Early Intervention in Preterm Infants: Short and Long Term Developmental Outcome After a Parental Training Program

Study Description

Brief Summary

Preterm infants, during their stay in the Neonatal Intensive Care Unit (NICU), face a period of stressful environment, which may negatively impact early brain development and subsequent neurobehavioral outcomes. This study aims to assess the effectiveness of training parents in reducing stressful experiences early in life and in enhancing brain development and long term developmental outcomes.

Detailed Description

Very preterm birth is associated with motor, cognitive and behavioral problems.

Micro-structural brain abnormalities, even in the absence of focal lesions, have been documented by neuroimaging studies in preterm infants at term corrected age and later in childhood. These alterations in brain maturation occurring during the neonatal period may be implicated in long-term neurobehavioral disorders later experienced by preterm babies.

However, there is increasing evidence that also negative environmental factors (intensive care, excessive sensory stimulation, paucity of parental contact etc.) can affect later outcomes.

Potential benefits of early dyadic interaction and preterm baby massage in reducing the effects of the NICU stressor environment have been demonstrated. More recently, few studies have investigated visual function in preterm infants focusing on the potential role of early visual interaction to enhance attention and improve later neurodevelopment.

The role of early intervention strategies to improve neurodevelopment has been recently emphasized.

Early intervention programs based on the concept of "individualized care" have proved to be effective in promoting brain maturation and neurodevelopmental outcome. In this context, early interventions as the Mother Infant Transaction Program (MITP) and the Premie Start, both targeting parenting, have the greatest potential to have sustained effects on child development.

In addition, recent studies have shown that exposure to stressful events in the neonatal period can cause epigenetic modifications in children born preterm; in particular alteration of serotonergic tone was observed, associated with methylation of the serotonin transporter gene, which could be implicated in the etiology of behavioral disorders observed in these children. In animal models these epigenetic effects appear to be influenced by maternal care that can epigenetically modulate the offsprings' stress response.

Study Design

Outcome Measures

Primary Outcome Measures

1. Neonatal Visual Assessment Battery to evaluate visual function [40 weeks postmenstrual age]

   Neonatal Visual Function is assessed using the Visual Assessment Battery developed by Ricci et al. The assessment evaluates the following items: Ocular spontaneous motility, ability to fix and follow a target, reaction to colour, visual acuity and visual attention at distance. Each item is scored as normal (score 0) or abnormal (score 1). The global score is then calculated as the sum of all the individual items, as designed by the authors.

2. Neonatal Behavior [2 months corrected age]

   Neonatal behavior is assessed using the Neonatal Behavior Assessment Scale that evaluates: habituation, social-interactive, motor system, state organization and regulation, autonomic system, reflexes.

Secondary Outcome Measures

1. Brain development [40 weeks postmenstrual age]

   Conventional and advanced MRI

2. Developmental outcome [24 months corrected age]

   Children development is assessed using the Bayley Scales of Infant and Toddlers (Third edition) - including: cognitive, motor, language, social-emotional and adaptive behavior)

3. Epigenetic changes [up to 48 weeks gestational age]

   epigenetic analysis is performed at birth on a cord blood sample (0.5 ml) and at hospital discharge on a peripheral blood sample (0.5 ml) collected according routine clinical procedures

4. overall duration of hospitalisation [up to 48 weeks gestational age]

   number of days from admission to home discharge from NICU

5. Weight (in grams) at 40 weeks postmenstrual age [40 week gestational age]

6. Length(in centimeters) at 40 weeks postmenstrual age [40 week gestational age]

7. Head circumference (in centimeters) at 40 weeks postmenstrual age [40 week gestational age]

8. Acquisition of full oral feeding [up to 48 weeks gestational age]

   Postmenstrual age at the acquisition of full oral feeding

9. Feeding with Human milk [up to 40 weeks gestational age]

   Feeding with human milk at 40 weeks postmenstrual age (yes or no)

10. Neurodevelopmental outcome [5-6 years of age]

    Children neurodevelopment is assessed using the Griffiths Development Scales (GMDS). Scores range from 50 to 150 General quotient mean 100 SD 12, sub scales mean 100 SD 16 Higher scores mean a better outcome

11. Behavioral outcome [5-6 years of age]

    Children behavior is assessed using the Child Behavior Checklist. A T score above 70 is considered to be in the clinical range, a T score between 65 an 70 is considered borderline while a T score below 65 is considered normal

12. Neuromotor outcome [5-6 years of age]

    Children neuromotor is assessed using the Movement Assessment Battery for Children (Movement ABC). A score above 67 is considered to be in the normal range, a score between 57 an 67 is considered borderline while a score below 56 is considered pathological

13. Attention outcome [5-6 years of age]

    Child attention abilities is assessed using the Early Childhood Attention Battery (ECAB). Scaled scores range from 1 to 19. Lower scores indicate worst outcome

14. L1 promoter methylation levels on buccal swab [5-6 years of age]

    epigenetic analysis - L1 promoter methylation (Percent) assessment is performed on a buccal swab collected at follow-up assessment at 5-6 years.

Eligibility Criteria

Criteria

Inclusion Criteria:

• Gestational age between 25+0 and 29+6 weeks

Exclusion Criteria:

• major brain lesions as documented by cranial ultrasound (intraventricular hemorrhage > 2 grade, cystic periventricular leukomalacia)

• neurosensorial deficits (retinopathy of prematurity > stage 2)

• genetic syndromes and/or major congenital malformations

• major neonatal comorbidities

Mothers are selected according to the following inclusion criteria: age over 18 years, good comprehension of Italian language, no obvious cognitive impairments or psychiatric disorders, no drug addiction and no single-parent families.

Contacts and Locations

Locations

Sponsors and Collaborators

• Fondazione IRCCS Ca' Granda, Ospedale Maggiore Policlinico

Investigators

• Principal Investigator: Monica Fumagalli, MD, Fondazione IRCCS Cà Granda Ospedale Maggiore Policlinico

Study Documents (Full-Text)

More Information

Publications

• Guzzetta A, D'Acunto MG, Carotenuto M, Berardi N, Bancale A, Biagioni E, Boldrini A, Ghirri P, Maffei L, Cioni G. The effects of preterm infant massage on brain electrical activity. Dev Med Child Neurol. 2011 Sep;53 Suppl 4:46-51. doi: 10.1111/j.1469-8749.2011.04065.x.
• Newnham CA, Milgrom J, Skouteris H. Effectiveness of a modified Mother-Infant Transaction Program on outcomes for preterm infants from 3 to 24 months of age. Infant Behav Dev. 2009 Jan;32(1):17-26. doi: 10.1016/j.infbeh.2008.09.004. Epub 2008 Nov 20.
• Provenzi L, Fumagalli M, Sirgiovanni I, Giorda R, Pozzoli U, Morandi F, Beri S, Menozzi G, Mosca F, Borgatti R, Montirosso R. Pain-related stress during the Neonatal Intensive Care Unit stay and SLC6A4 methylation in very preterm infants. Front Behav Neurosci. 2015 Apr 21;9:99. doi: 10.3389/fnbeh.2015.00099. eCollection 2015.
• Ricci D, Cesarini L, Romeo DM, Gallini F, Serrao F, Groppo M, De Carli A, Cota F, Lepore D, Molle F, Ratiglia R, De Carolis MP, Mosca F, Romagnoli C, Guzzetta F, Cowan F, Ramenghi LA, Mercuri E. Visual function at 35 and 40 weeks' postmenstrual age in low-risk preterm infants. Pediatrics. 2008 Dec;122(6):e1193-8. doi: 10.1542/peds.2008-1888.
• Ricci D, Romeo DM, Serrao F, Cesarini L, Gallini F, Cota F, Leone D, Zuppa AA, Romagnoli C, Cowan F, Mercuri E. Application of a neonatal assessment of visual function in a population of low risk full-term newborn. Early Hum Dev. 2008 Apr;84(4):277-80. Epub 2007 Nov 8.