Anesthetic Complications in the Neonate


Pro-apoptotic:

 • Isoflurane, sevoflurane, desflurane, N2O

 • Propofol, thiopental, ketamine, midazolam, diazepam, MgSO4, dexamethasone, CO2

Anti-apoptotic:

 • Lithium, melatonin, clonidine

Non-apoptotic:

 • Dexmedetomidine, opioids, ± xenon

Unknown:

 • Muscle relaxants



Obtaining definitive clinical data on such a complex subject with so many confounding variables is an involved and extremely difficult task. Retrospective studies designed to assess the effects of anesthesia on neurodevelopmental outcomes reveal a concern for anesthetic-induced neurocognitive or behavioral effects [175177]. These retrospective studies have major drawbacks, including but not limited to the difficulty in controlling for potential confounding variables including the lack of perioperative monitors, imprecise metrics, and measurement errors [175179]. In contrast to these studies, a monozygotic concordant-discordant twin design failed to demonstrate a causal relationship between anesthesia and cognitive performance [180]. This study did not directly assess for learning disabilities, did not examine the effects of multiple anesthetics, nor did they disclose any details about the anesthetics that were administered. The authors of the study stated that children who are sick often have learning disabilities related to their underlying illness and require surgery and anesthesia due to that illness [180, 181]. A retrospective review of children whose mothers underwent obstetrical anesthesia did not reveal a detrimental effect of general anesthesia 5 years after exposure [182]. A retrospective Dutch cohort study in adolescent children who underwent inguinal hernia repair as infants compared a randomly selected, age-matched population and found no differences in their ninth grade academic scores [183]. At present, any suggestion of a causal relationship between early exposure to anesthetics and subsequent impaired cognition or psychomotor performance remains unproven and tenuous.

Two promising clinical studies may shed light on the clinical implications of anesthetics on neurodevelopment: first, a prospective randomized, multicenter trial and, second, a retrospective cohort study. The first study, the General Anesthesia Study (GAS), is a multisite, multinational, randomized, controlled study that was initiated to compare the long-term neurodevelopmental outcomes in infants who received general or regional anesthesia for hernia surgery [155, 184]. This trial is expected to be completed by 2016. The second study is the multisite Pediatric Anesthesia NeuroDevelopmental Assessment (PANDA) [185]. PANDA is a mixed epidemiologic design that retrospectively examines a cohort that underwent a single anesthetic before the age of 3 years compared with developmentally age-matched siblings without anesthetic exposure. Both groups will then undergo a prospective, direct assessment of global and specific neurodevelopmental endpoints as they mature.

The FDA, understanding that the investigation of anesthetic neurotoxicity is an overwhelming task requiring public and private intellectual and financial collaboration, has formed a public-private partnership with the acronym SAFEKIDS (Safety of Key Inhaled and IV Drugs in Pediatrics) [186]. SAFEKIDS evolved into SmartTots (Strategies for Mitigating Anesthesia Related neuroToxicity in Tots) in 2010 [187]. SmartTots (http://​www.​smarttots.​org) is a “multi-year project designed to address major gaps in scientific information about the safe use of anesthetics and sedatives received by millions of children each year” [188]. The GAS and PANDA studies are now partnered with SmartTots.

If future clinical studies do reveal a risk of anesthetic-induced neuronal toxicity, how will this be balanced with the competing detrimental effects of untreated pain and stress? Unfortunately, the answers are neither forthcoming nor unambiguous, and it may be another generation before the complex interactions are completely understood. Regional anesthesia may play an important role by reducing the systemic administration of potential neurotoxic pharmacologic agents. Given the positive outcomes associated with early surgical intervention [158], surgery and thus anesthesia should not be postponed if clinically indicated. Practitioners must continue to focus on minimizing morbidity and mortality as our specialty awaits clarification of the actual risks associated with early anesthetic exposure in humans.



Conclusion


The incidence of perioperative morbidity and mortality is greatest in neonates and decreases thereafter with increasing age to adults. It is not surprising that neonates hold this position as they often present for emergency surgery with complicated multiorgan disease (respiratory and neurologic diseases), sepsis, and congenital heart disease. These coexisting disorders increase the perioperative risk. The complex environment and dynamics of an operating room combined with the vulnerabilities of a high-risk population converge to increase the likelihood of adverse events occurring. The ultimate goal in developing a successful anesthetic prescription is to prevent adverse events although a more realistic and achievable goal is to pursue strategies that decrease the number of adverse events and minimize their clinical consequences should they occur. Since perianesthetic systems require human interaction and decision-making, human errors are bound to occur. Continued improvements in perioperative and perianesthetic systems are essential to improve resiliency and decrease all types of errors. Through ongoing data collection and analysis using globally agreed-upon terms and definitions, continued education, innovative strategies, further standardization, and ever persistent diligence in the perianesthetic period, continued and significant improvement in safety and outcomes will be realized for our smallest and most vulnerable patient population, the neonate.


References



1.

Beecher HK, Todd DP. A study of the deaths associated with anesthesia and surgery: based on a study of 599, 548 anesthesias in ten institutions 1948-1952, inclusive. Ann Surg. 1954;140:2–35.PubMedCentralPubMed


2.

Phillips OC, Frazier TM, Graff TD, Dekornfeld TJ. The Baltimore anesthesia study committee. Review of 1,024 postoperative deaths. JAMA. 1960;174:2015–9.PubMed


3.

Rackow H, Salanitre E, Green LT. Frequency of cardiac arrest associated with anesthesia in infants and children. Pediatrics. 1961;28:697–704.PubMed


4.

Smith RM. Anesthesia for infants and children. St. Louis: Mosby; 1959.


5.

Graff TD, Phillips OC, Benson DW, Kelley E. Baltimore anesthesia study committee: factors in pediatric anesthesia mortality. Anesth Analg. 1964;43:407–14.PubMed


6.

van der Griend BF, Lister NA, McKenzie IM, et al. Postoperative mortality in children after 101,885 anesthetics at a tertiary pediatric hospital. Anesth Analg. 2011;112(6):1440.PubMed


7.

Bhananker SM, Ramamoorthy C, Geiduschek JM, et al. Anesthesia-related cardiac arrest in children: update from the pediatric perioperative cardiac arrest registry. Anesth Analg. 2007;105:344–50.PubMed


8.

Bunchungmongkol N, Somboonviboon W, Suraseranivongse S, Vasinanukorn M, Chau-in W, Hintong T. Pediatric anesthesia adverse events: the Thai Anesthesia Incidents Study (THAI Study) database of 25,098 cases. J Med Assoc Thai. 2007;90:2072–9.PubMed


9.

Cohen MM, Cameron CB, Duncan PG. Pediatric anesthesia morbidity and mortality in the perioperative period. Anesth Analg. 1990;70:160–7.PubMed


10.

Flick RP, Sprung J, Harrison TE, et al. Perioperative cardiac arrests in children between 1988 and 2005 at a tertiary referral center: a study of 92,881 patients. Anesthesiology. 2007;106:226–37. quiz 413-4.PubMed


11.

Jimenez N, Posner KL, Cheney FW, Caplan RA, Lee LA, Domino KB. An update on pediatric anesthesia liability: a closed claims analysis. Anesth Analg. 2007;104:147–53.PubMed


12.

Kakavouli A, Li G, Carson MP, et al. Intraoperative reported adverse events in children. Paediatr Anaesth. 2009;19:732–9.PubMedCentralPubMed


13.

Kawashima Y, Seo N, Morita K, et al. Anesthesia-related mortality and morbidity in Japan (1999). J Anesth. 2002;16:319–31.PubMed


14.

Keenan RL, Shapiro JH, Kane FR, Simpson PM. Bradycardia during anesthesia in infants. An epidemiologic study. Anesthesiology. 1994;80:976–82.PubMed


15.

Marcus R. Human factors in pediatric anesthesia incidents. Paediatr Anaesth. 2006;16:242–50.PubMed


16.

Morita K, Kawashima Y, Irita K. Perioperative mortality and morbidity in 1999 with a special reference to age in 466 certified training hospitals of Japanese Society of Anesthesiologists–report of Committee on Operating Room Safety of Japanese Society of Anesthesiologists. Masui. 2001;50:909–21.PubMed


17.

Morray JP, Geiduschek JM, Caplan RA, Posner KL, Gild WM, Cheney FW. A comparison of pediatric and adult anesthesia closed malpractice claims. Anesthesiology. 1993;78:461–7.PubMed


18.

Morray JP, Geiduschek JM, Ramamoorthy C, et al. Anesthesia-related cardiac arrest in children: initial findings of the pediatric perioperative cardiac arrest (POCA) registry. Anesthesiology. 2000;93:6–14.PubMed


19.

Murat I, Constant I, Maud’huy H. Perioperative anaesthetic morbidity in children: a database of 24,165 anaesthetics over a 30-month period. Paediatr Anaesth. 2004;14:158–66.PubMed


20.

Olsson GL, Hallen B. Laryngospasm during anaesthesia. A computer-aided incidence study in 136,929 patients. Acta Anaesthesiol Scand. 1984;28:567–75.PubMed


21.

Olsson GL, Hallen B. Cardiac arrest during anaesthesia. A computer-aided study in 250,543 anaesthetics. Acta Anaesthesiol Scand. 1988;32:653–64.PubMed


22.

Tay CL, Tan GM, Ng SB. Critical incidents in paediatric anaesthesia: an audit of 10 000 anaesthetics in Singapore. Paediatr Anaesth. 2001;11:711–8.PubMed


23.

Tiret L, Nivoche Y, Hatton F, Desmonts JM, Vourc’h G. Complications related to anaesthesia in infants and children. A prospective survey of 40240 anaesthetics. Br J Anaesth. 1988;61:263–9.PubMed


24.

Van der Walt JH, Sweeney DB, Runciman WB, Webb RK. The Australian Incident Monitoring Study. Paediatric incidents in anaesthesia: an analysis of 2000 incident reports. Anaesth Intensive Care. 1993;21:655–8.PubMed


25.

Leape LL. Error in medicine. JAMA. 1994;272:1851–7.PubMed


26.

Smith AF, Goodwin D, Mort M, Pope C. Adverse events in anaesthetic practice: qualitative study of definition, discussion and reporting. Br J Anaesth. 2006;96:715–21.PubMed


27.

Stanhope N, Crowley-Murphy M, Vincent C, O’Connor AM, Taylor-Adams SE. An evaluation of adverse incident reporting. J Eval Clin Pract. 1999;5:5–12.PubMed


28.

Taylor JA, Brownstein D, Christakis DA, et al. Use of incident reports by physicians and nurses to document medical errors in pediatric patients. Pediatrics. 2004;114:729–35.PubMed


29.

Derrington MC, Smith G. A review of studies of anaesthetic risk, morbidity and mortality. Br J Anaesth. 1987;59:815–33.PubMed


30.

Odegard KC, DiNardo JA, Kussman BD, et al. The frequency of anesthesia-related cardiac arrests in patients with congenital heart disease undergoing cardiac surgery. Anesth Analg. 2007;105:335–43.PubMed


31.

Ramamoorthy C, Haberkern CM, Bhananker SM, et al. Anesthesia-related cardiac arrest in children with heart disease: data from the pediatric perioperative cardiac arrest (POCA) registry. Anesth Analg. 2010;110:1376–82.PubMed


32.

Hansen G, Joffe AR, Nettel-Aguirre A, et al. Two-year survival and neurodevelopmental outcomes after cardiopulmonary resuscitation in neonatal patients after complex cardiac surgery. Resuscitation. 2011;82:313–8.PubMed


33.

Meaney PA, Nadkarni VM, Cook EF, et al. Higher survival rates among younger patients after pediatric intensive care unit cardiac arrests. Pediatrics. 2006;118:2424–33.PubMed


34.

Paterson N, Waterhouse P. Risk in pediatric anesthesia. Paediatr Anaesth. 2011;21:848–57.PubMed


35.

Fenner A, Schalk U, Hoenicke H, Wendenburg A, Roehling T. Periodic breathing in premature and neonatal babies: incidence, breathing pattern, respiratory gas tensions, response to changes in the composition of ambient air. Pediatr Res. 1973;7:174–83.PubMed


36.

Kelly DH, Stellwagen LM, Kaitz E, Shannon DC. Apnea and periodic breathing in normal full-term infants during the first twelve months. Pediatr Pulmonol. 1985;1:215–9.PubMed


37.

Hoppenbrouwers T, Hodgman JE, Harper RM, Hofmann E, Sterman MB, McGinty DJ. Polygraphic studies of normal infants during the first six months of life: III. Incidence of apnea and periodic breathing. Pediatrics. 1977;60:418–25.PubMed


38.

Kurth CD, LeBard SE. Association of postoperative apnea, airway obstruction, and hypoxemia in former premature infants. Anesthesiology. 1991;75:22–6.PubMed


39.

Steward DJ. Preterm infants are more prone to complications following minor surgery than are term infants. Anesthesiology. 1982;56:304–6.PubMed


40.

Cote CJ, Zaslavsky A, Downes JJ, et al. Postoperative apnea in former preterm infants after inguinal herniorrhaphy. A combined analysis. Anesthesiology. 1995;82:809–22.PubMed


41.

Fisher DM. When is the ex-premature infant no longer at risk for apnea? Anesthesiology. 1995;82:807–8.PubMed


42.

Craven PD, Badawi N, Henderson-Smart DJ, O’Brien M. Regional (spinal, epidural, caudal) versus general anaesthesia in preterm infants undergoing inguinal herniorrhaphy in early infancy. Cochrane Database Syst Rev 2003:CD003669.


43.

Gerber AC, Weiss M. Awake spinal or caudal anaesthesia in preterms for herniotomies: what is the evidence based benefit compared with general anaesthesia? Curr Opin Anaesthesiol. 2003;16:315–20.PubMed


44.

Frumiento C, Abajian JC, Vane DW. Spinal anesthesia for preterm infants undergoing inguinal hernia repair. Arch Surg. 2000;135:445–51.PubMed


45.

Kunst G, Linderkamp O, Holle R, Motsch J, Martin E. The proportion of high risk preterm infants with postoperative apnea and bradycardia is the same after general and spinal anesthesia. Can J Anaesth. 1999;46:94–5.PubMed


46.

Krane EJ, Haberkern CM, Jacobson LE. Postoperative apnea, bradycardia, and oxygen desaturation in formerly premature infants: prospective comparison of spinal and general anesthesia. Anesth Analg. 1995;80:7–13.PubMed


47.

Davidson A, Frawley GP, Sheppard S, Hunt R, Hardy P. Risk factors for apnea after infant inguinal hernia repair. Paediatr Anaesth. 2009;19:402–3.PubMed


48.

Kim J, Thornton J, Eipe N. Spinal anesthesia for the premature infant: is this really the answer to avoiding postoperative apnea? Paediatr Anaesth. 2009;19:56–8.PubMed


49.

O’Brien K, Robinson DN, Morton NS. Induction and emergence in infants less than 60 weeks post-conceptual age: comparison of thiopental, halothane, sevoflurane and desflurane. Br J Anaesth. 1998;80:456–9.PubMed


50.

Sale SM, Read JA, Stoddart PA, Wolf AR. Prospective comparison of sevoflurane and desflurane in formerly premature infants undergoing inguinal herniotomy. Br J Anaesth. 2006;96:774–8.PubMed


51.

Murphy JJ, Swanson T, Ansermino M, Milner R. The frequency of apneas in premature infants after inguinal hernia repair: do they need overnight monitoring in the intensive care unit? J Pediatr Surg. 2008;43:865–8.PubMed

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Sep 21, 2016 | Posted by in ANESTHESIA | Comments Off on Anesthetic Complications in the Neonate

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