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Abstract

Background

Neonates, particularly those born preterm, undergo multiple painful procedures in neonatal intensive care units (NICUs). Evidence shows that such exposures are not transient but induce long-lasting neuroimmune and epigenetic changes, creating a phenomenon termed “pain memory,” with effects on brain development and behavior.

Methods

This scoping review was conducted using a PICOT framework. Population: neonates (preterm and term); Intervention: procedural or surgical pain and its management (pharmacological and non-pharmacological); Comparator: infants with lower/no pain exposure or alternative management; Outcomes: (a) biological mechanisms, (b) neurodevelopmental and behavioral sequelae such as anxiety and dysregulation, (c) demographic/sex-specific differences, (d) clinical management strategies; Timeframe: immediate to long-term follow-up. Searches of PubMed, Embase, Web of Science, Scopus, and Cochrane (1990-May 2025) identified 342 records. Following duplicate removal, 270 abstracts were screened, 90 full texts were reviewed, and 30 studies were included. Screening was performed independently by two reviewers, with conflicts resolved by a third adjudicator. Data were charted for design, demographics, interventions, outcomes, and limitations.

Results

Studies have revealed that early nociceptive injury primes microglia and reprograms macrophages through epigenetic pathways. Clinical cohorts showed cumulative pain exposure associated with altered thalamic/cortical development, reduced white-matter integrity, lower cognitive scores, and higher risks of anxiety and behavioral dysregulation. Females exhibited stronger immune-mediated programming, while extremely preterm infants were most vulnerable. Non-pharmacological strategies (skin-to-skin, breastfeeding, sucrose), alongside judicious pharmacological use, reduced acute pain and may influence long-term outcomes.

Conclusions

Neonatal pain memory represents durable biological and behavioral alterations. Multimodal, family-centered approaches should be standard, while future trials must clarify whether early interventions reduce later neurodevelopmental risks and how sex-specific mechanisms can inform personalized care.

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References

Anand

, Hickey

PR.

Pain and its effects in the human neonate and fetus. N Engl J Med . 1987;317(21):1321–1329.

Simons

, van Dijk

, Anand

, Roofthooft

, van Lingen

, Tibboel

Do we still hurt newborn babies? A prospective study of procedural pain and analgesia in neonates. Arch Pediatr Adolesc Med . 2003;157(11):1058–1064.

Fitzgerald

, Walker

SM.

Infant pain mechanisms: Cortical network modulation, risk factors, and treatment. Anesthesiol Clin . 2009;27(3):439–452.

Grunau

, Holsti

, Peters

JW.

Long-term consequences of pain in human neonates. Semin Fetal Neonatal Med . 2006;11(5):268–275.

Grunau

RE.

Neonatal pain in very preterm infants: Long-term effects on brain, neurodevelopment and pain reactivity. Rambam Maimonides Med J . 2013;4(4):e0025.

Beggs

, Currie

, Salter

, Fitzgerald

, Walker

SM.

Priming of adult pain responses by neonatal pain experience: Maintenance by central neuroimmune activity. Brain . 2012;135(Pt 2):404–417.

Walker

, Beggs

, Baccei

ML.

Persistent changes in peripheral and central nociceptive processing after early tissue injury. J Biomed Biotechnol . 2011;2011:718946.

Burke

, Fan

, Trang

Microglia in health and pain: Impact of noxious early life events. Exp Physiol . 2016;101(8):1003–1015.

Dourson

, Fadaka

, Warshak

, . Macrophage memories of early-life injury drive neonatal nociceptive priming. Cell Rep . 2024;43(5):114129.

10.

Schwabenland

, Mossad

, Sievert

, . Neonatal immune challenge poses a sex-specific risk for epigenetic microglial reprogramming and behavioral impairment. Nat Commun . 2023;14:2721.

11.

Chau

CMY

, Synnes

, Oberlander

, Grunau

RE.

Neonatal pain and COMT Val158Met genotype in relation to serotonin transporter gene methylation in very preterm children. Front Behav Neurosci . 2014;8:409.

12.

Hatfield

, Hoffman

, Polomano

, Brahim

JS.

Epigenetic modifications following noxious stimuli in infants. Biol Res Nurs . 2018;20(2):137–144.

13.

Fitzgerald

The development of nociceptive circuits. Nat Rev Neurosci . 2005;6(7):507–520.

14.

Walker

SM.

Biological and neurodevelopmental implications of neonatal pain. Clin Perinatol . 2013;40(3):471–491.

15.

Valeri

, Holsti

, Linhares

MB.

Neonatal pain and developmental outcomes in children born preterm: A systematic review. Clin J Pain . 2015;31(4):355–362.

16.

Vinall

, Grunau

RE.

Impact of repeated procedural pain-related stress in infants born very preterm. Pediatr Res . 2014;75(4):584–587.

17.

Duerden

, Chau

, Grunau

, Synnes

, Poskitt

, Miller

SP.

Early procedural pain is associated with regionally specific alterations in thalamic development in preterm neonates. J Neurosci . 2018;38(3):878–886.

18.

Ranger

, Chau

CMY

, Garg

, . Neonatal pain-related stress and NFKBIA genotype are associated with altered preterm brain development. Brain Behav Immun . 2013;33:88–97.

19.

McLean

, Scoten

, Chau

CMY

, . Association of neonatal pain-related stress and parent interaction with internalizing behaviours from toddlerhood through school age in children born very preterm. JAMA Netw Open . 2022;5(10):e2238088.

20.

Roofthooft

, Simons

SHP

, Anand

KJS

, van Dijk

, Tibboel

Eight-year follow-up of pain sensitivity in children born extremely preterm. Pain . 2014;155(5):867–873.

21.

Slater

, Cantarella

, Gallella

, . Cortical pain responses in human infants. J Neurosci . 2006;26(14):3662–3666.

22.

Selvanathan

, Ufkes

, Guo

, . Pain exposure and brain connectivity in preterm infants. JAMA Netw Open . 2024;7(3):e242551.

23.

Ranger

, Grunau

RE.

Early repetitive pain in preterm infants in relation to their developing brain. Semin Perinatol . 2014;38(2):86–92.

24.

Johnston

, Campbell-Yeo

, Fernandes

, Inglis

, Streiner

, Zee

Skin-to-skin care for procedural pain in neonates. Cochrane Database Syst Rev . 2017;(2):CD008435.

25.

Rørvik

, Eriksson

, Andreasson

, . Parent-led neonatal pain management—A narrative review and update of research and practices. Front Pain Res . 2024;5:1375868.

26.

Taddio

, Shah

, Sanderson

, . Effect of breastfeeding on pain response during immunizations. Cochrane Database Syst Rev . 2016;(10):CD010853.

27.

Stevens

, Yamada

, Ohlsson

, Haliburton

, Shorkey

Sucrose for analgesia in newborn infants undergoing painful procedures. Cochrane Database Syst Rev . 2016;(7):CD001069.

28.

Pillai Riddell

, Salmond

, Flora

, . Non-pharmacological management of infant and young child procedural pain. Cochrane Database Syst Rev . 2023;(6):CD006275.

29.

Carbajal

, Rousset

, Danan

, . Epidemiology and treatment of painful procedures in neonates in intensive care units. JAMA . 2008;300(1):60–70.

30.

Duerden

, Guo

, Dodbiba

, . Midazolam dose correlates with abnormal hippocampal growth and neurodevelopmental outcome in preterm infants. Ann Neurol . 2016;79(4):548–559.

31.

Anand

KJS

, International Evidence-Based Group for Neonatal Pain. Consensus statement for the prevention and management of pain in the newborn. Arch Pediatr Adolesc Med . 2001;155(2):173–180.

32.

American Academy of Pediatrics, Section on Anesthesiology and Pain Medicine, Committee on Fetus and Newborn. Prevention and management of procedural pain in the neonate: An update. Pediatrics . 2016;137(2):e20154271.

33.

Campbell-Yeo

ML.

Reaffirming that every poke counts! Higher repeated pain exposure in early life linked with greater short- and long-lasting alteration of the nociceptive system. Pediatr Res . 2020;87(1):15–16.

34.

Doesburg

, Chau

, Cheung

, . Neonatal pain-related stress, functional cortical activity and visual-perceptual abilities in school-age children born at extremely low gestational age. Pain . 2013;154(10):1946–1952.

35.

Puchalski

, Hummel

The reality of neonatal pain. Adv Neonatal Care . 2002;2(5):233–247.

36.

Williams

, Lascelles

BD.

Early neonatal pain—A review of clinical and experimental implications on painful conditions later in life. Front Pediatr . 2020;8:30.

37.

Jones

, Batalle

, Meek

, . Differential maturation of the brain networks required for the sensory, emotional, and cognitive aspects of pain in human newborns. Pain . 2022;163(10):e1097.

38.

Nuseir

, Alzoubi

, Altarifi

, Kassab

, Khabour

OF.

Long-term effects of neonatal pain and sucrose treatment. Curr Res Pharmacol Drug Discov . 2024;6:100176.

39.

Ling

, Wang

, Zheng

, . Effects of different types of neonatal pain on somatosensory and cognitive development in male juvenile rats. Brain Behav . 2023;13(12):e3309.

40.

Tortora

, Severino

, Di Biase

, . Early pain exposure influences functional brain connectivity in very preterm neonates. Front Neurosci . 2019;13:899.

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The Lasting Imprint: Neonatal Pain Memory Across Biological,Developmental,and Clinical Domains—A Scoping Review

Abstract

Background

Methods

Results

Conclusions

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References

Supplementary Material