Inhaled Nitric Oxide (iNO) in Newborns - Dr Padmesh - Neonatology

Inhaled Nitric Oxide (iNO)
in newborns
Dr Padmesh V
DM Neonatology

At birth
Vascular endothelium
Vasoactive products
Cardiopulmonary transition at birth.
Pulmonary
endothelial
NO

cGMP, cyclic guanosine monophosphate ; GTP, Guanosine triphosphate.
Calcium
efflux

• iNO therapy causes:
– Potent,
– Selective,
– Sustained
Improved Oxygenation
Pulmonary
Vasodilatation

• ACTIONS OF iNO:
• Decreases extrapulmonary right-to-left shunting by
reducing PVR,
• Decreases intrapulmonary shunting by redirecting
blood from poorly aerated or diseased lung regions
to better aerated distal air spaces (“microselective
effect”).

• Potential Beneficial Effects of Low-Dose iNO in Hypoxemic
Respiratory Failure:
• 1. Pulmonary vasodilation → decreased extrapulmonary
right-to-left shunting
• 2. Enhanced matching of alveolar ventilation with perfusion
 decreased intrapulmonary shunting
• 3. ↓ Inflammation (↓ lung neutrophil accumulation)
• 4. ↓ Vascular leak and lung edema

• Potential Beneficial Effects of Low-Dose iNO in Hypoxemic
Respiratory Failure:
• 5. Preservation of surfactant function
• 6. ↓ Oxidant injury (inhibition of lipid oxidation)
• 7. Diagnostic value: failure to respond to iNO  Rule out
anatomic cardiovascular or pulmonary disease.

• Guidelines for Use of Inhaled Nitric Oxide
Therapy:
• Patient profile: >= 34 weeks gestational age.
• When:
– In the first week of life ,
– Echocardiographic evidence of extrapulmonary right-
to-left shunting ,
– OI greater than 25 ,
– After effective lung recruitment.
• Starting dose: 20 ppm

Therapy:
• Duration of treatment: Typically less than 5 days.
• Discontinuation:
• FiO2 < 60% and PaO2 > 60 ,
• Without evidence of
– Rebound pulmonary hypertension
– Increase in FiO2 >15% after iNO withdrawal.
• ECMO availability: If used in a non-ECMO center,
arrangements should be in place to continue iNO
during transport.

Therapy: Monitoring :
• Methemoglobinemia:
• NO + Hb  Nitrosyl Hb  Oxidized to Methemoglobin
• Monitor percentage methemoglobin by co-oximetry
within 4 hours of starting iNO and at 24-hour intervals.

• Methemoglobinemia:
• Methemoglobinemia occurs after exposure to high
concentrations of iNO (80 ppm).
• Not reported at lower doses of iNO (< 20 ppm). However,
because methemoglobin reductase deficiency may occur
unpredictably, monitoring should be done.
• Methemoglobin: Should not exceed 5% to 7%.

• Other toxicities:
Nitric oxide + oxygen
Nitrogen dioxide (NO2)
Nitric acid
Pulmonary edema
Death Upper limit for NO2 –> 3ppm over 8 hours
and 5ppm over 15 minutes.

• 4 Patterns of response to iNO:
• Pattern 1 : Non-responders
• Pattern 2: Responders: Initial response, but no
sustained response.
• Pattern 3: Responders: Initial response + sustained
response + successfully weaned within 5 days.
• Pattern 4: Responders: Initial response, but
sustained dependence on iNO for weeks together.
Pediatrics 1996;98;706-713

• Ventilator Management
• Effects of iNO may be suboptimal when lung
volume is decreased in association with pulmonary
parenchymal disease.
• Recruitment of alveoli important for iNO to work.

• Effects of combined therapy with HFOV & iNO in
term newborns with PPHN:
HFOV
iNO
HFOV
+iNO

• ROLE OF INHALED NITRIC OXIDE IN NEWBORNS
WITH CONGENITAL DIAPHRAGMATIC HERNIA
• No difference in the combined endpoint of death and/or
ECMO use between iNO-treated and control infants.
• Most infants with CDH have transient improvement in
oxygenation with iNO, but this response is not sustained.

• ROLE OF INHALED NITRIC OXIDE IN NEWBORNS
WITH CONGENITAL DIAPHRAGMATIC HERNIA
• iNO therapy should not be routinely used in patients with
CDH; rather, its use should be limited to patients with:
– Suprasystemic PVR
– After establishing optimal lung inflation and
– After demonstrating adequate LV performance
• However, there is clearly a role for iNO therapy in the
treatment of late pulmonary hypertension (PH) in
patients with CDH.

• THE PREMATURE NEWBORN:
• In preterm infants, iNO can be used for:
– Acute treatment of severe PPHN (as in term infants),
– Management of chronic PH in evolving or established
BPD, and
– For prevention of BPD.

• Effects of iNO in preterms may depend on:
– Timing,
– Dose, of therapy
– Duration,
– Nature of underlying disease.
• Low-dose iNO may be safe and effective in
reducing risk of death/BPD for infants with birth
weights >1000 g.
• Treatment between 7 and 14 days after birth
appears to be safe and effective in reducing BPD.

• A consensus conference by NICHD:
• Insufficient data to support use of iNO therapy for
the prevention of BPD.

• INNOVO trial:
• 108 premature infants with severe hypoxemic
respiratory failure were randomized to receive or
not receive iNO.
• Primary outcome: Death or severe disability at 1
year corrected age.
• No difference between the iNO and the control
group in the main outcome and no difference in
adverse events.

• NO CLD trial:
• Prolonged inhaled nitric oxide therapy that is
initiated between 7 and 21 days of age in preterm
infants undergoing mechanical ventilation
– significantly improved survival without
bronchopulmonary dysplasia
– without short-term adverse effects.
• However, no long term benefits demonstrated.

• Schreiber et al.
• 207 infants randomized to treatment with iNO or
placebo.
• Reduction in incidence of BPD and death by 24%
in iNO group.
• 47% decrease in the incidence of severe ICH and
periventricular leukomalacia (PVL)  improved
neurodevelopmental outcome on follow-up
examinations.

• Inhaled nitric oxide for respiratory failure in
preterm infants
• iNO does not appear to be effective as
rescue therapy for the very ill preterm infant.
• Early routine use of iNO in preterm infants with
respiratory disease does not prevent serious brain
injury or improve survival without BPD.
• Later use of iNO to prevent BPD could be effective,
but current 95% confidence intervals include no
effect; the effect size is likely small (RR 0.92) and
requires further study.

• Neonatal Inhaled Nitric Oxide Study (NINOS) trial:
(NICHD)
• 235 infants >34 weeks’ gestation with hypoxic
respiratory failure were randomized to:
–iNO 20-80 ppm with 91-96% FiO2 versus
–Standard ventilator management with 100%
oxygen.
• Primary end point was death or ECMO.

(NICHD)
• There was 40% reduction in need for ECMO among babies
treated with iNO.
• However, mortality rate was not different in either
treatment arm.
• Follow-up of survivors at 2 years showed no difference in
neurodevelopmental outcome between treated and control
patients.

(NICHD)
Initial dose in NINOS: 20 ppm
If improvement in PaO2< 20 torr.
Dose increased to 80 ppm
• Only 3 (6%) of 53 infants who had little response to 20 ppm
had an increase in PaO2 greater than 20 torr when treated
with 80 ppm iNO.
• At 80 ppm: Methemoglobinemia (> 7%) occurred 35% of
patients.

(NICHD):
• iNO in CDH
• Immediate short-term improvements in oxygenation seen
in some treated infants may be of benefit in stabilizing
responding infants for transport and initiation of ECMO.
• Conclusion: For term and near-term infants with CDH and
hypoxemic respiratory failure unresponsive to conventional
therapy, inhaled NO therapy did not reduce the need for
ECMO or death.

• Nitric oxide for respiratory failure in infants
born at or near term:
Inhaled nitric oxide is effective at an initial
concentration of 20 ppm for term and near-
term infants with hypoxic respiratory failure
who do not have a diaphragmatic hernia.

Inhaled Nitric Oxide (iNO) in Newborns - Dr Padmesh - Neonatology

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Inhaled Nitric Oxide (iNO) in Newborns - Dr Padmesh - Neonatology