Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT05874323 |
| Other study ID # |
IDE00296 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
January 1, 2023 |
| Est. completion date |
May 10, 2023 |
Study information
| Verified date |
August 2023 |
| Source |
Future University in Egypt |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Type I Diabetes Mellitus (TIDM) is a chronic metabolic disorder caused by the immune-mediated
T-cell and macrophages that typically affects insulin-producing β-cells of Langerhans leading
to cell destruction and absolute insulin deficiency. This study aimed to investigate the
correlation of RAGE gene polymorphism rs1800625 with the incidence of type I diabetes
mellitus in the Egyptian patients with the activity and the severity of the disease and to
assess their association with inflammatory reactions in TIDM patients (IL-6, TNF-α). Also,
this study investigated the relation between MiRNA-34, MiRNA-146, to TID severity and
activity
Description:
Type I diabetes mellitus (TIDM) is also called autoimmune diabetes, juvenile-onset or
insulin-dependent diabetes mellitus . It is representing 10% of diabetes cases, estimated
that most of these patients are less than 15 years old. The pathophysiology of TIDM is a
complex and available data proposed the important cause for this disease such as autoimmune
disease and some genetic factors TIDM is a chronic disease caused by the immune-mediated
T-cell and macrophages attack on insulin-producing β-cells of Langerhans leading to cell
destruction and absolute insulin deficiency. This will produce high blood sugar
(hyperglycemia) and change in the proteins and lipids metabolism TIDM is usually
characterized by the presence of anti-glutamic acid decarboxylase, islet of β-cell or insulin
antibodies which identify the autoimmune processes, leads to β-cell destruction .
Type I diabetes mellitus is account for only a minority of the total burden of diabetes in a
population, however it is considered the major type of diabetes in younger age .
Treatment of TIDM is more complex than other types of diabetes, as it cannot be regulated
only by dietary interventions, as it is usually accompanied by severe complications, and has
extreme variability due to the diverse ages of diagnosis. Primary treatment for TIDM include
immune-suppressive drugs and continuous exogenous insulin that cover the primary
pathophysiology of TIDM Currently, diabetes mellitus is diagnosed when hemoglobin A1C (HbA1c)
is ≥6.5% or fasting plasma glucose (FPG) is ≥ 126 mg/dl or 2 hour postprandial plasma glucose
is ≥ 200 mg/dl during an oral glucose tolerance test or a random plasma glucose is ≥ 200
mg/dl plus symptoms of diabetes .
Advanced glycation end products (AGEs) Advanced glycation end products (AGEs) are defined as
a heterogeneous group of irreversibly reactive derivatives. They are formed by non-enzymatic
glycation with tissue proteins, and shown to accumulate on long-lived proteins in diabetes
mellitus . They generate oxidative stress and induce inflammation and they have been tied to
be a factor in the development an unfavorable pro-inflammatory state implicated in many
degenerative diseases, such as autoimmune diseases, diabetes, atherosclerosis, chronic renal
failure, metabolic syndrome and its complications, and neurological diseases such as
Alzheimer's disease, cardiovascular diseases (Kuzan and Aleksandra 2021). These harmful
compounds can affect every type of cell in the body and are thought to be one factor in some
age-related chronic diseases. Receptor for advanced glycation end products (RAGE) is a
multi-ligand cell surface receptor that belongs to the immunoglobulin superfamily. RAGE
activation by various ligands have been reported to induce LDL deposition, resulting in foam
cell formation . Furthermore, it increase oxidative stress generation and subsequently
increase inflammatory, proliferative, angiogenic, fibrotic, thrombogenic, and apoptotic
reactions in numerous cell types via activation of many intracellular signaling pathways such
as nuclear factor-κB (NF-κB) . RAGE expression is usually low in the majority of healthy
adult tissues, but its levels are elevated under pathological conditions such as diabetes .
RAGE is a highly polymorphic gene, with around ten polymorphisms being predominantly studied.
The genetic variations of RAGE should be considered as responsible for the development of
many diseases (Serveaux et al., 2019). In addition, combining RAGE-circulating protein levels
and RAGE polymorphisms may be used as a useful clinical tool to predict risk of vascular
diseases. Indeed, sRAGE could be a valuable biomarker in many pathological states. It
increases in patients with decreased renal function, and decreases in diabetic complications
and coronary artery disease, but also elevated levels of sRAGE are often associated with
end-stage disease . The genetic background of RAGE demonstrated that some gene polymorphisms
are implicated in various pathological states, for example, diabetes complications,
amplification of the inflammatory response, gastric cancer, and breast cancer . Recently,
five main RAGE polymorphisms described (rs2070600, rs1800624, rs184003, and a 63 bp deletion)
were not associated with either type 1 or type 2 diabetes . In this study, we focused on the
principal RAGE polymorphism (rs1800625) and their potential pathological effect depending on
the study of the Egyptian population with TIDM.
Rs1800625 Polymorphism The rs1800625 SNP (- 429 T > C) located in the upstream region and was
found to increase the transcription of RAGE around twofold in vitro and so increase the RAGE
expression, which might influence the pathogenesis of many diseases such as autoimmune and
inflammatory diseases (Ahuja el al., 2022). In the presence of rs1800625 polymorphism, it is
not only a higher expression of sRAGE but also, there is an increase of AGEs. Studies on
different pathologies (inflammatory disease, cancer, coronary artery disease, lung disease,
and myocardial infarction) focused on rs1800625, but with conflicting results. However the
rs1800625 SNP was studied in different types of cancer but founded to be not involved in the
pathogenesis of pancreatic cancer like RAGE is implicated There were numerous studies of SNP
rs1800625 in diabetic patients, but with conflicting results. The rs1800625 SNP was
significantly increased in type 2 diabetes subjects with retinopathy, compared to those
without . Many studies demonstrated a correlation between rs1800625 polymorphism and diabetic
complications. The rs1800625 and rs3134940 were founded to be increase (+65%) the risk of
developing diabetic nephropathy and was associated with its early onset. The rs1800625 SNP
was also associated with the development of insulin resistance, and in a Brazilian population
there was a two-fold increase in the incidence of rs1800625 when subjects were diabetic. An
analysis in infants with type I diabetes from the Finn Diane cohort reported that rs1800625
was more prevalent in type I diabetic patients than in controls . In diabetic subjects,
rs1800625 was associated with higher HbA1c levels, with an increased incidence of type 1
diabetes.
The association of rs1800625 with cardiovascular risk has been evaluated, with again
controversial results. The rs1800625 was associated with higher levels of circulating form of
(RAGE) and an increased risk of developing coronary artery disease, especially in diabetic
patients
