Age Infants (age + infant)

Distribution by Scientific Domains

Kinds of Age Infants

  • gestational age infant


  • Selected Abstracts


    Transepidermal water loss in 24 and 25 weeks gestational age infants

    ACTA PAEDIATRICA, Issue 6 2000
    LB Nonato
    No abstract is available for this article. [source]


    What are you looking at?

    DEVELOPMENTAL SCIENCE, Issue 1 2008
    Infants' neural processing of an adult's object-directed eye gaze
    Previous research suggests that by 4 months of age infants use the eye gaze of adults to guide their attention and facilitate processing of environmental information. Here we address the question of how infants process the relation between another person and an external object. We applied an ERP paradigm to investigate the neural processes underlying the perception of the direction of an adult's eye gaze in 4-month-old infants. Infants showed differential processing of an adult's eye gaze, which was directed at a simultaneously presented object compared to non-object-directed eye gaze. This distinction was evident in two ERP components: The Negative component, reflecting attentional processes, and the positive slow wave, which is involved in memory encoding. The implications of these findings for the development of joint attention and related social cognitive functions are discussed. [source]


    Type I collagen markers in cord serum of appropriate vs. small for gestational age infants born during the second half of pregnancy

    EUROPEAN JOURNAL OF CLINICAL INVESTIGATION, Issue 5 2001
    T. Saarela
    Background The serum concentration of the N-terminal propeptide of type I procollagen (PINP) reflects the synthesis rate of type I collagen, whereas the corresponding C-terminal telopeptide (ICTP) mirrors its degradation. Design PINP and ICTP were measured in a total of 690 cord serum samples from 592 appropriate-for-gestational-age (AGA) infants and 98 smal-for-gestational-age (SGA) infants. These markers were compared between AGA and SGA infants of different gestational ages, ranging from 23 to 41 weeks, and birth weights, from 620 to 4555 g. Results Both PINP and ICTP levels were very high in the preterm AGA infants and declined significantly with advancing gestational age, paralleling the shape of the fetal growth velocity curve. Regardless of the quite large interindividual variations observed in these markers, PINP was significantly lower in both the preterm and term AGA infants than in the SGA infants. This was also the case for ICTP in the preterm infants of gestational age less than 36 weeks. In stepwise multiple regression analyses, gestational age, being either AGA or SGA and head circumference were significant factors to explain the levels of PINP and ICTP. The levels of PINP and ICTP were correlated with each other highly significantly in both the AGA and SGA infants (rs = 0·700 and 0·692, respectively; P < 0·001 in both). Conclusions The levels of type I collagen markers seem to follow closely the shape of the fetal growth velocity curve during different stages of gestation. However, because of the large interindividual variations observed, further studies are needed before the significance of these markers for the assessment of normal and abnormal fetal growth can be established. [source]


    Changes in the Ability to Detect Ordinal Numerical Relationships Between 9 and 11 Months of Age

    INFANCY, Issue 4 2008
    Sumarga H. Suanda
    When are the precursors of ordinal numerical knowledge first evident in infancy? Brannon (2002) argued that by 11 months of age, infants possess the ability to appreciate the greater than and less than relations between numerical values but that this ability experiences a sudden onset between 9 and 11 months of age. Here we present 5 experiments that explore the changes that take place between 9 and 11 months of age in infants' ability to detect reversals in the ordinal direction of a sequence of arrays. In Experiment 1, we replicate the finding that 11- but not 9-month-old infants detect a numerical ordinal reversal. In Experiment 2 we rule out an alternative hypothesis that 11-month-old infants attended to changes in the absolute numerosity of the first stimulus in the sequence rather than a reversal in ordinal direction. In Experiment 3, we demonstrate that 9-month-old infants are not aided by additional exposure to each numerosity stimulus in a sequence. In Experiment 4 we find that 11-month-old but not 9-month-old infants succeed at detecting the reversal in a nonnumerical size or area-based rule, casting doubt on Brannon's prior claim that what develops between 9 and 11 months of age is a specifically numerical ability. In Experiment 5 we demonstrate that 9-month-old infants are capable of detecting a reversal in ordinal direction but only when there are multiple converging cues to ordinality. Collectively these data indicate that at 11 months of age infants can represent ordinal relations that are based on number, size, or cumulative area, whereas at 9 months of age infants are unable to use any of these dimensions in isolation but instead require a confluence of cues. [source]


    Protein intake, growth and lung function of infants with chronic lung disease

    JOURNAL OF HUMAN NUTRITION & DIETETICS, Issue 3 2009
    E. Cillié
    Background:, The increased survival rate of extremely preterm infants has not improved the incidence or outcome of infants diagnosed with chronic lung disease (CLD) (Riley, 2008). The relationship between optimal nutrition (particularly protein intake) and chronic lung disease has not been established. The aim of this study was to investigate the association between protein intake, growth and lung function in infants with CLD. Methods:, A CLD database, maintained for the past 10 years, was used to select participants that had reached 1 year of corrected age. Infants who were born during 2001,2006 with a birth weight of <1500 g, and who subsequently had a diagnosis of CLD, were included. Infants with evidence of intra-uterine growth restriction and abnormal cerebral pathology were excluded. Demographic, mean weight gain, protein intake and respiratory support data were collected retrospectively from the medical notes. Growth parameters and need for oxygen and inhalers up to 1 year of corrected age were collected from the CLD follow-up database. SPSS, version 15 (SPSS Inc., Chicago, IL, USA) were used for Pearson's or Spearmans correlation analysis and analysis of variance or the Wilcoxon test, as appropriate. Results:, Sixty infants were studied: 25 females and 35 males. The median (range) post-menstrual age at birth was 26 (22,31) weeks. The most common feed was breast milk; fortified breast milk was used for 37% of the total days studied. The mean (SD) protein intake was 2.28 (0.33) g kg,1 day,1 and the mean (SD) weight gain was 11.67 (1.77) g kg,1 day,1. There was a positive correlation between protein intake and weight gain (r = 0.32, P = 0.013), which was stronger in females (r = 0.51, P = 0.009). Protein intake was significantly associated with head circumference growth in females only (r = 0.47, P = 0.038). Protein intake was inversely related to the number of days spent mechanically ventilated (r = ,0.32, P = 0.015). There was no relationship between protein intake and growth at 1 year corrected age, time spent on continuous positive airway pressure, age weaned off oxygen, or the use of inhalers. There was an inverse correlation between total weeks of oxygen dependence and head circumference at 1 year (r = ,0.35, P = 0.022). Discussion:, The mean protein intake was <3 g kg,1 day,1, which is the minimum requirement for preterm infants (Tsang et al., 2005). This was associated with a sub-optimal weight gain in our participants of <15 g kg,1 day,1 (Steward & Pridham, 2002). The study demonstrates the known association between low protein intake and poor growth with ventilator dependence (Loui et al., 2008). Conclusions:, Low birth weight and low gestational age infants at risk of CLD should receive special attention to optimise their protein intake because sub-optimal protein intake potentially leads to poor growth when on a neonatal intensive care unit. References Loui, A., Tsalikaki, E., Maier, K., Walch, E., Kamarianakis, Y. & Obladen, M. (2008) Growth in high risk infants <1500 g birth weight during the first 5 weeks. Early Hum. Dev. 84, 645,650, Doi: 10.1016/j.earlhumdev.2008.04.005. Riley, K., Roth, S., Sellwood, M. & Wyatt, J.S. (2008) Survival and neurodevelopmental morbidity at 1 year of age following extremely preterm delivery over a 20-year period: a single centre cohort study. Acta Paediatr.97, 159,165. Steward, D.K. & Pridham, K.F. (2002) Growth patterns of extremely low-birth-weight hospitalised preterm infants. JOGN Nurs31, 57,65. Tsang, R.C., Uauy, R., Koletzko, B. & Zlotkin, S.H., eds. (2005) Nutrition of the Preterm Infant: Scientific Basis and Practical Guidelines. Cincinnati: Digital Educational Publishing. [source]


    Resuscitation of extremely low gestational age infants: an Advisory Committee's Dilemmas

    ACTA PAEDIATRICA, Issue 6 2010
    Daniel BattonArticle first published online: 5 MAR 2010
    No abstract is available for this article. [source]


    Brain abnormalities in extremely low gestational age infants: a Swedish population based MRI study

    ACTA PAEDIATRICA, Issue 7 2007
    Sandra Horsch
    Abstract Aims: Brain abnormalities are common in preterm infants and can be reliably detected by magnetic resonance (MR) imaging at term equivalent age. The aim of the present study was to acquire population based data on brain abnormalities in extremely low gestational age (ELGA) infants from the Stockholm region and to correlate the MR findings to perinatal data, in order to identify risk factors. Methods: All infants with gestational age <27 weeks, born in the Stockholm region between January 2004 and August 2005, were scanned on a 1.5 T MR system at term equivalent age. Images were analysed using a previously established scoring system for grey and white matter abnormalities. Results: No or only mild white matter abnormalities were observed in 82% and moderate to severe white matter abnormalities in 18% of infants. The Clinical Risk Index for Babies (CRIB II) score, use of inotropes, the presence of high-grade intraventricular haemorrhages and posthaemorrhagic ventricular dilatation were associated with white matter abnormalities. Conclusion: The incidence of moderate to severe white matter abnormalities in a population-based cohort of ELGA infants from the Stockholm region was 18%. To examine the clinical relevance of these promising results, neurodevelopmental follow up at 30 month corrected age, is ongoing. [source]