Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT05878379 |
| Other study ID # |
MUPH 2018-048 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
May 2, 2018 |
| Est. completion date |
October 30, 2018 |
Study information
| Verified date |
May 2023 |
| Source |
Mahidol University |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Iron deficiency (ID) continues to be one of the most prevalent disorders, which can adversely
affect cognitive ability in childhood. Our aim was to determine the effect of a dietary iron
education program (DIP) on children's iron status and intelligence quotient (IQ) score. This
pre-test (week 1) post-test (week 16) quasi-experimental study with follow-up (week 18)
utilized constructs from the Health Belief Model. Children and caregivers participated in the
DIP which incorporated group talks, presentations, brainstorming, game-based learning and
cooking sessions from weeks 2-15. Knowledge of ID and dietary iron, perceived susceptibility
and severity, benefits and barriers for changing behavior, dietary intake, iron status and IQ
score were determined at all timepoints (weeks 1, 16, and 18).
Description:
1. Objective The objective of this study was to determine whether an education-based
dietary iron program that involved school teachers, parents and children could increase
iron status and intelligence quotient (IQ) score in a group of schoolchildren.
2. Methods
2.1 Study design A quasi-experimental study (pre-test post-test design with follow-up) was
used in this study that was based on the Health Belief Model as its theoretical framework.
2.2 Study Setting and Participants Child-parent/caregiver dyads were recruited from one
purposively selected government-administered primary school in Phatthalung province. Schools
were not involved in any other programs, located in a rural area, and had at least 200
children studying in grades 4-5. Hookworm screening was done 6 weeks before program
implementation by the local government screening program. All children who were studying in
grades 4-5 in the selected school were invited to participate. Out of 190 children, 34
children who were mildly anemic were enrolled in the study, together with their
parents/caregivers. Sample size was calculated based on serum ferritin concentrations among
school-aged children from a study by Rahman et al. [17]. Informed written consent was
obtained from child-parent/caregiver dyads prior to program implementation.
2.3 Procedure for the intervention The Health Belief Model underpinned the development of the
dietary iron program, which focused on the importance of adequate dietary iron consumption
and emphasized prevention of iron deficiency (ID) and iron deficiency anemia (IDA). It was
implemented from weeks 2 to 15 of the study. Child-parent/caregiver dyads and teachers
received an ID/IDA booklet that included information about anemia, causes of ID, iron-rich
food, iron concentration in traditional foods, dietary enhancers and inhibitors of iron
absorption, and recipes for iron-rich local and culturally appropriate meals for teachers,
parents/caregivers and children, as part of the dietary iron program.
Teachers who were involved in school lunch design participated for discussing and planning
iron-rich school lunch menus, and observed teaching and learning process with the use of
media and games during the iron lessons for children. Four lessons were conducted for
parents/caregivers. The first lesson was discussion that addressed parental perceptions about
children's susceptibility to ID and IDA and the severity of ID and IDA concerning cognitive
function. In the second lesson, parents/caregivers were asked to list the benefits and
barriers for changing behavior with regards to preparing more iron-rich foods in the home.
Then, the principal researcher invited parents/caregivers to brainstorm and share ways to
overcome these barriers. Cooking classes for preparing iron-rich meals at home were
conducted. Parents/caregivers voted for two iron-rich meals that they wanted to cook and then
they prepared and cooked them in the classes. For the final lesson, the principal researcher
visited each parent/caregiver to discuss the barriers they faced when trying to incorporate
more iron-rich meals into their child's diet at home. Three lessons were conducted for the
children, one per month. In the first lesson, group talks and games were used to engage the
children about the causes and effects of ID and IDA. The second lesson focused on iron-rich
food. After that, the children partook in games that entailed writing names of food
ingredients that contained iron and circling pictures of iron-rich foods, and describing the
sensations associated with consuming these foods. Both positive and negative answers from
children were selected for discussion, and approaches for consuming more iron-rich food were
brainstormed. A market assignment was set to help the children remember the names of
iron-rich food and recognize the foods when they visited a market with their parents. The
last lesson was a cooking class. After each cooking class finished, the researcher and a
teacher encouraged them to eat this meal together.
2.4 Measurement outcomes The main outcome for this study was the effect of an education-based
dietary iron program on iron status and intelligence quotient (IQ) score among children
before program implementation (week 1) and at week 16 (immediately after program
implementation) and at 18 weeks (follow-up appointment to determine the sustainability of the
intervention). All of the outcome variables were measured at different time points.
Children's knowledge towards ID and IDA was determined using a questionnaire, while
children's iron intake was estimated by using three days of 24-hour recalls (2 school days
and 1 weekend day). Portion sizes were estimated by using household portion sizes
(rice-serving spoon, tablespoon, teaspoon and glass). IQ score was measured by a trained
child psychologist by using the Standard Progressive Matrices (SPM) parallel version. Iron
status was determined from blood samples drawn by medical technologists in the first-aid
rooms. Concentration of hemoglobin, serum ferritin and serum C-reactive protein were measured
by laboratory staff at hematology laboratory at N-health laboratory, Bangkok Dusit Medical
Service Hospital (BDMS), Songkla province, using the hemoglobin assay kit (Colorimetric),
chemiluminescent immunoassay (CMIA) and high-sensitivity C-reactive protein methods,
respectively. Iron status was defined iron-replete: hemoglobin >115 g/l and serum ferritin
level > 30 µg/l; anemia: hemoglobin <115 g/l and serum ferritin level >30 µg/l; mild-moderate
iron depletion with anemia: hemoglobin 80-114 g/l and serum ferritin level <30 µg/l.; mild
iron depletion without anemia: serum ferritin level < 30 µg/l and hemoglobin>115 g/l. In
addition, parents/caregivers were assessed by using a questionnaire toward knowledge and
perceptions consisted of perceived susceptibility, severity, benefits and barriers in
relation to ID and IDA.
2.5 Data Analysis Data from questionnaires were recorded using EpiData version 3.1, while
24-hour dietary recall data were entered into INMUCAL V3, which is a nutrient composition
database of dietary items commonly consumed in Thailand. Portion sizes were converted into
grams before entering data, and energy and nutrient intakes were calculated. Statistical
analysis was carried out by using SPSS version 18. Frequencies, percentage, mean (SD) and
median (25th-75th percentile) were calculated for demographic characteristics of participant
knowledge, perceptions, iron intake, iron status, and IQ score. The One-Way Repeated Measures
ANOVA and Friedman's Two-Way Analysis of Variance by Ranks were used to compare mean
differences in knowledge score and perception score of IDA and ID prevention among
parents/caregivers, total iron intake, heme iron intake, non-heme iron intake, iron status
and IQ score among children at different time points. The Monte Carlo exact test was used to
compare the number of children in grades 4-5 who met/did not meet the Thai DRI for iron at
pre-test, post-test and follow-up. Differences were considered to be significantly different
when p<0.05.
2.6 Ethical approval The study was granted ethical approval by the Committee of the Ethical
Review for Human Research, Faculty of Public Health, Mahidol University Thailand 9 March 2018
(COA. No. MUPH 2018-048).
