1. Oster ME, Lee KA, Honein MA, Et Al., Temporal Trends in Survival Among Infants With

References

1. Oster ME, Lee KA, Honein MA, et al., Temporal trends in survival among infants with

critical congenital heart defects. Pediatrics 2013;131: e1502–8.

2. Welke KF, Shen I, Ungerleider RM. Current assessment of mortality rates in

congenital cardiac surgery. Ann Thorac Surg 2006;82:164–70.

3. Bellinger DC, Newburger JW, Wypij D, et al. Behaviour at eight years in children with

surgically corrected transposition: The Boston Circulatory Arrest Trial. Cardiol Young

2009;19:86–97.

4. Marino BS, Lipkin PH, Newburger JW, et al. Neurodevelopmental outcomes in

children with congenital heart disease: evaluation and management: a scientific

statement from the American Heart Association. Circulation 2012;126:1143–72.

5. Bellinger DC, Wypij D, duPlessis AJ, et al. Neurodevelopmental status at eight years

in children with dextro-transposition of the great arteries: the Boston Circulatory

Arrest Trial. J Thorac Cardiovasc Surg 2003;126: 1385–96.

6. van Rijen EH, Utens EM, Roos-Hesselink JW, et al. Psychosocial functioning of the

adult with congenital heart disease: a 20–33 years follow-up. Eur Heart J

2003;24:673–83.

7. Andropoulos DB, Easley RB, Brady K, et al. Neurodevelopmental outcomes after

regional cerebral perfusion with neuromonitoring for neonatal aortic arch

reconstruction. Ann Thorac Surg 2013;95: 648–54.

8. Daliento L, Mapelli D, Volpe B. Measurement of cognitive outcome and quality of life

in congenital heart disease. Heart 2006;92:569–74. 9. Daliento L, Mapelli D, Russo G, et al. Health related quality of life in adults with

repaired tetralogy of Fallot: psychosocial and cognitive outcomes. Heart

2005;91:213–8.

10. Lane DA, Lip GY, Millane TA. Quality of life in adults with congenital heart disease.

Heart 2002;88:71–5.

11. Kovacs AH, Saidi AS, Kuhl EA, et al. Depression and anxiety in adult congenital heart

disease: predictors and prevalence. Int J Cardiol 2009;137:158–64.

12. Kovacs AH, Sears SF, Saidi AS. Biopsychosocial experiences of adults with congenital

heart disease: review of the literature. Am Heart J 2005;150: 193–201.

13. Kamphuis M, Vogels T, Ottenkamp J, et al. Employment in adults with congenital

heart disease. Arch Pediatr Adolesc Med 2002;156:1143–8.

14. Mahle WT, Tavani F, Zimmerman RA, et al. An MRI study of neurological injury

before and after congenital heart surgery. Circulation 2002;106: I109–14.

15. Andropoulos DB, Hunter JV, Nelson DP, et al. Brain immaturity is associated with

brain injury before and after neonatal cardiac surgery with high-flow bypass and

cerebral oxygenation monitoring. J Thorac Cardiovasc Surg 2010;139:543–56.

16. Andropoulos DB, Brady K, Easley RB, et al. Erythropoietin neuroprotection in

neonatal cardiac surgery: a phase I/II safety and efficacy trial. J Thorac Cardiovasc

Surg 2013;146:124–31.

17. Galli KK, Zimmerman RA, Jarvik GP, et al. Periventricular leukomalacia is common

after neonatal cardiac surgery. J Thorac Cardiovasc Surg 2004;127: 692–704.

18. Dent CL, Spaeth JP, Jones BV, et al. Brain magnetic resonance imaging abnormalities

after the Norwood procedure using regional cerebral perfusion. J Thorac Cardiovasc

Surg 2006;131:190–7. 19. Miller SP, McQuillen PS, Hamrick S, et al. Abnormal brain development in newborns

with congenital heart disease. N Engl J Med 2007;357:1928–38.

20. Beca J, Gunn JK, Coleman L, et al. New white matter brain injury after infant heart

surgery is associated with diagnostic group and the use of circulatory arrest.

Circulation 2013;127: 971–9.

21. Block AJ, McQuillen PS, Chau V, et al. Clinically silent preoperative brain injuries do

not worsen with surgery in neonates with congenital heart disease. J Thorac

Cardiovasc Surg2010;140: 550–7.

22. Woodward LJ, Anderson PJ, Austin NC, et al. Neonatal MRI to predict

neurodevelopmental outcomes in preterm infants. N Engl J Med 2006;355:685–94.

23. Miller SP, Ferriero DM, Leonard C, et al. Early brain injury in premature newborns

detected with magnetic resonance imaging is associated with adverse early

neurodevelopmental outcome. J Pediatr 2005;147:609–16.

24. Volpe JJ.Neurobiology of periventricular leukomalacia in the premature infant.

Pediatr Res 2001;50:553–62.

25. Buser JR, Segovia KN, Dean JM, et al. Timing of appearance of late oligodendrocyte

progenitors coincides with enhanced susceptibility of preterm rabbit cerebral white

matter to hypoxia-ischemia. J Cereb Blood Flow Metab 2010;30:1053–65.

26. Segovia KN, McClure M, Moravec M, et al. Arrested oligodendrocyte lineage

maturation in chronic perinatal white matter injury. Ann Neurol 2008;63: 520–30.

27. Greeley WJ, Ungerleider RM. Assessing the effect of cardiopulmonary bypass on the

brain. Ann Thorac Surg 1991;52:417–9. 28. Greeley WJ, Kern FH, Ungerleider RM, et al. The effect of hypothermic

cardiopulmonary bypass and total circulatory arrest on cerebral metabolism in

neonates, infants, and children. J Thorac Cardiovasc Surg 1991;101:783–94.

29. Greeley WJ, Ungerleider RM, Smith LR, Reves JG.T he effects of deep hypothermic

cardiopulmonary bypass and total circulatory arrest on cerebral blood flow in infants

and children. J Thorac Cardiovasc Surg 1989;97: 737–45.

30. Greeley WJ, Ungerleider RM, Kern FH, et al. Effects of cardiopulmonary bypass on

cerebral blood flow in neonates, infants, and children. Circulation 1989;80:I209–15.

31. Koehler RC, Roman RJ, Harder DR. Astrocytes and the regulation of cerebral blood

flow. Trends Neurosci 2009;32:160–9.

32. Fraser CD 3rd, Brady KM, Rhee CJ, et al. The frequency response of cerebral

autoregulation. J Appl Physiol 2013;115:52–6.

33. Taylor RH, Burrows FA, Bissonnette B. Cerebral pressure-flow velocity relationship

during hypothermic cardiopulmonary bypass in neonates and infants. Anesth Analg

1992;74:636–42.

34. Czosnyka M, Brady K, Reinhard M, et al. Monitoring of cerebrovascular

autoregulation: facts, myths, and missing links. Neurocrit Care 2009;10:373–86.

35. Gleason CA, Short BL, Jones MD Jr. Cerebral blood flow and metabolism during and

after prolonged hypocapnia in newborn lambs. J Pediatr 1989;115:309–14.

36. Muizelaar JP, van der Poel HG, Li ZC, et al. Pial arteriolar vessel diameter and CO2

reactivity during prolonged hyperventilation in the rabbit. J Neurosurg 1988;69:923–

7. 37. Laussen PC. Optimal blood gas management during deep hypothermic paediatric

cardiac surgery: alpha-stat is easy, but pH-stat may be preferable. Paediatr Anaesth

2002;12:199–204.

38. Hiramatsu T, Miura T, Forbess JM, et al. pH strategies and cerebral energetics before

and after circulatory arrest. J Thorac Cardiovasc Surg 1995;109:948–57.

39. Hirsch JC, Jacobs ML, Andropoulos D, et al. Protecting the infant brain during cardiac

surgery: a systematic review. Ann Thorac Surg 2012;94:1365–73.

40. Sakamoto T, Zurakowski D, Duebener LF, et al. Combination of alpha-stat strategy

and hemodilution exacerbates neurologic injury in a survival piglet model with deep

hypothermic circulatory arrest. Ann Thorac Surg 2002;73:180–9.

41. Wypij D, Jonas RA, Bellinger DC, et al. The effect of hematocrit during hypothermic

cardiopulmonary bypass in infant heart surgery: results from the combined Boston

hematocrit trials. J Thorac Cardiovasc Surg 2008;135:355–60.

42. Kurth CD, Steven JM. Keeping a cool head. Anesthesiology 2000;93: 598–600.

43. Bissonnette B, Holtby HM, Davis AJ, et al. Cerebral hyperthermia in children after

cardiopulmonary bypass. Anesthesiology, 2000;93:611–8.

44. Cottrell SM, Morris KP, Davies P, et al. Early postoperative body temperature and

developmental outcome after open heart surgery in infants. Ann Thorac Surg

2004;77: 66–71.

45. Kern FH, Jonas RA, Mayer JE Jr, et al. Temperature monitoring during CPB in infants:

does it predict efficient brain cooling? Ann Thorac Surg 1992;54:749–54.

46. Bellinger DC, Wernovsky G, Rappaport LA, et al. Cognitive development of children

following early repair of transposition of the great arteries using deep hypothermic

circulatory arrest. Pediatrics 1991;87:701–7. 47. Wong PC, Barlow CF, Hickey PR, et al. Factors associated with choreoathetosis after

cardiopulmonary bypass in children with congenital heart disease. Circulation

1992;86:II118–26.

48. Newburger JW, Jonas RA, Wernovsky G, et al. A comparison of the perioperative

neurologic effects of hypothermic circulatory arrest versus low-flow

cardiopulmonary bypass in infant heart surgery. N Engl J Med 1993;329:1057–64.

49. de Ferranti S, Gauvreau K, Hickey PR, et al. Intraoperative hyperglycemia during

infant cardiac surgery is not associated with adverse neurodevelopmental outcomes

at 1, 4, and 8 years. Anesthesiology2004;100:1345–52.

50. Ballweg JA, Wernovsky G, Ittenbach RF, et al. Hyperglycemia after infant cardiac

surgery does not adversely impact neurodevelopmental outcome. Ann Thorac Surg

2007;84: 2052–8.

51. Burrows FA, Bissonnette B. Cerebral blood flow velocity patterns during cardiac

surgery utilizing profound hypothermia with low-flow cardiopulmonary bypass or

circulatory arrest in neonates and infants. Can J Anaesth 1993;40:298–307.

52. Hillier SC, Burrows FA, Bissonnette B, Taylor RH. Cerebral hemodynamics in neonates

and infants undergoing cardiopulmonary bypass and profound hypothermic

circulatory arrest: assessment by transcranial Doppler sonography. Anesth Analg

1991;72:723–8.

53. Astudillo R, van der Linden J, Ekroth R, et al. Absent diastolic cerebral blood flow

velocity after circulatory arrest but not after low flow in infants. Ann Thorac Surg

1993;56:515–9. 54. Jonassen AE, Quaegebeur JM, Young WL. Cerebral blood flow velocity in pediatric

patients is reduced after cardiopulmonary bypass with profound hypothermia. J

Thorac Cardiovasc Surg 1995;110:934–43.

55. Tsui SS, Kirshbom PM, Davies MJ, et al. Nitric oxide production affects cerebral

perfusion and metabolism after deep hypothermic circulatory arrest. Ann Thorac

Surg 1996;61:1699–707.

56. Tsui SS, Kirshbom PM, Davies MJ, et al. Thromboxane A2-receptor blockade

improves cerebral protection for deep hypothermic circulatory arrest. Eur J

Cardiothorac Surg,1997;12:228–35.

57. S Skaryak LA, Kirshbom PM, DiBernardo LR, et al. Modified ultrafiltration improves

cerebral metabolic recovery after circulatory arrest. J Thorac Cardiovasc Surg

1995;109:744–51.

58. K Kirshbom PM, Skaryak LR, DiBernardo LR, et al. pH-stat cooling improves cerebral

metabolic recovery after circulatory arrest in a piglet model of aortopulmonary

collaterals. J Thorac Cardiovasc Surg 1996;111:147–55.

59. Rodriguez RA, Austin EH 3rd, Audenaert SM. Postbypass effects of delayed

rewarming on cerebral blood flow velocities in infants after total circulatory arrest. J

60. Fuller S, Rajagopalan R, Jarvik GP et al. J. Maxwell Chamberlain Memorial Paper for

congenital heart surgery. Deep hypothermic circulatory arrest does not impair

neurodevelopmental outcome in school-age children after infant cardiac surgery.

Ann Thorac Surg 2010;90:1985–94. 61. Bellinger DC, Rappaport LA, Wypij D, et al. Patterns of developmental dysfunction

after surgery during infancy to correct transposition of the great arteries. J Dev

Behav Pediatr 1997;18:75–83.

62. McGrath E, Wypij D, Rappaport LA, et al. Prediction of IQ and achievement at age 8

years from neurodevelopmental status at age 1 year in children with D-transposition

of the great arteries. Pediatrics, 2004;114:e572–6.

63. Bellinger DC, Wypij D, Rivkin MJ, et al. Adolescents with d-transposition of the great

arteries corrected with the arterial switch procedure: neuropsychological

assessment and structural brain imaging. Circulation 2011;124:1361–9.

64. Jonas RA, Wypij D, Roth SJ, et al. The influence of hemodilution on outcome after

hypothermic cardiopulmonary bypass: results of a randomized trial in infants. J

65. Visconti KJ, Rimmer D, Gauvreau K, et al. Regional low-flow perfusion versus

circulatory arrest in neonates: one-year neurodevelopmental outcome. Ann Thorac

Surg 2006;82:2207–11.

66. Goldberg CS, Bove EL, Devaney EJ, et al. A randomized clinical trial of regional

cerebral perfusion versus deep hypothermic circulatory arrest: outcomes for infants

with functional single ventricle. J Thorac Cardiovasc Surg 2007;133: 880–7.

67. Algra SO, Jansen NJ, van der Tweel I, et al. Neurological injury after neonatal cardiac

surgery: a randomized, controlled trial of 2 perfusion techniques. Circulation

2014;129:224–33.

68. Schwartz AE, Kaplon RJ, Young WL, et al. Cerebral blood flow during low-flow

hypothermic cardiopulmonary bypass in baboons. Anesthesiology 1994;81:959–64. 69. Schwartz AE, Kaplon RJ, Young WL, et al. Phenylephrine increases cerebral blood

flow during low-flow hypothermic cardiopulmonary bypass in baboons.

Anesthesiology, 1996;85:380–4.

70. Schwartz AE, Sandhu AA, Kaplon RJ, et al. Cerebral blood flow is determined by

arterial pressure and not cardiopulmonary bypass flow rate. Ann Thorac Surg

1995;60:165–9.

71. Harrington DK, Walker AS, Kaukuntla H, et al. Selective antegrade cerebral perfusion

attenuates brain metabolic deficit in aortic arch surgery: a prospective randomized

trial. Circulation 2004;110:II231–6.

72. Andropoulos DB, Stayer SA, McKenzie ED, Fraser CD Jr. Novel cerebral physiologic

monitoring to guide low-flow cerebral perfusion during neonatal aortic arch

reconstruction. J Thorac Cardiovasc Surg 2003;125:491–9.

73. DeCampli WM, Schears G, Myung R, et al. Tissue oxygen tension during regional low-

flow perfusion in neonates. J Thorac Cardiovasc Surg 2003;125:472–80.

74. Myung RJ, Petko M, Judkins AR, et al. Regional low-flow perfusion improves

neurologic outcome compared with deep hypothermic circulatory arrest in neonatal

piglets. J Thorac Cardiovasc Surg. 2004;127:1051–6.

75. Sasaki T, Tsuda S, Riemer RK, et al. Optimal flow rate for antegrade cerebral

perfusion. J Thorac Cardiovasc Surg 2010;139:530–76.

76. Andropoulos DB, Stayer SA, McKenzie ED, Fraser CD Jr. low-flow perfusion provides

comparable blood flow and oxygenation to both cerebral hemispheres during

neonatal aortic arch reconstruction. J Thorac Cardiovasc Surg 2003;126:1712–7. 77. Liu J, Ji B, Feng Z, et al. Application of modified perfusion technique on one stage

repair of interrupted aortic arch in infants: a case series and literature review. ASAIO

J 2007;53:666–9.

78. Oppido G, Pace Napoleone C, Turci S, et al. Moderately hypothermic

cardiopulmonary bypass and low-flow antegrade selective cerebral perfusion for

neonatal aortic arch surgery. Ann Thorac Surg2006;82:2233–9.

79. Lim C, Kim WH, Kim SC, et al. Aortic arch reconstruction using regional perfusion

without circulatory arrest. Eur J Cardiothorac Surg 2003;23:149–55.

80. Langley SM, Chai PJ, Miller SE, et al. Intermittent perfusion protects the brain during

deep hypothermic circulatory arrest. Ann Thorac Surg 1999;68:4–12.

81. Hickey E, Karamlou T, You X, et al. Hawley H. Seiler Resident Award paper. The use of a miniaturized circuit and bloodless prime to avoid cerebral no-reflow after neonatal cardiopulmonary bypass. Ann Thorac Surg. 2007;83:895–901.

82. Greeley WJ, Kern FH, Ungerleider RM, The effect of hypothermic cardiopulmonary

bypass and total circulatory arrest on cerebral metabolism in neonates, infants, and

children. J Thorac Cardiovasc Surg. 1991;101:783–94.

83. Kern FH, Ungerleider RM, Reves JG, et al. Effect of altering pump flow rate on

cerebral blood flow and metabolism in infants and children. Ann Thorac Surg

1993;56:1366–72.

84. Kern FH, Ungerleider RM, Quill TJ, et al. Cerebral blood flow response to changes in

arterial carbon dioxide tension during hypothermic cardiopulmonary bypass in

children. J Thorac Cardiovasc Surg 1991;101:618–22. 85. Bacon F. Of the proficience and advancement of learning divine and human. In:

Bacon F. The works of Francis Bacon (vol. I) Cambridge, UK: Hurd & Houghton, 1878,

p. 121 (original work published 1605).

86. Claridge JA, Fabian TC. History and development of evidence-based medicine. World

J Surg 2005;29:547–53.

87. Columb MO, Lalkhen AG. Systematic reviews & meta-analyses. Curr Anaesth Crit

Care, 2005;16:391–394.

88. American Socieity of Anesthesiologists. Standards for basic anesthetic monitoring.

July 1, 2011; available from: http://www.asahq.org/For-Members/Standards-

Guidelines-and-Statements.aspx (accessed March 28, 2014).

89. Pedersen T, Nicholson A, Hovhannisyan K, et al. Pulse oximetry for perioperative

monitoring. Cochrane Database Syst Rev. 2014 Mar 17;3:CD002013. [Epub ahead of

print]

90. Kasman N, Brady K. Cerebral oximetry for pediatric anesthesia: why do intelligent

clinicians disagree? Paediatr Anaesth 2011;21:473–8.

91. The Brain Trauma Foundation. The American Association of Neurological Surgeons.

The Joint Section on Neurotrauma and Critical Care. Indications for intracranial

pressure monitoring. J Neurotrauma 2000;17:479–91.

92. Austin EH 3rd, Edmonds HL Jr, Auden SM, et al. Benefit of neurophysiologic

monitoring for pediatric cardiac surgery. J Thorac Cardiovasc Surg1997;114:707–17.

93. Akiyama T, Kobayashi K, Nakahori T, et al. Electroencephalographic changes and

their regional differences during pediatric cardiovascular surgery with hypothermia.

Brain Dev 2001;23:115–21.

94. Bowdle TA. Depth of anesthesia monitoring. Anesthesiol Clin 2006;24:793–822. 95. Davidson AJ. Measuring anesthesia in children using the EEG. Paediatr Anaesth

2006;16:374–87.

96. Sigl JC, Chamoun NG. An introduction to bispectral analysis for the

electroencephalogram. J Clin Monit 1994;10:92–404.

97. Denman WT, Swanson EL, Rosow D, et al. Pediatric evaluation of the bispectral index

(BIS) monitor and correlation of BIS with end-tidal sevoflurane concentration in

infants and children. Anesth Analg 2000;90:872–7.

98. Goldmann L, Shah MV, Hebden MW. Memory of cardiac anaesthesia. Psychological

sequelae in cardiac patients of intra-operative suggestion and operating room

conversation. Anaesthesia 1987;42:596–603.

99. Dowd NP, Cheng DC, Karski JM, et al. Intraoperative awareness in fast-track cardiac

anesthesia. Anesthesiology 1998;89:1068–73.

100. Zabala L, Ahmed MI, Denman WT. Bispectral index in a 3-year old undergoing deep

hypothermia and circulatory arrest. Paediatr Anaesth 2003;13:355–9.

101. Mychaskiw G, Heath BJ, Eichhorn JH.Falsely elevated bispectral index during deep

hypothermic circulatory arrest. Br J Anaesth 2000;85:798–800.

102. Laussen PC, Murphy JA, Zurakowski D, et al. Bispectral index monitoring in children

undergoing mild hypothermic cardiopulmonary bypass. Paediatr Anaesth

2001;11:567–73.

103. Fischer AQ, Truemper EJ. Applications in the neonate and child. In: Bibikian VL,

Wechsler LR (eds) Transcranial Doppler Ultrasonography, 2nd edn. Oxford: England:

Butterworth-Heineman, 1993, pp. 355–75.

104. O'Brien JJ, Butterworth J, Hammon JW, et al. Cerebral emboli during cardiac surgery

in children. Anesthesiology 1997;87:1063–9. 105. Rodriguez RA, Cornel G, Splinter WM, et al. Cerebral vascular effects of aortovenous

cannulations for pediatric cardiopulmonary bypass. Ann Thorac Surg 2000;69:1229–

106. Sandström K, Nilsson K, Andréasson S, Larsson LE. Jugular bulb temperature

compared with non-invasive temperatures and cerebral arteriovenous oxygen

saturation differences during open heart surgery. Paediatr Anaesth 1999;9:123–8.

107. Yoshitake A, Goto T, Baba T, Shibata Y. Analysis of factors related to jugular venous

oxygen saturation during cardiopulmonary bypass. J Cardiothorac Vasc Anesth

1999;13:160–4.

108. Jobsis FF. Non-invasive, infra-red monitoring of cerebral O2 sufficiency, bloodvolume,

HbO2-Hb shifts and bloodflow. Acta Neurol Scand 1977;64:452–3.

109. Brazy JE, Lewis DV, Mitnick MH, Jöbsis vander Vliet FF. Noninvasive monitoring of

cerebral oxygenation in preterm infants: preliminary observations. Pediatrics

1985;75:217–25.

110. Watzman HM, Kurth CD, Montenegro LM, et al. Arterial and venous contributions to

near-infrared cerebral oximetry. Anesthesiology 2000;93: 947–53.

111. Yoxall CW, Weindling AM, Dawani NH, Peart I. Measurement of cerebral venous

oxyhemoglobin saturation in children by near-infrared spectroscopy and partial

jugular venous occlusion. Pediatr Res 1995;38:319–23.

112. Rais-Bahrami K, Rivera O, Short BL. Validation of a noninvasive neonatal optical

cerebral oximeter in veno-venous ECMO patients with a cephalad catheter. J

Perinatol,2006;26:628–35. 113. Abdul-Khaliq H, Troitzsch D, Schubert S, et al. Cerebral oxygen monitoring during

neonatal cardiopulmonary bypass and deep hypothermic circulatory arrest. Thorac

Cardiovasc Surg 2002;50:77–81.

114. Daubeney PE, Pilkington SN, Janke E, et al. Cerebral oxygenation measured by near-

infrared spectroscopy: comparison with jugular bulb oximetry. Ann Thorac Surg

1996;61:930–4.

115. Abdul-Khaliq H, Troitzsch D, Berger F, Lange PE. [Regional transcranial oximetry with

near infrared spectroscopy (NIRS) in comparison with measuring oxygen saturation

in the jugular bulb in infants and children for monitoring cerebral oxygenation].

Biomed Tech (Berl) 2000;45:328–32.

116. McQuillen PS, Barkovich AJ, Hamrick SE, et al. Temporal and anatomic risk profile of

brain injury with neonatal repair of congenital heart defects. Stroke 2007;38:36–41.

117. Phelps HM, Mahle WT, Kim D, et al. Postoperative cerebral oxygenation in

hypoplastic left heart syndrome after the Norwood procedure. Ann Thorac Surg

2009;87:1490–4.

118. Rivers EP, Coba V, Whitmill M.Whitmill, Early goal-directed therapy in severe sepsis

and septic shock: a contemporary review of the literature. Curr Opin Anaesthesiol

2008;21:128–40.

119. Tweddell JS, Ghanayem NS, Hoffman GM. Pro: NIRS is "standard of care" for

postoperative management. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu

2010;13:44–50. 120. Snookes SH, Gunn JK, Eldridge BJ, et al. A systematic review of motor and cognitive outcomes after early surgery for congenital heart disease. Pediatrics 2010;125:e818–27.

121. Tabbutt S, Gaynor JW, Newburger JW. Neurodevelopmental outcomes after congenital

heart surgery and strategies for improvement. Curr Opin Cardiol 2012;27:82–91.

122. Martinez-Biarge M, Jowett VC, Cowan FM, Wusthoff CJ. Neurodevelopmental outcome

in children with congenital heart disease. Semin Fetal Neonatal Med 2013;18:279–

123. Bellinger DC, Jonas RA, Rappaport LA, et al. Developmental and neurologic status of

children after heart surgery with hypothermic circulatory arrest or low-flow

cardiopulmonary bypass. N Engl J Med. 1995;332:549–55.

124. Rivkin MJ, Watson CG, Scoppettuolo LA, et al. Adolescents with D-transposition of the

great arteries repaired in early infancy demonstrate reduced white matter

microstructure associated with clinical risk factors. J Thorac Cardiovasc Surg

2013;146:543–9.

125. Gaynor JW, Gerdes M, Zackai EH, et al. Apolipoprotein E genotype and

neurodevelopmental sequelae of infant cardiac surgery. J Thorac Cardiovasc Surg

2003;126:1736–45.

126. Fuller S, Nord AS, Gerdes M, et al. Predictors of impaired neurodevelopmental

outcomes at one year of age after infant cardiac surgery. Eur J Cardiothorac Surg

2009;36:40–7.

127. Gaynor JW, Jarvik GP, Gerdes M, et al. Postoperative electroencephalographic seizures

are associated with deficits in executive function and social behaviors at 4 years of

age following cardiac surgery in infancy. J Thorac Cardiovasc Surg 2013

Jul;146(1):132–7. 128. Fuller S, Rajagopalan R, Jarvik GP, et al. J. Maxwell Chamberlain Memorial Paper for

congenital heart surgery. Deep hypothermic circulatory arrest does not impair

neurodevelopmental outcome in school-age children after infant cardiac surgery.

Ann Thorac Surg 2010;90:1985–94.

129. Goff DA, Luan X, Gerdes M, et al. Younger gestational age is associated with worse

neurodevelopmental outcomes after cardiac surgery in infancy. J Thorac Cardiovasc

Surg 2012;143:535–42.

130. Robertson CM, Joffe AR, Sauve RS, et al. Outcomes from an interprovincial program of

newborn open heart surgery. J Pediatr 2004;144:86–92.

131. Atallah J, Joffe AR, Robertson CM, et al. Two-year general and neurodevelopmental

outcome after neonatal complex cardiac surgery in patients with deletion 22q11.2: a

comparative study. J Thorac Cardiovasc Surg 2007;134:772–9.

132. Creighton DE, Robertson CM, Sauve RS, et al. Neurocognitive, functional, and health

outcomes at 5 years of age for children after complex cardiac surgery at 6 weeks of

age or younger. Pediatrics 2007;120:e478–86.

133. Guerra GG, Robertson CM, Alton GY, J et al. Neurodevelopmental outcome following

exposure to sedative and analgesic drugs for complex cardiac surgery in infancy.

Paediatr Anaesth 2011;21:932–41.

134. Guerra GG, Robertson CM, Alton GY, et al. Neurotoxicity of sedative and analgesia

drugs in young infants with congenital heart disease: 4-year follow-up.Paediatr

Anaesth 2014;24:257–65.

135. Hoffman GM, Brosig CL, Mussatto KA, et al. Perioperative cerebral oxygen saturation in

neonates with hypoplastic left heart syndrome and childhood neurodevelopmental

outcome. J Thorac Cardiovasc Surg 2013;146:1153–64. 136. Andropoulos DB, Easley RB, Brady K, et al. Changing expectations for neurological

outcomes after the neonatal arterial switch operation. Ann Thorac Surg

2012;94:1250–5.

137. Andropoulos DB, Ahmad HB, Haq T, et al. The association between brain injury,

perioperative anesthetic exposure, and 12-month neurodevelopmental outcomes

after neonatal cardiac surgery: a retrospective cohort study. Paediatr Anaesth

2014;24:266–74.

138. Newburger JW, Sleeper LA, Bellinger DC, et al. Early developmental outcome in

children with hypoplastic left heart syndrome and related anomalies: the single

ventricle reconstruction trial. Circulation 2012;125:2081–91.

139. Gaynor JW, Stopp C, Wypij D, et al. Early neurodevelopmental outcomes after cardiac

surgery in infancy have not improved: a multi-center retrospective analysis of 1718

patients. Circulation 2012;126:(21), Supplement: American Heart Association 2012

Annual Meeting Abstract #12437. (Abstract).

140. Ghoumari AM, Baulieu EE, Schumacher M. Progesterone increases oligodendroglial cell

proliferation in rat cerebellar slice cultures. Neuroscience 2005;135:47–58.

141. Baulieu EE, Schumacher. M. Progesterone as a neuroactive neurosteroid, with special

reference to the effect of progesterone on myelination. Human Reproduction

2000;15:1–13.

142. Andropoulos DB, Mizrahi EM, Hrachovy RA, et al. Electroencephalographic seizures

after neonatal cardiac surgery with high-flow cardiopulmonary bypass. Anesth Analg

2010;110:1680–5. 143. Fraser CD Jr, Andropoulos DB. Principles of antegrade cerebral perfusion during arch

reconstruction in newborns/infants. Semin Thorac Cardiovasc Surg Pediatr Card Surg

Annu 2008:61–8.

144. Kern FH, Greeley WJ, Ungerleider R. The effects of bypass on the developing brain. Perfusion 1993;8:49–54.

145. Pigula FA, Nemoto EM, Griffith BP, Siewers RD (2000) Regional low-flow perfusion provides cerebral circulatory support during neonatal aortic arch reconstruction. J Thorac Cardiovasc Surg 119:331–9.