Severe Acute Malnutrition Clinical Trial
— OptiDiagOfficial title:
OptiDiag: Biomedical Investigations for Optimized Diagnosis and Monitoring of Severe Acute Malnutrition (SAM): Elucidating the Heterogeneous Diagnosis of SAM by Current Anthropometric Criteria and Moving Beyond
NCT number | NCT03400930 |
Other study ID # | 1061/15 |
Secondary ID | |
Status | Completed |
Phase | |
First received | |
Last updated | |
Start date | January 1, 2017 |
Est. completion date | April 25, 2018 |
Verified date | July 2019 |
Source | Action Contre la Faim |
Contact | n/a |
Is FDA regulated | No |
Health authority | |
Study type | Observational |
INTRODUCTION
In 2014, 50 million children under 5 suffered from acute malnutrition, of which 16 million
suffered from SAM, most of them living in sub-Saharan Africa and Southeast Asia. SAM children
have higher risk of mortality (relative risk between 5 and 20). It is an underlying factor in
over 50% of the 10 - 11 million preventable deaths per year among children under five. At
present, 65 countries have implemented WHO recommendations for SAM treatment (both in-patient
for complicated cases and outpatient for uncomplicated cases) but these programs have very
low coverage, reaching only around 10 - 15 % of SAM children.
In 2009 the World Health Organization (WHO) and the United Nations Children's Fund (UNICEF)
issued a joint statement in an effort to harmonize the application of anthropometric criteria
for SAM diagnosis and monitoring in child aged 6 - 59 months; the statement presents
recommended cut-offs, and summarizes the rational for the adoption, of the following two
anthropometric criteria:
1. Weight-for-Height Z-Score (WHZ): "WHO and UNICEF recommend the use of a cut-off for
weight-for-height of below -3 standard deviations (SD) of the WHO standards to identify
infants and children as having SAM." Additionally, analysis of existing data show that
children with a WHZ < -3 have a highly elevated risk of death.
2. Mid-Upper Arm Circumference (MUAC): "WHO standards for the MUAC-for-age show that in a
well-nourished population there are very few children aged 6 - 59 months with a MUAC
less than 115 mm. Children with a MUAC less than 115 mm have a highly elevated risk of
death compared to those who are above. Thus it is recommended to [use] the cut-off point
[of] 115 mm to define SAM with MUAC."
GENERAL OBJECTIVE
To generate new evidence on pathophysiological process, nutritional needs and risks
associated with different types of anthropometric deficits in children under 5, in order to
optimize the diagnosis and treatment of SAM.
SPECIFIC OBJECTIVES
- To compare nutritional status, metabolism, pathophysiological process and risks in
different types of SAM anthropometric diagnosis, with or without concomitant stunting
(growth retardation).
- To analyze the extent to which current SAM treatment is promoting recovery and healthy
growth in different categories of children.
- To evaluate the relevance of current discharge criteria used in nutrition programs and
their association with metabolic recovery, in different age groups and among those who
are stunted.
- To test novel rapid tests of emerging biomarkers predicting long-term outcomes and
mortality risk in the field.
METHODOLOGY
A wide range of supplementary information related to nutritional status, body composition,
metabolic and immune status, including emerging biomarkers of metabolic deprivation and
vulnerability, will be collected besides anthropometry during prospective observational
studies. They will be collected with minimum level of invasiveness, compatible with field
work requirements in the humanitarian context.
Phase 1: Cross-sectional surveys. Phase 2: Prospective cohort studies involving SAM children
between 6 months and 5 years old.
Children admitted as SAM at the nutrition centers will be enrolled into the cohort. The
follow up duration will be at least three months.
EXPECTED OUTCOMES
- Confirmation of current hypotheses related to:
1. possible misdiagnosis of SAM made by MUAC or WHZ criteria,
2. varying degree of severity and need for admission to treatment of the different
types of diagnosis,
3. underlying heterogeneity of the pathophysiology.
- Generation of new algorithms for the assessment and classification of malnourished
children, based on the combined use of emerging biomarkers and anthropometric measures,
or on the modification of anthropometric criteria.
- Generation of new treatment paradigms based on the predictive value of biomarkers in
combination with traditional anthropometric measures. This will enable us to assess the
power of current treatment regimens to promote long-term weight gain and growth and will
allow us to tailor treatment to the physiological needs of the child.
Status | Completed |
Enrollment | 473 |
Est. completion date | April 25, 2018 |
Est. primary completion date | April 25, 2018 |
Accepts healthy volunteers | No |
Gender | All |
Age group | 6 Months to 5 Years |
Eligibility |
Inclusion Criteria: - Diagnosed SAM and eligible for CMAM treatment, defined as: (1) WHZ < -3 and/or MUAC < 115 mm; (2) No bilateral pitting edema; (3) Children without the general danger signs of illness as per the Integrated Management of Childhood Illness (IMCI) guidelines like lethargy, unconsciousness, convulsions or severe vomiting (WHO 2005). - Resident of the catchment area at the time of inclusion; and - Caretakers consent for the child to participate. Exclusion Criteria: - Plans to leave the catchment area within the next 6 months; - Known peanut and/or milk allergy; - Admitted for SAM treatment within the past 6 months prior to recruitment (including re-admission after default, relapse or medical transfer); - Malformations which may affect food intake such as cleft palate, cerebral palsy, Down's syndrome; and, - The presence of general danger signs as per the IMCI guidelines. |
Country | Name | City | State |
---|---|---|---|
Bangladesh | Action Against Hunger, Bangladesh | Cox's Bazar | Chittagong |
Burkina Faso | Action Contre la Faim, Burkina Faso | Fada N'Gourma | Région De l'Est |
Liberia | Action Against Hunger, Liberia | Monrovia | Montserrado |
Lead Sponsor | Collaborator |
---|---|
Action Contre la Faim | AgroParisTech, Duke University, European Commission's Directorate-General for European Civil Protection and Humanitarian Aid Operations, Humanitarian Innovation Fund, University College, London, University Ghent |
Bangladesh, Burkina Faso, Liberia,
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* Note: There are 45 references in all — Click here to view all references
Type | Measure | Description | Time frame | Safety issue |
---|---|---|---|---|
Other | Socio-economic index | Measures of household wealth reflected by durable assets, source of water supply, sanitation favility, type of floor material, type of cooking fuel, transportation, livestock, homestead or land area, bank account, number of family members per sleeping room. | At 3 weeks after admission. | |
Other | Household food insecurity access scale (HFIAS) | The HFIAS is composed of a set of nine questions that have been used in several countries and appear to distinguish food insecure from food secure households across different cultural contexts. | At 1 weeks after admission. | |
Other | Individual Dietary Diversity Score (IDDS) | Individual dietary diversity scores (IDDS) validated for age/sex groups. | At 2 weeks, 4 weeks, 6 weeks & 8 after admission. | |
Primary | Leptin | Describe and compare the different types of SAM anthropometric diagnoses based on circulating leptin. | At admission | |
Primary | Stable Isotope Analysis (SIA) | Describe and compare the different types of SAM anthropometric diagnoses based on Stable Isotope Analysis (SIA) | At admission | |
Primary | Clinical Signs | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of clinical signs at admission; these include: dehydration, visible signs of wasting, pulse, signs of micronutrient deficiency, acute resipiratory infections, respiratory rate, temperature, dermatosis and hair changes and diarrhea. | At admission | |
Primary | Micronutrient status | Describe and compare the different types of SAM anthropometric diagnoses based on micronutrient status. | At admission | |
Primary | Bioelectric impedance (BI) | Describe and compare the different types of SAM anthropometric diagnoses based on bioelectric impedance (BI). | At admission | |
Primary | Patient's health and nutritional status (caretaker's perception) | Describe and compare the different types of SAM anthropometric diagnoses based on the caretaker's perception of the patient's health and nutritional status. | At admission | |
Secondary | Stable Isotope Analysis (SIA) | Describe and compare the different types of SAM anthropometric diagnoses based on the history of lipid and protein catabolism (d13C and d15N isotopes in hair) reversed throughout nutritional rehabilitation. | At 2 weeks, 4 weeks, 6 weeks & 8 after admission. | |
Secondary | Clinical signs: dehydration | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of clinical signs for dehydration at admission and the development of clinical signs of dehydration during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: visible wasting | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of clinical signs of visible wasting at admission and the development of clinical signs of visible wasting during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: pulse | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of abnormal pulse at admission and the development of abnormal pulse during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: micronutrient deficiency | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of clinical signs of micronutrient deficency at admission and the development of clinical signs of micronutrient deficency during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: acute respiratory infection | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of clinical signs of acute respiratory infection at admission and the development of clinical signs of acute respiratory infection during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: respiratory rate | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of abnormal respiratory rate at admission and the development of clinical signs of abnormal respiratory rate during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: temperature | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of abnormal temperature at admission and the development of clinical signs of abnormal temperature during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: dermatosis | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of clinical signs of dermatosis at admission and the development of clinical signs of dermatosis during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: hair changes | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of clinical signs of hair change (color and consistency) linked to acute malnutrition at admission and the development of clinical signs of of hair change (color and consistency) during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Clinical signs: diarrhea | Describe and compare the different types of SAM anthropometric diagnoses based on the severity of diarrhea at admission and the development of diarrhea during treatment. | At 2 weeks & 8 weeks after admission. | |
Secondary | Treatment outcomes | Describe and compare the different types of SAM anthropometric diagnoses based on negative and positive treatment outcomes; these include: discharged from program as recovered [mid-upper arm circumference (MUAC) = 125 and weight-for-height Z-score (WHZ) = -2], defaulted from program (caretaker confirmation of unwillingness to participate), death, transfer to an in-patient facility (developement of medical complications as per national protocol, loss of or static weight), transfer to another out-patient facility outside of the program catchment area and facility and non-response to treatment (cure criteria unattained before maximum treatment duration). | Events occuring up to maximum treatment duration as per national protocol (up to 12 weeks in Bangladesh, up to 16 weeks in Burkina Faso, and up to 12 weeks in Liberia). | |
Secondary | Early weight gain | Describe and compare the different types of SAM anthropometric diagnoses based on early weight gain. | After 2 weeks and 4 weeks after admission. | |
Secondary | Leptin | Describe and compare the different types of SAM anthropometric diagnoses based on circulating leptin | At 2 weeks & 8 weeks after admission. | |
Secondary | Micronutrient status | Describe and compare the different types of SAM anthropometric diagnoses based on micronutrient status. | At 2 weeks & 8 weeks after admission. | |
Secondary | Patient's health and nutritional status (caretaker's perception) | Describe and compare the different types of SAM anthropometric diagnoses based on the caretaker's perception of the patient's health and nutritional status. | At 2 weeks & 8 weeks after admission. | |
Secondary | Bioelectric impedance (BI) | Describe and compare the different types of SAM anthropometric diagnoses based on bioelectric impedance. | At 2 weeks & 8 weeks after admission. |
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