Introduction
Currently, Peru and the world face three child malnutrition burdens: 1) food deficit that causes shortness in height; 2) poor intake of iron-rich foods, which leads to iron deficiency anemia; and 3) excessive eating that results in children being overweight and obese1,2. This situation has caused nutritional deficiencies and psychomotor developmental delays in children3,4.
The World Health Organization (OMS) has defined iron deficiency as the morbid state of blood hemoglobin concentration below the accepted levels according to age, sex, and geographical altitude5. The largest number of cases occurs within the first three years6, which results in physical, psychological, and socio-emotional changes as well as developmental disorders7,8. The insufficient intake of foods rich in iron has become one of the most urgent nutritional and public health problems to face due to the growth and developmental delays that this deficiency may cause. It is a problem that needs to be addressed since the Food and Agriculture Organization of the United Nations (FAO) has acknowledged that the number of nutritional disorders such as iron deficiency anemia (IDA) has increased due to a low budget allocation and the lack of effective health policies9.
Worldwide, nearly a quarter of the population has iron deficiency, of which 42% are under five years of age10. Furthermore, according to the UNICEF (United Nations International Children’s Emergency Fund)11 almost half (48%) of the children between 2 to 5 years old and 41% of children under 3 years old have IDA. In Peru, iron deficiency reached 40% in children aged between 6 and 35 months in 2020 (4.3 percentage points lower than in 2018). 48.4% of these cases were located in rural areas (five regions showed prevalence rates higher than 50%). In the Cajamarca region and the Chota province, 33.8% and 33% of infants displayed iron deficiency, respectively12. This situation indicates that the problem is worsening, especially among the poor and extremely poor sectors of the population, which have been the most hardly affected by the COVID-19 health emergency.
Nutritional (low weight, acute malnutrition, short height, being overweight, etc.) and iron deficiency problems have negative consequences on the growth and development of children, also causing physical, psychological, and social damages as well as increasing child morbidity and mortality rates3,11,13,14. In addition, iron deficiency has short and long term consequences, which are critical for the child’s health status as it increases the risk of psychomotor developmental delays. In this regard, the Spanish Association of Pediatrics4, has identified that deficient nutritional states such as anemia cause a decrease in physical abilities as well as an increase in the risk of delaying the development of psychomotor (language, motor skills, and coordination) and cognitive skills.
Psychomotor development is any dynamic process of acquisition and organization of the child’s biopsychosocial skills, which results from the neuro-maturation required to achieve progressive autonomy of the infant in areas such as coordination, language, and motor skills15,16. Piaget17 from his Cognitive Development theory, states that intellectual development is built from the experiences that each child has in his/her environment. Thus, this construction involves the development of sensorial and psychomotor abilities, which are achieved during the first two years, as well as the development of the symbolic function and language (oral/written), reached between the 2 and 7 years of age. However, iron deficiency not only leads to psychomotor developmental disorders in areas such as coordination, language, and motor skills but also causes problems at cognitive (learning and intelligence) and socio-emotional levels, which manifest in the short and long term18,19.
Based on the UNICEF reports18, 32% of the worldwide population of children under five years old are developmentally delayed, whereas 43% are at risk of psychomotor developmental delay. These figures are a result of an increase in both poverty and chronic malnutrition. In Peru, the mother-child emotional bond in children under one year old reached 48%, with women and rural areas being affected with percentages of 51% and 52%, respectively20. Likewise, 50% of children aged under three years know how to express correctly their emotions (verbal communication). In this regard, the results were more negative for both being male (46%) and living in mountainous areas (48%)12.
In this context and for an efficient approach to the problem, it is essential to recognize that iron deficiency is a disorder that affects children’s psychomotor development during their first years of life, with a greater prevalence in poor populations and those that lack access to basic services (health, education, water, sanitation, etc.). In addition, the developmental disorder and its risk can be the result of the lack of knowledge and inadequate practices in terms of early stimulation at maternal and familial level. This problematic situation, together with the lack of local and regional studies, was the basis to carry out this study.
Materials and methods
Type, design and population of the study
Relational, cross-sectional study conducted between the months of March and April, 2022. The population included 48 children aged 2 - 4 years old, who were treated at the Cuyumalca Clinic. A population-based sample (48=48) was chosen through a non-randomized convenience sampling protocol. The participants were children of both genders who lived in the Centro Poblado neighborhood of Cuyumalca. Children with a diagnosis of mental disability, premature birth, intrauterine growth delay, and multiple births were excluded.
Data collection techniques and instruments
Hemoglobin levels were assessed with a HemoCue® Hb201+ portable hemoglobinometer21, which was used to analyze a capillary blood sample obtained from the tip of the child’s index finger, through a cyanomethemoglobin method. Hemoglobin concentration was classified following the WHO parameters for children aged between six months to five years old5, as follows: normal (≥11.0 g/dl), mild anemia (10.0-10.9g/dl), moderate anemia (7.0-9.9 g/dl), and severe anemia (<7.0 g/dl). This is a safe, accurate and user-friendly method to be used by trained personnel, which has also been internationally standardized by the WHO for hemoglobin testing5,22.
Psychomotor development was assessed through the Psychomotor Development Test (PDT) for 2-5 years old children and the 1985 Haeusssler and Marchand questionnaire16 y utilizado por el Ministerio de Salud de Perú dentro de su normativa para la evaluación del desarrollo psicomotor infantil which is used by the Ministry of Health to assess infant psychomotor development13,19. The PDT test is applied to characterize the child’s performance in multiple areas, including coordination, language and motor skills and provides a global/general development profile. The test includes 52 items (coordination=16; language=24; and motor skills=12), which are quantified as normal (score=01) or disorder (score=00). Likewise, the child’s performance is determined through the total T score obtained in either the total test or the Subsets, where: normal T score≥40 points , risk T score= 30-39 points, and delay T score<29 ponts19.
The PDT test was validated through a study on 540 children organized in 6 age groups. The reliability of its psychometric properties included: (i) the discriminate test-item score (p>0.003); internal concordance: Total Test (KR-20=0.94) and Subtests Coordination (KR-20=0.89), Language (KR-20=0.94) and Motor Skills (KR-20=0.82); and (iii) concurrent validity: Stanford Binet Test evaluated with Pearson r (coordination r=0.73 and language r=0.73) and the Denver Test (Total test=0.85, language=0.84, and motor skills=0.71)16.
Procedure for data collection
Data collection required documented authorization from the Head of the Cuyumalca Health Clinic and the Nursing professional responsible for the growth and development service. The training of the participants was done in the hours of 8:00 am to 5:00 pm through an invitation letter. The hemoglobin level was assessed in the growth and development clinic office and the application of the PDT test was conducted in the early intervention area of this clinic. The equipment (hemoglobinometer) and materials (PDT test battery, procedure manual and PDT format and registry) used were standardize by the WHO and the Peruvian Ministry of Health5,19.
Before the start of data collection, the researchers received training in the portable hemoglobinometer and PDT Test use. This activity was done by the Nursing professional of the clinic.
Ethical criteria
The study was approved by the scientific committee of the Health Sciences Department of the National Autonoma University of Chota, through the department resolution No. 035-2022-FCCSS-UNACH/C, issued on February 23, 2022. The ethical criteria were upheld during the entire process. The mothers who agreed voluntarily to participate in the study signed informed consents prior to the collection of information.
Statistical analysis
The collected information was uploaded in a data matrix designed through SPSS.V.25.0 software. The descriptive statistical analysis applied absolute and relative frequencies. The inferential analysis used Chi-square (X2), adjusted with Fisher’s exact test in frequencies lower than 5, considering a significant p-value<0.05.
Results
The study was done with 48 children from 2 to 5 years of age, from both genders, treated at the Cuyumalca Health Clinic. The average age was 32.6 months, 39.6% were between 2 years 0 months 0 days and 2 years 11 months 29 days, and 52.1% were male (Table 1).
31.2% of the children exhibited some type of anemiz, with moderate anemia being the most frequent (16.7%) (Table 2).
Hemoglobin levels | N(48) | % [IC = 95%] |
---|---|---|
Without anemia | 33 | 68.8 [55.7;81.9] |
Mild anemia | 7 | 14.5 [4.5;24.5] |
Moderate anemia | 8 | 16.7 [6.1;27.3] |
In average, 10.9% of participating children displayed some level of psychomotor developmental disorder, specifically in coordination (6.3%), language (8.4%), and motor skills (16.7%), as well as global development (12.5%) (Table 3).
Source: Psychomotor Development Test (PDT).
There are no statistical differences between iron deficiency anemia and psychomotor development in children from 2 to 5 years of age [p>0.05] (Table 4).
*X2=p>0.05.
Source: Psychomotor Development Test (PDT).
Discussion
The demographic composition of the sample is similar to the characteristics shown by children less than five years of age in the study by Nampijja et al.23 in Uganda, where 50.4% were male, with an average age of 34.6 months, 26.3% had a delay in growth, and 6.5% lived in poverty conditions. Similarly, the Peruvian studies conducted by Chura and Arestegui24, showed that 52.5% of the children were male and ranged between two to three years of age. Burga25 reported that 56% were male, and of these 36% were four years old, while Bravo26 reported 58% were male. Likewise, the result coincide with those reported by the National Institute of Statistics and Computer Sciences (NISCS) in 202019,27, where of the more than 500,000 births, 296,000 were male and 248,000 were female. This is related to the descending demographics in birth, mortality, and marriage rates, which have been registered in Peru during the last two decades. The demographic findings are used to characterize the children and contextualize the social and physical space where they live in, which helps to understand the situations which are causing the morbid nutritional states, such as anemia and psychomotor developmental disorders28. These public health problems had the highest incidence in certain ages and contexts29.30.
Nearly one third of the children showed some degree of anemia, with moderate anemia being the most frequent. These figures may be reflecting the impact that COVID-19 is having on infant health services, as well as the lack of knowledge and nutritional habits of mothers, the adherence to food supplementation, or the limited efficiency of the iron food supplements and other micronutrients provided by the government1,9. This may be due to the interruption of the health services worldwide because of the COVID-19 pandemic, which caused the closing of first level health services (for the first 8 months of the pandemic in Peru), as well as the redistribution of resources towards the clinical assistance for COVID-19, which could have affected the follow up and treatment of childhood anemia. Moreover, the limited access to health services caused by the confinement restrictions and the worry about exposure to the virus made it difficult for families to access health services, which could have led to a small number of visits to children health services, including diagnosis and treatment of anemia.
The iron deficiency results coincide with those of diverse studies, which showed that mild and moderate anemia are the most frequent but differ in terms of frequencies. To this respect, Kazakhstan, Pivina et al.31 showed that more and 50% of children younger than 5 years of age presented with iron deficiency anemia; while Luciano et al.32 in Italy, found that close to 30% of one year old children had iron deficiency anemia. Also, Zhang et al.33 showed higher than 35% figures in China. However, Uganda Nampijja et al.23 reported that 75.8% and 47.1% of children from Uganda had mild and moderate anemia, respectively. In Peru, Burga25. revealed that over half of the children had either mild or moderate anemia, Gómez34 found that 59% had mild anemia and 41% had moderate anemia, Tume35 reported that 48% had moderate anemia and 35% had mild anemia, and Chura y Arestegui24 observed that 50% had moderate anemia and 35% had mild anemia. The reported iron deficiency figures may be affecting the cognitive, social, motor, language, and coordination growth and development of children22. This is the reason why the government health institutions must increase financial resources to strengthen strategies focused on prevention of iron deficiency anemia36,37.
The diverse proportions of anemia shown by the discussed studies could be related to the socioeconomic and cultural context where they were conducted, since they have demonstrated that this iron deficiency disorder is more common in rural and marginal urban areas as well as in poor and under 5 years old populations26,34. In addition, the problem may be exacerbated by the limited access to health services (nutritional guidance, preventive and therapeutic management of anemia, antiparasitic treatment, etc.) during the COVID-19 pandemic. The observed iron deficiency may also be the consequence of the lack of knowledge and inadequate nutritional practices provided by the mother, which affect the nutritional state and psychomotor development of the child38.
The observed higher frequency of the risk for psychomotor development may be associated with iron deficiency, since Farreras-Rozman39 has shown that this disorder leads to deficient myelination and neuronal deficit, which causes alterations in neurotransmitter function and future psychomotor developmental problems. In addition to causing changes in the homeostasis of neurotransmitter, iron deficiency also alters synaptogenesis and decreases basal ganglia functionin31.
The reported psychomotor development figures are significantly lower than those shown previously. Studies from Studies from Uganda23, Kazakhstan31, Italy32, and China33 showed that nearly one third of participating children had some degree of developmental delay. Likewise, in Peru, Rojas40 found that on average 62.5% of children were at risk in the developmental areas and global development which were evaluated. Tume35 reported a risk of 53% and an 8% of global developmental delay and an average of 36% in the areas of coordination, language and motor skills. Similarly, Burga25 identified an 8% risk, 2% of delay in global development, and a risk average of 18% for development of coordination and language. These figures alter the acquisition and organization of biopsychosocial abilities in children (neural maturation of the central nervous system and interaction with their environment), thereby limiting the progressive autonomy in the distinct areas of development15,16,41-43.
In reference to the relationship between anemia and psychomotor development, the findings and similar to those reported by Bravo26 y Chura24 who determined the relationship between anemia severity, developmental areas, and global development was not significant [p>0.05]. Likewise, the study by Nampijja et al.23 in Uganda did not find a significant relationship between iron deficiency anemia and the development of the language (p=0.22), motor skills (p=0.25), and social (p=0.67) areas. In contrast, these observations differ from findings from a Chinese study done by Zhang et al.33 in which a significant association was reported between variables (p=0.007); as well as in Peruvian studies from Gómez34, Tume35 y Burga25. who reported a statistically significant relationship (p<0.05) between three areas of development and iron deficiency anemia. This may be caused by the higher severity of anemia and the higher prevalence of risk and developmental delay in participating children, which shows that as anemia worsens it alters the process of psychomotor development42,44, causes nutritional disorders which leads to irreversible impacts on the central nervous system (oligodendrocytes require iron to synthesize fatty acids and cholesterol, which are essential for myelination and fast neuronal response to stimuli)28,40 and affect the neurolinguistic functions of the child43.
Finally, the government policies must be focused not only in health services to counteract anemia and developmental delays through iron supplements and early intervention for development, but the multicausal problems that this represents must also be considered since once present in the child, they will lead to short-term and long-term developmental problems. This is why strategies in the first level of health intervention that are focused on addressing the multicausal factors such as: lack of iron supplements, low adherence to supplementation programs, shortage of effective nutritional guidance, inadequate therapeutic management of anemia, non-existent or scare early stimulation and early intervention programs, etc.
Conclusions
Moderate anemia was the most frequent. The risk for psychomotor development was the more common developmental disorder. There is no statistically significant relationship between iron deficiency anemia and psychomotor development in the coordination, language, and motor skills areas as well as in global development. The strengthening of intervention strategies in first level health services would help social agencies to reduce iron deficiency anemia and psychomotor development disorders. The identification of social, demographic, economic, cultural and environmental factors that are associated with iron deficiency and children developmental disorders is required.