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Category: Volume 13 Issue 03 March 2025
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Title: Complications of respiratory function in prematurely born children

Authors: Emilija Manasievski, Karolina Simonovska, Petranka Andonova, Elita Maneva, Mirjana Popovska, Lidija Novachevska, Zorica Dimchevska

 DOI: https://dx.doi.org/10.18535/jmscr/v13i03.08

Abstract

A premature newborn baby is any newborn born before the 37th gestation week. According to their gestational age at birth, premature newborn babies are divided into extreme premature babies (< 28 week), very early premature babies (28-32 week), early premature babes (32-36 week) and late premature babies (> 36 week). Premature birth leads to disruption and alterations in the structure and function of the respiratory system as well as of the pulmonary and systemic immunity. The lung parenchyma is immature at birth because alveolarization begins at 36-37 week and continues until the eighth year of life (Figure 1).Compromised development of pulmonary acini resulting in the creation of larger and fewer alveoli with thinned alveolar-capillary membranes and altered capillary vascularization directly leads to reduced respiratory ventilation and perfusion.36 This leaves repercussions not only in this period of life but also further on as a manifested reduced lung capacity for gas exchange.37

Despite initial assumptions that pulmonary hypoplasia and small immature airways are a predisposing factor, multifactorial influence is a determining factor in the development of chronic obstructive disease and asthma. Numerous factors from the environment (cigarette smoke, air pollution), genetic predisposition to atopy or asthma, susceptibility to severe respiratory viral infections (RSV, HRV), alterations in the microbiome and  in the immature immune system each contribute in their own way to the development of asthma in premature infants. Understanding why these preterm infants are at higher risk of developing asthma is crucial for further prevention, early detection and possibly delaying the onset of asthma, all in order to reduce the increased morbidity and mortality in this group of patients.1

On the other hand, improved intensive neonatal care over recent years has contributed to increased survival even of extremely premature newborns in whom the severity of the initial lung affectedness is more serious and of a larger scale, which directly leads to an increase in the number of children with BPD and chronic respiratory problems further in their lives.2

References

  1. Global, regional, and national estimates of levels of preterm birth in 2014: a systematic review and modelling analysis Lancet Glob Health 2019 Jan;7(1):e37-e46.
  2. ABC of preterm birth, Respiratory complications of preterm birth2004 Oct 23; 329(7472): 962–965.
  3. Lifelong Lung Sequelae of Prematurity Int J Environ Res Public Health. 2022 Apr 26;19(9):5273.
  4. Crump C, Sundquist J, Sundquist K. Preterm or early term birth and long-term risk of asthma into mid adulthood: a national cohort and co-sibling study. 
  5. Jaakkola JJ, Ahmed P, Ieromnimon A, et al. Preterm delivery and asthma: a systematic review and meta-analysis. J Allergy Clin Immunol. 2006;118(4):823-830.
  6. Morata-Alba J, Romero-Rubio MT, Castillo-Corullón S, Escribano Montaner A. Respiratory morbidity, atopy and asthma at school age in preterm infants aged 32-35 weeks. Eur J Pediatr. 2019;178(7):973-982.
  7. Harju M, Keski-Nisula L, Georgiadis L, Räisänen S, Gissler M, Heinonen S. The burden of childhood asthma and late preterm and early term births. J Pediatr. 2014;164(2):295-9.e1.
  8. Mitselou N, Andersson N, Bergström A, et al. Preterm birth reduces the risk of IgE sensitization up to early adulthood: a population based birth cohort study. Allergy. 2022;77(5):1570-1582.
  9. Barcik W, Boutin RCT, Sokolowska M, Finlay BB. The role of lung and gut microbiota in the pathology of asthma. Immunity. 2020;52(2):241-255.
  10. Olin A, Henckel E, Chen Y, et al. Stereotypic immune system development in newborn children. Cell. 2018;174 (5):1277-1292.e14.
  11. Wang S, Zeng S, Egan M, et al. Metagenomics analysis of mother/infant gut microbiome reveals global distinct and shared microbial signatures. Gut Microbes. 2021;13(1):1-24.
  12. Zimmermann P, Messina N, Mohn WW, Finlay BB, Curtis N. Association between the intestinal microbiota and allergic sensitization, eczema, and asthma: a systematic review. J Allergy Clin Immunol. 2019;143(2):467-485.
  13. Healy DB, Ryan CA, Ross RP, Stanton C, Dempsey EM. Clinical implications of preterm infant gut microbiome development. Nat Microbiol. 2022;7(1):22-33.
  14. Patrick DM, Sbihi H, Dai DLY, et al. Decreasing antibiotic use, the gut microbiota, and asthma incidence in children: evidence from population-based and prospective cohort studies. Lancet Respir Med. 2020;8(11):1094-1105.
  15. Arrieta MC, Stiemsma LT, Dimitriu PA, et al. Early infancy microbial and metabolic alterations affect risk of childhood asthma. Sci Transl Med. 2015;7(307):307ra152.
  16. Bizzarro MJ. Avoiding unnecessary antibiotic exposure in premature infants: understanding when (not) to start and when to stop. JAMA Netw Open. 2018;1(1):e180165.
  17. Depner M, Taft DH, Kirjavainen PV, et al. Maturation of the gut microbiome during the first year of life contributes to the protective farm effect on childhood asthma. Nat Med. 2020;26(11):1766-1775.
  18. Fujimura KE, Sitarik AR, Havstad S, et al. Neonatal gut microbiota associates with childhood multisensitized atopy and T cell differentiation. Nat Med. 2016;22(10):1187-1191.
  19. Tomassen P, Jarvis D, Newson R, et al. Staphylococcus aureus enterotoxin-specific IgE is associated with asthma in the general population: a GA(2)LEN study. Allergy. 2013;68(10):1289-1297.
  20. Bisgaard H, Hermansen MN, Buchvald F, et al. Childhood asthma after bacterial colonization of the airway in neonates. N Engl J Med. 2007;357(15):1487-1495.
  21. Raita Y, Pérez-Losada M, Freishtat RJ, et al. Nasopharyngeal metatranscriptome profiles of infants with bronchiolitis and risk of childhood asthma: a multicentre prospective study. Eur Respir J. 2022;60(1):2102293.
  22. Raita Y, Pérez-Losada M, Freishtat RJ, et al. Integrated omics endotyping of infants with respiratory syncytial virus bronchiolitis 13989995, 2023, 4, 2021 Jun 14;12(1):3601.
  23. Jeremy Anderson, Lien Anh Ha Do, Danielle Wurzel, Paul V. Licciardi. Understanding the increased susceptibility to asthma development in preterm infants. 31 January 2023 78,928-939.
  24. Huang YJ, Nelson CE, Brodie EL, et al. Airway microbiota and bronchial hyperresponsiveness in patients with sub optimally controlled asthma. J Allergy Clin Immunol. 2011;127(2):372-381.e1-3.
  25. Anderson EJ, Carbonell-Estrany X, Blanken M, et al. Burden of severe respiratory syncytial virus disease among 33-35 weeks' gestational age infants born during multiple respiratory syncytial virus seasons. Pediatr Infect Dis J. 2017;36(2):160-167.
  26. Drysdale SB, Alcazar-Paris M, Wilson T, et al. Rhinovirus infection and healthcare utilisation in prematurely born infants. Eur Respir J. 2013;42(4):1029-1036.
  27. Jackson DJ, Gangnon RE, Evans MD, et al. Wheezing rhinovirus illnesses in early life predict asthma development in high-risk children. Am J Respir Crit Care Med. 2008;178(7):667-672.
  28. Adnan M, Wu SY, Khilfeh M, Davis V. Vitamin D status in very low birth weight infants and response to vitamin D intake during their NICU stays: a prospective cohort study. J Perinatol. 2022;42(2):209- 216.
  29. Plummer EL, Chebar Lozinsky A, Tobin JM, et al. Postnatal probiotics and allergic disease in very preterm infants: sub-study to the ProPrems randomized trial. Allergy. 
  30. 2020;75(1):127-136.Robin, B.; Kim, Y.L.; Huth, J.; Klocksieben, J.; Torres, M.; Tepper, R.S.; Castile, R.G.; Solway, J.; Hershenson, M.B.; Goldstein-Filbrun, A. Pulmonary function in bronchopulmonary dysplasia. Pediatr Pulmonol. 2004, 37, 236–242.
  31. Hennessy, E.; Bracewell, M.; Wood, N.; Wolke, D.; Costeloe, K.; Gibson, A.; Marlow, N. Respiratory health in pre-school and school age children following extremely preterm birth. Arch. Dis. Child. 2008, 93, 1037–1043.
  32. Narang, I.; Rosenthal, M.; Cremonesini, D.; Silverman, M.; Bush, A. Longitudinal evaluation of airway function 21 years after preterm birth. Am. J. Respir. Crit. Care Med. 2008, 178, 74–80.
  33. Baraldi, E.; Filippone, M. Chronic lung disease after premature birth. N. Engl. J. Med. 2007, 357, 1946–1955.
  34. European Community Respiratory Health Survey. Variations in the prevalence of respiratory symptoms, self-reported asthma attacks, and use of asthma medication in the European Community Respiratory Health Survey (ECRHS). Eur. Respir. J. 1996, 9, 687–695.
  35. Gough, A.; Linden, M.; Spence, D.; Patterson, C.C.; Halliday, H.L.; McGarvey, L.P. Impaired lung function and health status in adult survivors of bronchopulmonary dysplasia. Eur. Respir. J. 2014, 43, 808–816.
  36. De Paepe, M.E.; Mao, Q.; Powell, J.; Rubin, S.E.; Dekoninck, P.; Appel, N.; Dixon, M.; Gundogan, F. Growth of pulmonary microvasculature in ventilated preterm infants. Am. J. Respir. Crit. Care Med. 2006, 173, 204–211.
  37. Sørensen, J.K.; Buchvald, F.; Berg, A.K.; Robinson, P.D.; Nielsen, K.G. Ventilation inhomogeneity and NO and CO diffusing capacity in ex-premature school children. Respir. Med. 2018, 140, 94–100.

Corresponding Author

Emilija Manasievski

PHI University Clinic for Respiratory Diseases in Children - Kozle, Skopje, Republic of North Macedonia