and no firm recommendation can be made (A).

  13. Antenatal Antibiotices • Use of antibiotics in preterm, pre-labor rupture of the membranes reduces the risk of preterm delivery (A) and accordingly reduce the risk of developing RDS. • Erythromycin 500 mg 6 hourly should be given to mothers with preterm pre-labor rupture of the membranes.

  14. Tocolytics • No clear evidence that use of tocolytics in preterm labour improve outcome. • Can be used in the short-term to delay birth to allow completion of a course of prenatal corticosteroids and/or in utero transfer to a perinatal center (A).

  15. Delivery Room Stabilization • Oxygen Concentration • CPAP • PPV • Intubation • Pulse oxymetry

  16. Oxygen Concentration • Pure oxygen (100%) is associated with increased mortality & may be harmful to preterm infants- ↓in cerebral blood flow and worse alveolar/arterial oxygen gradients in babies resuscitated with oxygen versus air. • The lowest concentration of oxygen possible should be used during resuscitation, provided there is an adequate HR response (>100/min)

  17. CPAP • Babies with surfactant deficiency have difficulty achieving adequate FRC and maintain alveolar aeration. • Start resuscitation with CPAP of at least 5–6 cm water via mask or nasal prongs to stabilize the airway and establish functional residual volume (D).

  18. Positive Pressure Ventilation (PPV) • Uncontrolled tidal volumes, either too large or too small, may also be detrimental to the immature lung • If PPV is needed for resuscitation, aim to avoid excessive tidal volumes by incorporating resuscitation devices which measure or limit the peak inspiratory pressure (D).

  19. Intubation • Intubation should be reserved for babies who have not responded to positive pressure ventilation by mask or those requiring surfactant therapy (D).

  20. Pulse Oxymetry • Provides useful information on heart rate & O2 Sat. during resuscitation. • Normal saturations during transition after birth may be between 50–80% . • Oximetry may identify babies outside this range and Pulse oximetry may be used to guide oxygen delivery during resuscitation, aiming to avoid hyperoxic peaks(D).

  21. Surfactant Therapy • Surfactant therapy has revolutionized neonatal respiratory care over the past two decades. • Use have been tested in multicenter RCT • It is clear that prophylactic or rescue surfactant therapy to babies with or at risk of developing RDS reduces risk of neonatal death and pneumothorax (A).

  22. Surfactant Dosing (1) • The earlier in the course of RDS that surfactant is given the greater the chance of avoiding ventilation. • Prophylaxis (within 15 min of birth) should be given to almost all babies <27 weeks’ gestation. • Prophylaxis should be considered for babies over 26 weeks but < 30 weeks’ gestation if intubation is needed in delivery suite or if the mother has not received prenatal steroids (A).

  23. Surfactant Dosing (2) • Early rescue surfactant should be given to untreated babies if there is evidence of RDS e.g. ↑ requirement for oxygen (A). • In babies who require surfactant, use of the ‘‘INSURE’’ technique (INtubate – SUrfactant – Extubate to CPAP) has been shown in RCT trials to reduce the need for mechanical ventilation. • For babies on CPAP a second dose should be given if they are determined to need mechanical ventilation (D).

  24. Surfactant Re-dosing • There are 2 approaches to repeat dosing- rigid and more flexible re-dosing. • A 2nd & sometimes a 3rd dose should be given if there is ongoing evidence of RDS e.g. persistent oxygen requirement and need for mechanical ventilation or if over 50% oxygen is needed on CPAP at 6 cm H2O as this reduces pneumothorax and probably also mortality (A).

  25. Surfactant Preparations (1) • There are several different types of surfactant preparation licensed for use in neonates with RDS including synthetic (protein-free) and natural (derived from animal lungs) surfactants • Natural surfactants should be used in preference to synthetic as they reduce pulmonary air leaks and mortality (A).

  26. After Surfactant Treatment • Where possible, duration of mechanical ventilation should be shortened by immediate (or early) extubation to CPAP following surfactant administration provided the baby is otherwise stable (B).

  27. Oxygen Supplementation Beyond Stabilization • In babies receiving oxygen, saturation should be maintained at all times below 95% as this may reduce ROP & BPD (D). • After giving surfactant, avoid a hyperoxic peak by rapid reduction in FiO2 as this is associated with grade I and II IVH (C). • Consider giving IM vitamin A as this reduces BPD although it requires thrice weekly IM injections for 4 weeks (A).

  28. The Role of CPAP in the Management of RDS (1) • The earlier CPAP is applied, the greater the chance of avoiding MV • CPAP should be initiated in all babies at risk of RDS, such as those < 30 weeks’ gestation who are not receiving mechanical ventilation, until their clinical status can be assessed (D).

  29. The role of CPAP in the Management of RDS (1) • The use of CPAP with early rescue surfactant should be considered in babies with RDS in order to reduce the need for mechanical ventilation (A). • Short binasal prongs should be used rather than a single prong (C) • A pressure of at least 6 cm water should be applied as this reduces the need for re-intubation in babies recently extubated (A).

  30. Mechanical Ventilation (MV) (1) • MV should be used to support babies with respiratory failure as this improves survival (A). • MV can be provided as IPPV or HFOV • Strategy & technique of MV are more important than mode of ventilation • HFOV may be useful as a rescue therapy in babies with respiratory failure on IPPV, ↓new pneumothorax but ↑ risks of IVH.

  31. Mechanical Ventilation (MV) (2) • All modes of MV can induce lung injury & should be avoided OR use is limited to the shortest possible duration provided there is a reasonable chance of successful extubation (D). • Avoid hypocapnia, is associated with increased risks of BPD and PVL (B). • Following extubation, babies should be put on nasal CPAP as this reduces the need for re-intubation (A).

  32. Prophylactic Treatment for Sepsis • Prematurity, amongst other risk factors, increases the likelihood that GBS is present • In preterm babies up to 30% of cases of early onset GBS sepsis will die and there is a high proportion of adverse neurological sequelae in survivors. • Symptoms of early onset GBS pneumonia closely mimic RDS.

  33. Prophylactic Treatment for Sepsis • Babies with RDS should routinely have blood cultures performed before starting treatment with intravenous penicillin or ampicillin (D) until sepsis has been excluded, usually by a negative blood culture after 48 h. • This may reduce death from early onset GBS although data to support this approach are not available from RCTs.

  34. Temperature Control • Premature infants continue to be at risk for hypothermia when treated according to current practice & this is associated with ↑mortality. • Babies <28 wks gestation use plastic bags or plastic wrapping in delivery room & transfer + radiant heat helps to maintain temp.

  35. Fluid Management (1) • Fluid & electrolyte should be tailored individually in preterm infants, allowing a 2.5–4% daily weight loss (15% total), rather than imposing a fixed daily progression (D). • Most babies should be started on IV fluids of 70–80 mL/kg/day while being kept in >80% ambient moisture in the incubator (D). • Sodium-should be restricted over the 1st few days of life; initiated after the onset of diuresis + monitor fluid balance & electrolytes (B).

  36. Nutritional Management (1) • Early nutrition is an important part of the overall care plan for babies with RDS. • Initially, enteral feeding might not be possible or desirable, so nutrients should be given as parenteral nutrition (PN). • Early introduction of protein, calories and lipids in PN improves survival (A). • Minimal enteral feeding should be started in stable babies with RDS as this will shorten duration of hospitalization (B).

  37. Maintenance of Blood Pressure (2) • Treatment is recommended when there is evidence of poor tissue perfusion (C). • USS assessment of systemic hemodynamics should be used when possible to determine the mechanisms responsible and guide treat. (D). • In the absence of USS, volume expansion with 10 mL/kg 0.9% saline used as 1st line treatment to exclude hypovolemia (D).

  38. Maintenance of Blood Pressure (3) • Dopamine rather than dobutamine should be used if volume expansion fails (B). • Dobutamine or epinephrine infusions may be used in addition, if maximum dose dopamine fails to improve blood pressure (D). • Hydrocortisone should be used in cases of refractory hypotension where conventional therapy has failed (B).

  39. Management of Persistent Ductus Arteriosus • Indomethacin prophylaxis reduces PDA and severe IVH but there is no evidence of differences in long term outcome, so firm recommendations cannot be made (A). • If a decision is made to attempt closure of the PDA then indomethacin or ibuprofen have been shown to be equally efficacious (B). Ibuprofen is associated with a lower rate of renal adverse effects

  40. Summary • Neonatal Respiratory Distress Syndrome (RDS) • Evidence based recommendations • The European Consensus Guidelines

  41. European Consensus Guidelines on Neonatal RDS Any Questions

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