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Supplementation With Lactoferrin in Preterm Newborns (lactoprenew)

Primary Purpose

Prematurity, Low Birth Weight

Status
Completed
Phase
Phase 4
Locations
Study Type
Interventional
Intervention
Lactoferrin
Lactoferrin
Sponsored by
University of Siena
About
Eligibility
Locations
Arms
Outcomes
Full info

About this trial

This is an interventional treatment trial for Prematurity

Eligibility Criteria

23 Weeks - 32 Weeks (Child)All SexesDoes not accept healthy volunteers

Inclusion criteria:

  • Newborns with a birthweight ≤ 1500 grand/or gestational age ≤ 32 weeks
  • Sign of the informed consent by parents

Exclusion criteria:

  • Fetal-onset disorders and/or recognizable at birth
  • Milk intolerance
  • Family history of allergies
  • Use of infant formula supplemented with lactoferrin

Sites / Locations

    Arms of the Study

    Arm 1

    Arm Type

    Experimental

    Arm Label

    Lactoferrin

    Arm Description

    Outcomes

    Primary Outcome Measures

    The main objective of the study is to evaluate the antioxidant effect of lactoferrin and its ability to reduce free radicals related diseases in the newborn. This evaluation will be done trough the assessment of neuro-developmental follow-up.

    Secondary Outcome Measures

    The secondary objective is to identify a panel of markers for assessing oxidative stress and for a correlation with the lactoferrin antioxidant effect.

    Full Information

    First Posted
    July 28, 2010
    Last Updated
    March 24, 2020
    Sponsor
    University of Siena
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    1. Study Identification

    Unique Protocol Identification Number
    NCT01172236
    Brief Title
    Supplementation With Lactoferrin in Preterm Newborns
    Acronym
    lactoprenew
    Official Title
    Supplementation With Lactoferrin in Preterm Newborns
    Study Type
    Interventional

    2. Study Status

    Record Verification Date
    April 2010
    Overall Recruitment Status
    Completed
    Study Start Date
    January 2011 (Actual)
    Primary Completion Date
    January 2012 (Actual)
    Study Completion Date
    January 2013 (Actual)

    3. Sponsor/Collaborators

    Responsible Party, by Official Title
    Principal Investigator
    Name of the Sponsor
    University of Siena

    4. Oversight

    5. Study Description

    Brief Summary
    The main objective of the study is to evaluate the antioxidant effect of lactoferrin and its ability to reduce free radicals related diseases in the newborn. This evaluation will be done through the assessment of neuro-developmental follow-up. The secondary objective is to identify a panel of markers for assessing oxidative stress and for a correlation with the lactoferrin antioxidant effect.
    Detailed Description
    The study arises from the need to structure care to identify a product natural with antioxidant propriety that may reduce the extent of damage in perinatal neurological disorders related to oxidative stress by limiting the pain for infants and families and simultaneously reducing the cost to the SSN arising from standard pharmacological therapy and rehabilitation in the short and medium term. The research results will remain available to the scientific community and will not be used for profit or commercial. The iron (Fe) is the most abundant transition metal1 in the body and an essential element for growth and welfare of almost all life2 where he played a key role in many biochemical processes3. It is essential as cofactor in many enzymatic reactions and as catalyst in the processes of electron transport, yet is potentially toxic and rarely available. In the presence of oxygen Fe causes harmful action on the cell since it enhances the production by non-enzymatic reactive oxygen species. The hydroxyl radical in particular, can damage various cellular components such as DNA, proteins and membrane lipids. All bodies have therefore developed strategies that allow them to retain Fe was acquired in a soluble, nontoxic and in a form readily available. The Fe excess, also caused by weak bonds that the metal has with nonspecific and specific plasma proteins may carry out its negative effects by generating free radicals through the reactions of Fenton and Heber-Weiss4. Physiological requirements of Fe is higher during periods of rapid growth and differentiation, such as perinatal and nervous system that develops rapidly in late fetal life and early neonatal period, appears to be particularly sensitive to modulations of Fe contents5 In the newborn the inability to regulate, as necessary, the uptake of Fe by the immature gut may be the reason for failure and / or excess metal. Both situations may have adverse effects on neurological development of infants and in case of failure becomes irreversible even6-8 because any supplementation does not improve autcome9-11. In both cases the events that occur in early childhood have adverse effects on neuronal function in adults. The mechanism by which iron deficiency affects brain development is completely unknown but we know that can range up to a general lack metabolic errors of myelination and synaptogenesis and changes in specific funcions12 . It was also suggested that the adverse clinical outcomes in premature infants receiving blood transfusions and / or colonization13 may be related to oxidative damage14-17 <br>The main source of food for newborns is breast milk or formula. Breast milk contains heme Fe consequently the non-heme Fe, which is bound to milk proteins and other substances with lower molecular weight, is the main source of Fe in the diet of infants. The child is able to regulate the absorption of iron from the gut, in response to supplementation, only near the first year of life,18 so the inability of infants to regulate the intestinal absorption predisposes them to a deficiency when the Fe in the diet is insufficient, or an overload, when levels in the diet are high. It was also suggested that the enrichment of Fe in young children may lead to an increase in its plasma concentration and the formation of nonspecific compounds (nonspecific binding to proteins with low affinity bonds) that give rise to the so-called free Fe (NPBI) which originate from reactive oxygen species. Some authors have demonstrated increased oxidative stress in infants of very low birth weight who were subjected to a large oral iron supplementation, especially if breastfed seno.19-21 Although gestational age and some clinical treatments such as transfusions and ventilation considered because of an increased risk of oxidative damage Fe-indotto.22 Since the status of Fe in breast-fed term infants is usually satisfactory, at least until the sixth month, and an important part of Fe in human milk is bound to lactoferrin, has been previously suggested that the effect protective of human milk is related to the presence of this protein fixing most of the Fe and regulates its absorption. The lactoferrin is an iron-binding protein, naturally found in high concentrations in breast milk and in low concentrations in other fluids esocrini23. For the size and structure of lactoferrin is closely linked to another group of Fe-related protein, the transferrin and is considered by many as a member of this family. Lactoferrin binds iron with high affinity binding and its structure is unusually resistant to proteolytic degradation. Besides regulating the absorption of iron during inflammatory processes and infettivi24 performs several physiological functions including antibacterial, antifungal, antivirale25, antiparassitary26, antitumoral27, immunomodulator28-29. This ability antibacterial and antiviral properties, may explain the low prevalence and shorter duration of infection in breast-fed infants. In human milk lactoferrin plays an antioxidant sequestering free ions of Fe30 and thus preventing lipid peroxidation and subsequent milk oxidation31. Some AA.32 have shown this property in vitro using salts and Fe ions in the presence of a biological agent such as reducing ascorbato33. A recent study has also demonstrated its antioxidant effect in blood34. Again lactoferrin is able to bind free Fe, from binding studies, avoiding be sure to trigger a series of chain reactions that produce free radicals and thus reduces the damage induced by oxidative stress. This explains why breastfed children have significantly higher total antioxidant capacity and significantly lower index of oxidative stress. A recent study on infants supplied with formula supplemented with lactoferrin showed that presence of this protein helps the absorption of Fe in the small gut. The same study suggests that its activity could stimulate the proliferation and differentiation of mucosal cells in the gut35, thus increasing the surface and in turn increase the absorption of nutrients. Studies in pregnancy women 36 suggests that lactoferrin may have an anti-inflammatory effect, while also improving the Fe status of women.

    6. Conditions and Keywords

    Primary Disease or Condition Being Studied in the Trial, or the Focus of the Study
    Prematurity, Low Birth Weight

    7. Study Design

    Primary Purpose
    Treatment
    Study Phase
    Phase 4
    Interventional Study Model
    Single Group Assignment
    Masking
    None (Open Label)
    Allocation
    N/A
    Enrollment
    1300 (Actual)

    8. Arms, Groups, and Interventions

    Arm Title
    Lactoferrin
    Arm Type
    Experimental
    Intervention Type
    Drug
    Intervention Name(s)
    Lactoferrin
    Intervention Description
    Experimental group: newborns (group A) will receive a daily dose of 100 mg of lactoferrin (Dicorfam® Elleffe 1''% 2C supplement containing lactoferrin) + standard therapy. Control group: newborns (group B) will receive only standard therapy and they will be used as controls.
    Intervention Type
    Drug
    Intervention Name(s)
    Lactoferrin
    Intervention Description
    Experimental group: 650 newborns (group A) will receive a daily dose of 100 mg of lactoferrin (Dicorfam® Elleffe 1''% 2C supplement containing lactoferrin) + standard therapy.Control group: 650 newborns (group B) will receive only standard therapy and they will be used as controls.
    Primary Outcome Measure Information:
    Title
    The main objective of the study is to evaluate the antioxidant effect of lactoferrin and its ability to reduce free radicals related diseases in the newborn. This evaluation will be done trough the assessment of neuro-developmental follow-up.
    Time Frame
    12 months
    Secondary Outcome Measure Information:
    Title
    The secondary objective is to identify a panel of markers for assessing oxidative stress and for a correlation with the lactoferrin antioxidant effect.
    Time Frame
    24 months

    10. Eligibility

    Sex
    All
    Minimum Age & Unit of Time
    23 Weeks
    Maximum Age & Unit of Time
    32 Weeks
    Accepts Healthy Volunteers
    No
    Eligibility Criteria
    Inclusion criteria: Newborns with a birthweight ≤ 1500 grand/or gestational age ≤ 32 weeks Sign of the informed consent by parents Exclusion criteria: Fetal-onset disorders and/or recognizable at birth Milk intolerance Family history of allergies Use of infant formula supplemented with lactoferrin

    12. IPD Sharing Statement

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    Supplementation With Lactoferrin in Preterm Newborns

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