Post on 28-Jan-2020
When Is the Premature Neonate Ready for Bypass?
Denise Suttner, MD
Professor of Pediatrics
Division of Neonatology
University of California at San Diego
Rady Children’s Hospital
Disclosure
• I have no relevant financial relationships with the manufacturer(s) of any commercial product(s) and/or provider(s) of commercial services discussed in this CME activity.
• I do not intend to discuss any unapproved or investigational use of a commercial product/device in my presentation
Prematurity and risk of CPB - main consideration:
• Faces a number challenges
• skin
• immune
• eye
• lungs
• intestine
• endocrine
• More concerns with lower GA
• **CNS and developmental outcome
Timing of CPB for the premature infant
Objectives:
Define neurologic outcomes for premature infants
Discuss the maturation dependent vulnerability of the premature brain
Review brain injury that is unique to premature patients
Identify risk factors associated with adverse neurodevelopmental outcome
Describe some aspects of cardiac critical care that likely affect the premature brain
Prematurity Definition
• Ext Preterm: 23-25wk
• Preterm: 251/7-316/7wk
• Moderately Preterm: 32-336/7wk
• Late preterm (LPT): 340/7-366/7wk
• Early Term (ET): 37-38wk
• Term: 39 0/7-406/7wk
75% of all preterm births
Neurodevelopmental outcomes premature (<28wks)
• Advances in care -> increased survival
• Major developmental delays are significant 10-30%
• cerebral palsy
• intelligence
• hearing loss
• visual important
• Cognitive/behavioral/attentional deficits in about 50%
More interest for PCICS - late preterm and early term ?
• Not just “small term babies’
• still in a critical developmental time period
• neurodevelopmental immaturity
• lower brain volume
• less differentiated patterns of myelination and neural connectivity
• In NICU:
• Realize that a fair number end up in NICU (without CHD)
Sahni, Clin Perinatol, 2013
More interest for PCICS - late preterm and early term ?
• Long term outcomes – adults born early:
• reading competence
• IQ
• behavioral assessment
• memory/attention
• increased utilization of special needs preschool services
• higher morbidities
• slower neurological development
• worse cognitive performance
• more school-related problems
• poorer academic achievements lower education and socioeconomic attainment as adults
• higher risk for cognitive impairments in late adulthood
Prachi Shah et al. Pediatrics 2016;138:e20153496
©2016 by American Academy of Pediatrics
Dueker, et al. Early Human Development, 2016
Brain Development and Injury
When Is the premature neonate ready for bypass?
• Problem: premature neonate may already starting with injury
• Avoid a CNS injury with permanent consequences
• Problem: CPB/cardiac ICU care - 2nd “hit”
Environmental insults: which ones matter?
• Important factors that likely have life-long consequences:
• timing in gestation
• severity
• nature
• Premature infant brain – uniquely at risk, negatively affected by
• hypoxia/ischemia
• inflammatory
• hemodynamic disturbance
Environmental insults: which ones matter?
• Downstream recognizable result
• IVH
• cerebellar hemorrhage/infarct
• hydrocephalus
• WMI **
• Early gestation: neurogenesis and neuronal migration – peak
• Injury
• death of neurons
• slowing neuronal migration
• gliosis
Rees, Early Human Development, 2005
• Complex
• 1. Vasculature
• Primitive – develops throughout gestation
• immature structure (IVH)
• less arterial anastomoses at arterial border zones
(hypoxia/ischemia)
• “pressure-passive” circulation (ischemia/IVH)
• 2. Immature and sensitive glia – Oligodendrocytes
Explanation for premature brain injury
Problem: impaired autoregulation
• IVH – multifactorial dz of prematurity
• Pressure/passive circulation important
• ischemia -> reperfusion or
• hyperemia from excessive ABP
• Autoregulation plays a role in IVH and important in
cardiac critical care
Rhee, J Perinatol, 2014
Problem: impaired autoregulation
Intraventricular hemorrhage
**WMI = PVL = +/- cortical or deep grey matter (cortex/hippocampus/cerebellum)
“Encephalopathy of prematurity”
Primarily 24-32 weeks
Late preterm/term
CHD
Problem: immature/sensitive glial cells
Khwaja, Arch Dis Child Fetal Neonatal, 2008
New pre-OL cells?fail to myelinate axonsarrested differentiation↑ risk for inflammatory mediated injury↓ cortical connections in gray matter
Pre – CPB summary
• Premature infants already at risk for poor neurodevelopmental outcome
• Efforts to optimize neurologic outcome must consider risks of CPB and necessary ICU care
Postnatal CPB/Cardiac ICU Care
Cardiac ICU– CPB
• Number of concerns
• SIRS
• cytokines
• free radicals
• Cerebral perfusion
• Impact CPB – unclear
• Premature infants with CHD worse outcomes
Maluf and Barbosa Evora, 2014
Cardiac ICU- procedures
• Preterm infants experience up to 14 painful procedures each day, median
101 during ICU stay (Drueden, 2016)
• Stress response and physiologic changes after procedures
• Altered response to repeated painful stimuli results in hypersensitivity
• Once we OK CPB – we are committing infant to more intervention
Cardiac ICU– infections
• Increased risk with decreasing gestation
• Premie + sepsis -> ↑rates of cerebral palsy and PVL
• Relationship to [cytokine] and poor outcome
Maluf and Barbosa Evora, 2014
Cardiac ICU - medication
• Morphine and Fentanyl cause apoptosis of developing CNS cells (Attarian, Brain Sci 2014)
• Population studies found association between adverse ND outcome even among “non-preterm” normal children who required anesthesia during early childhood
Cardiac ICU - medication
• Wilder RT, Anesthesiology 2009, Minnesota
• Retrospective birth cohort study
• Educational and medical records of all children, from 1976 to 1982
• 5,357 patients: 593 received general anesthesia < 4 yr
• Increased risk LD
• 1 exposure to anesthesia (n = 449) no association
• 2 exposures (n = 100) (hazard ratio = 1.59)
• > 3exposures (n = 44) (hazard ratio = 2.60)
• Commonly used anesthetic agents - NMDA and GABA-A
receptors
• Isoflurane
• Ketamine
• Midazolam
• Lorazepam
• Diazepam
• Pentobarbital
• Thiopental
• Propofol
Cardiac ICU– medication midazolam
• Duerden et al, ANN NEUROL 2016
• total midazolam dose predicted decreased hippocampal volumes
(p<0.001) and increased MD (p<0.02), whereas invasive procedures
did not (p>0.5 each).
• lower cognitive scores were associated with hippocampal growth
(p<0.003), midazolam dose (p<0.03), and surgery (p<0.04)
Conclusions
• Survival in premature infants increasing
• ND outcomes remain significant
• Question raised relevant
• What we know about CHD
• ND also concerning
• morbidity and mortality increased in premature infants
• increased WMI in infants with CHD
• Prematurity + CPB = added risk
Question – when is the premature infant ready for CPB?
• Wait – when possible
• Optimize medical treatment and palliative surgeries until term
• Lack neuroprotective strategies