Relationship Between Blood Groups , Iron Deficiency Anemia and Helicobacter Pylori in Children.
- Conditions
- Relationship Between Blood Groups , Iron Deficiency Anemia and Helicobacter Pylori in Children
- Registration Number
- NCT05841433
- Lead Sponsor
- Assiut University
- Brief Summary
Iron-deficiency anemia (IDA) represents a global public health problem which has a significant impact on human health and social and economic development. Inadequate iron intake, chronic blood loss and impaired iron absorption are among the causes of IDA There are an association between H. pylori infection and IDA, but the biological explanation for H. pylori infection causing iron-deficiency anemia remains unknown. Initially, sideropenic anemia was considered to be caused by occult blood loss due to chronic superficial active gastritis caused by H. pylori, but subsequent studies did not confirm this theory . H. pylori infection can cause disorders in iron assimilation and increased iron requirements. Hypoacidity caused by pangastritis and a low level of ascorbic acid in the stomach of patients infected with H. pylori may affect the absorption of iron in the duodenum . In addition, levels of lactoferrin gastric mucosa (an iron-binding protein) are high in patients infected with iron-deficient H. pylori, showing a possible role between increased lactoferrin sequestration and iron utilization by the body . H. pylori also competes with the host for available food grade iron. H. pylori has several iron acquisition systems, which can capture iron available in the microenvironment of the stomach lumen . Moreover, there are studies that indicate that an iron-deficiency anemia which does not respond to iron therapy can be resolved by eradicating H. pylori from the stomach . ABO blood group seem to be looked into as risks for H. pylori related stomach malignancy, nevertheless, there are actually inconsistent scientific studies because of numerous confounding outcomes. Blood group antigens have the receptor properties for toxins, parasitic organisms and bacteria, exactly where this bacteria could assist in annexation or intrusion and avert multitude approval components .
- Detailed Description
Iron-deficiency anemia (IDA) represents a global public health problem which has a significant impact on human health and social and economic development. Inadequate iron intake, chronic blood loss and impaired iron absorption are among the causes of IDA There are an association between H. pylori infection and IDA, but the biological explanation for H. pylori infection causing iron-deficiency anemia remains unknown. Initially, sideropenic anemia was considered to be caused by occult blood loss due to chronic superficial active gastritis caused by H. pylori, but subsequent studies did not confirm this theory . H. pylori infection can cause disorders in iron assimilation and increased iron requirements. Hypoacidity caused by pangastritis and a low level of ascorbic acid in the stomach of patients infected with H. pylori may affect the absorption of iron in the duodenum . In addition, levels of lactoferrin gastric mucosa (an iron-binding protein) are high in patients infected with iron-deficient H. pylori, showing a possible role between increased lactoferrin sequestration and iron utilization by the body . H. pylori also competes with the host for available food grade iron. H. pylori has several iron acquisition systems, which can capture iron available in the microenvironment of the stomach lumen . Moreover, there are studies that indicate that an iron-deficiency anemia which does not respond to iron therapy can be resolved by eradicating H. pylori from the stomach . ABO blood group seem to be looked into as risks for H. pylori related stomach malignancy, nevertheless, there are actually inconsistent scientific studies because of numerous confounding outcomes. Blood group antigens have the receptor properties for toxins, parasitic organisms and bacteria, exactly where this bacteria could assist in annexation or intrusion and avert multitude approval components .
Recruitment & Eligibility
- Status
- NOT_YET_RECRUITING
- Sex
- All
- Target Recruitment
- 101
- Children from both sexes their ages ranged from 4-18 years.
- Children who are diagnosed to have H. Pylori infection.
- Children less than 4 years and more than 18 years.
- Children with chronic illnesses (e.g. CRF, CHF or chronic hemolytic anemias).
- Children who are receiving iron supplementation or multivitamins containing iron.
Study & Design
- Study Type
- OBSERVATIONAL
- Study Design
- Not specified
- Primary Outcome Measures
Name Time Method The incidence of seropositive helicopacter pylori infection and the frequencies of ABO blood groups and iron deficiency anemia in helicopacter pylori seropositive children. baseline by Lohman technique , height and weight were recorded for children without shoes and wearing light clothes, standing straight, with their weight uniformly distributed on both feet and their arms hanging freely on the sides. A digital scale (model 881; Seca, Hamburg, Germany).
Height measurements in centimeters. Body mass index (BMI) to age was obtained. Anemia was defined according to (WHO) age criteria; that is, hemoglobin level of \<11 g/dL (110 g/L) in children \<5 years, \<11.5 g/dL (115 g/L) in children with ages between 5 and 12 years and \<12 g/dL (120 g/L) for patients with ages between 12 and 18 years old. Serum ferritin level was measured using electro chemiluminescence (Elec Sys 2010 analyzer; Roche Diagnostics, Mannheim, Germany), and Serum iron level and total iron binding capacity (TIBC) were determined by CobasIntegra700 analyzer (Roche Diagnostics, Basel, Switzerland). Iron deficiency anemia (IDA) was defined as serum ferritin level of \<-2SD for age.
- Secondary Outcome Measures
Name Time Method
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