Overview
People with diabetes are at increased risk of developing dementia, including Alzheimer's disease and vascular dementia. In addition, persons with diabetes have more pronounced age-related brain atrophy and cognitive difficulties compared to people without diabetes. The mechanisms behind the effects on the brain of diabetes are still unclear. New research suggests that the brains of some people with diabetes do not respond normally to insulin signals, a condition known as brain insulin resistance (BIR). To date, there have been no large clinical studies investigating BIR and its impact on brain health, but several smaller studies suggest that BIR may be a cause of cognitive decline and impaired brain health in people with diabetes. Another mechanism that may contribute to impaired brain health in people with diabetes is damage to the blood vessels in the brain. Damage to blood vessels is a well-known complication of diabetes, but how it affects the brain is not fully described. In this project, we will investigate the relationship between BIR and brain blood vessel dysfunction and its relationship to cognition and brain function. This is done by examining patients with type 1 diabetes (T1D), type 2 diabetes (T2D) and healthy controls. The participants will undergo MRI brain scans to assess the impact of BIR on the brain physiology and to evaluate brain blood vessel health. Participants will undergo comprehensive assessments of their cognitive abilities and thorough health examination.
Description
The BIR-BrainHealth project investigates the role of brain insulin resistance (BIR) as a key mechanism linking diabetes to cognitive decline and dementia risk. By combining cognitive testing with advanced neuroimaging (MRI and PET), metabolic profiling, and multi-omics analyses, the study aims to uncover how BIR affects brain physiology, energy metabolism, and neurovascular function. The present trial registration specifically covers the MRI components of the project and does not include PET imaging.
Diabetes significantly increases the risk of mild cognitive impairment and dementia. The exact link between diabetes and cognitive decline is yet to be fully understood. Early cognitive decline in diabetes suggests a unique pathogenetic trajectory. One hypothesized mechanism involves impaired insulin signaling/transport in the brain, referred to as brain insulin resistance (BIR). Evidence indicates that in some individuals with diabetes, neuronal insulin signaling is abnormal, resulting in dysregulated cerebral metabolism and function. Another possible pathway is cerebrovascular pathology, which may compromise cerebral perfusion and energy metabolism. The present project will investigate the relationship between BIR and cerebrovascular dysfunction, and their impact on cognition and brain function.
We will set up a multicenter study in Denmark and Germany. Initially the study will include 50 participants with type 1 diabetes, 50 participants with type 2 diabetes, and 50 control participants without diabetes. All participants will undergo a comprehensive clinical evaluation to characterize diabetes duration, severity, and systemic comorbidities. The cognitive performance of the participants will be assessed using a neuropsychological test battery of following standardized tests:
- Rey Auditory Verbal Learning Test (RAVLT)
- Trail Making Test (TMT) part A and B
- Symbol Digit Modalities Test (SDMT)
- RBANS Digit Span forward (Version A)
- Wechsler Adult Intelligence Scale III Letter-Number Sequencing test (WAIS-LNS)
- Verbal Fluency test (phonetic and semantic)
- Grooved Pegboard
- Rapid Visual Processing (RVP) test from the Cambridge Neuropsychological Test Automated Battery (CANTAB) using A' (RVP-A) and mean latency for correct responses
- The Montreal Cognitive Assessment (MoCA)
Tests will be grouped by cognitive domains, and each domain score is calculated as the mean of the individual component z-scores. A cognitive composite (global score) will be derived from the mean of the domains: learning and memory, executive function and working memory, processing speed, and attention.
Magnetic resonance imaging (MRI) will be performed to assess BIR and structural brain changes, including atrophy. All MRI-scans will be performed on a research-optimized 3 Tesla MRI scanner. BIR will be evaluated by measuring changes in cerebral perfusion from administration of intranasal insulin delivered via nasal spray.
Blood, urine and stool will be collected for biomarker development and characterization of patients with BIR. A multi-omics approach will be applied to identify reliable biomarkers of BIR, incorporating lipidomics, metabolomics, proteomics, and transcriptomics. Lipidomic analysis will quantify approximately 650 lipid species, including phospholipids, lysophos-pholipids, ceramides, sphingolipids, diacylglycerols, and triacylglycerols, using liquid chromatography-mass spectrometry. Metabolomic profiling will measure approximately 300 metabolites, including citric acid cycle intermediates, short-chain fatty acids, ketones, and amino acids, using gas chromatography-mass spectrometry. Proteomic analysis will be conducted using a validated, clinically applicable mass spectrometry method, and transcriptomic profiling will be performed using RNA-based methods. The participants will be genotyped using the Illumina Infinium Global Screening Array (GSA v2.4), with exclusion of rare variants and clinically relevant mutations listed by the American College of Medical Genetics, in accordance with the guidelines of the National Science Ethics Committee on genomic research.
A subset of participants will undergo additional advanced MRI-scanning for assessments of cerebro-vascular function. Brain perfusion, blood-brain barrier integrity, and capillary perfusion distribution will be measured using dynamic contrast-enhanced MRI. Cerebrovascular reactivity will be measured by perfusion-weighted MRI during inhalation of air enriched with 5% CO2, a potent cerebral vasodilator. Cerebral blood flow responses to neuronal activation induced by visual stimulation will be assessed using perfusion-weighted MRI. Lastly, in a subset of participants the brain glucose sensing will be assessed using functional MRI (fMRI). fMRI will be measured prior to, during and following oral ingestion of water containing 75 grams of glucose. The glucose drink is given through a straw while the participants are lying in the scanner and will be consumed over a period of 5 minutes. Blood samples will be collected throughout the scan for measurements of blood glucose.
Eligibility
Inclusion Criteria (all):
- age 50-80 years
Inclusion Criteria (diabetes only):
- Diagnosis of either type 1 diabetes or type 2 diabetes
- Diabetes duration of ≥10 years for individuals with type 1 diabetes and ≥5 years for individuals with type 2 diabetes
Exclusion Criteria:
- HbA1c \>100 mmol/mol
- Other type of diabetes
- Weight \>140 Kg
- Treatment with drugs that cannot be paused for 12 hours
- Diagnosis of dementia
- Active and recent (1year) malignant disease
- History of major stroke
- Major depression and/or treatment with antipsychotics
- History of traumatic brain injury
- Other medical condition or disorder (e.g., epilepsy, recent concussion) that in the opinion of the investigator precludes compliance with the protocol, evaluation of the results or represent an unacceptable risk for the participant's safety.
- Inability to perform neuropsychological tests (e.g., severe vision and hearing impairment that cannot be improved with aids such as glasses and hearing aids, or language barrier.)
- Severe claustrophobia
- Foreign bodies of metal in the body which prohibits brain MRI scans (e.g. pacemaker or screws/plates from surgery in the head or neck region)
- Participants who do not wish to be informed about accidental findings by MRI
- eGFR measurement \<45 within 3 months of study visit