Ignite Creation Date:
2025-12-24 @ 2:39 AM
Ignite Modification Date:
2025-12-24 @ 2:39 AM
Study NCT ID:
NCT07292493
Status:
ENROLLING_BY_INVITATION
Last Update Posted:
2025-12-18
First Post:
2025-11-19
Is Possible Gene Therapy:
False
Has Adverse Events:
False
Brief Title:
Immune System in Diabetic Kidney Disease
Sponsor:
University Medical Centre Ljubljana
Organization:
Study Overview
Official Title:
The Role of Complement in Diabetic Kidney Disease
Status:
ENROLLING_BY_INVITATION
Status Verified Date:
2025-11
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
KID-CODE
Brief Summary:
Diabetes is a chronic condition marked by long-term elevated blood glucose levels. There are more types of diabetes; the majority of patients have type 1 or type 2 diabetes. Over long period of time, high blood sugar damages blood vessels and organs. One of the most common complications is diabetic kidney disease, which can slowly lead to kidney failure. People with this condition also have a much higher risk of heart and blood vessel diseases.
Newer research shows that the immune system, especially the complement system (a group of proteins that help defend the body), may also play a role in worsening kidney disease in diabetes. High blood sugar can activate these proteins, and they have been found in kidney tissue of patients with diabetic kidney disease.
The goal of this study is to find out how much the complement system contributes to kidney damage in diabetes, whether it affects different groups of patients differently, and whether it is linked to blood vessel health or the stage of kidney disease. The study will also assess if improved diabetes control is linked to reduced complement system activity.
Newer research shows that the immune system, especially the complement system (a group of proteins that help defend the body), may also play a role in worsening kidney disease in diabetes. High blood sugar can activate these proteins, and they have been found in kidney tissue of patients with diabetic kidney disease.
The goal of this study is to find out how much the complement system contributes to kidney damage in diabetes, whether it affects different groups of patients differently, and whether it is linked to blood vessel health or the stage of kidney disease. The study will also assess if improved diabetes control is linked to reduced complement system activity.
Detailed Description:
Diabetes is a chronic disease characterized by long-term elevated blood glucose levels. Several types of diabetes are known, with most affected individuals having type 1 or type 2 diabetes. Long-term elevation of blood glucose affects various organs in the body, a condition referred to as chronic complications of diabetes. Since elevated blood glucose damages both small and large blood vessels, complications are classified as microvascular (damage to small vessels) and macrovascular (damage to large vessels). Diabetic kidney disease is the main microvascular complication in both type 1 and type 2 diabetes and is also the leading cause of kidney failure.
Changes in the kidneys develop over many years. Gradual deterioration of kidney function is monitored using laboratory parameters. Along with declining kidney function, blood pressure also increases, and cardiovascular diseases begin to develop- the risk of these rises exponentially with worsening kidney function. Cardiovascular diseases represent the leading cause of mortality among people with diabetes.
Traditionally, diabetic kidney disease was considered as non-inflammatory condition. Its development was attributed to impaired glucose metabolism and elevated blood pressure. Consequently, achieving optimal blood glucose and blood pressure values has been regarded as key to preventing chronic complications. However, diabetes itself represents an additional risk factor for cardiovascular disease compared with individuals without diabetes. Thus, individuals with diabetic kidney disease are even more prone to cardiovascular events. In these patients it is especially important to follow treatment guidelines and to treat elevated blood glucose and blood pressure as intensively as possible. For individuals with diabetic kidney disease, medications from the group of angiotensin-converting enzyme inhibitors or angiotensin receptor blockers are prescribed for the treatment of high blood pressure. Both medication groups also have a protective effect on the kidneys and slow the decline of kidney function. Angiotensin is a substance in the body responsible for raising blood pressure-when its action is inhibited, blood pressure decreases.
The investigators now know that inflammation and the immune system also play a role in the development of chronic diabetic complications. The complement system (a group of proteins in the blood involved in immune responses) is becoming recognized for its importance. Current studies do not suggest that the complement system plays a key role in the onset of the disease; however, its role in the progression of diabetic kidney disease and possibly in the occurrence of different forms of the disease has become evident. Hyperglycaemia increases the activity of certain complement proteins and activates specific pathways, while the hyperglycaemic environment also impairs the regulation of some proteins. Kidney biopsies of individuals with diabetic kidney disease have shown the presence of complement proteins in kidney tissue, and gene expression analyses have identified activation of complement-related genes.
The purpose of this study is to determine whether and to what extent activation of the complement system contributes to diabetic kidney disease and to define potential differences among different groups of individuals with diabetes. Additionally, the investigators aim to determine whether there is a connection between complement system activation and arterial function, as well as between complement system activation and the stage of kidney disease. The investigators will also investigate whether diabetes control influences complement system activation and whether previous kidney biopsy findings correspond with laboratory results.
Changes in the kidneys develop over many years. Gradual deterioration of kidney function is monitored using laboratory parameters. Along with declining kidney function, blood pressure also increases, and cardiovascular diseases begin to develop- the risk of these rises exponentially with worsening kidney function. Cardiovascular diseases represent the leading cause of mortality among people with diabetes.
Traditionally, diabetic kidney disease was considered as non-inflammatory condition. Its development was attributed to impaired glucose metabolism and elevated blood pressure. Consequently, achieving optimal blood glucose and blood pressure values has been regarded as key to preventing chronic complications. However, diabetes itself represents an additional risk factor for cardiovascular disease compared with individuals without diabetes. Thus, individuals with diabetic kidney disease are even more prone to cardiovascular events. In these patients it is especially important to follow treatment guidelines and to treat elevated blood glucose and blood pressure as intensively as possible. For individuals with diabetic kidney disease, medications from the group of angiotensin-converting enzyme inhibitors or angiotensin receptor blockers are prescribed for the treatment of high blood pressure. Both medication groups also have a protective effect on the kidneys and slow the decline of kidney function. Angiotensin is a substance in the body responsible for raising blood pressure-when its action is inhibited, blood pressure decreases.
The investigators now know that inflammation and the immune system also play a role in the development of chronic diabetic complications. The complement system (a group of proteins in the blood involved in immune responses) is becoming recognized for its importance. Current studies do not suggest that the complement system plays a key role in the onset of the disease; however, its role in the progression of diabetic kidney disease and possibly in the occurrence of different forms of the disease has become evident. Hyperglycaemia increases the activity of certain complement proteins and activates specific pathways, while the hyperglycaemic environment also impairs the regulation of some proteins. Kidney biopsies of individuals with diabetic kidney disease have shown the presence of complement proteins in kidney tissue, and gene expression analyses have identified activation of complement-related genes.
The purpose of this study is to determine whether and to what extent activation of the complement system contributes to diabetic kidney disease and to define potential differences among different groups of individuals with diabetes. Additionally, the investigators aim to determine whether there is a connection between complement system activation and arterial function, as well as between complement system activation and the stage of kidney disease. The investigators will also investigate whether diabetes control influences complement system activation and whether previous kidney biopsy findings correspond with laboratory results.
Study Oversight
Has Oversight DMC:
False
Is a FDA Regulated Drug?:
None
Is a FDA Regulated Device?:
None
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
None
Is an FDA AA801 Violation?: