- Researchers investigated the link between metabolic profile and brain health.
- Factors such as high blood pressure and high basic metabolic rate (BMR) were linked to worse brain health.
- The researchers noted that further studies are needed to determine causation.
According to the World Health Organization, over
Investigating the link between metabolic risk factors and dementia could aid preventative approaches based on metabolic risk profiles.
Recently, researchers investigated the link between metabolic biomarkers and brain health, captured via brain imaging data.
They found that metabolic profiles are linked to neuroimaging characteristics that indicate cognitive decline and increased dementia risk.
The study was published in
For the study, the researchers analyzed data from 26,239 individuals from the U.K. Biobank who were free from dementia and stroke at recruitment. The participants were aged between 37 and 73 years old at recruitment and 52% were female.
The researchers examined the participants’ brain MRI data, including:
- total brain volume (TBV)
- grey matter volume (GMV)
- white matter hyperintensity (WMH) volume
- hippocampal volume (HV)
- iron deposition
Meanwhile, greater iron deposition has been linked to a greater risk for Alzheimer’s disease, which is the most common form of dementia. Reduced HV is also linked to poorer memory, verbal learning, processing speed, and executive function.
The researchers assessed brain imaging along a number of biomarkers, including:
- cholesterol levels
- levels of inflammation
- kidney function
- liver function
- Body Mass Index (BMI)
- Basic Metabolic Rate (BMR)—the number of calories burned while at rest
- blood pressure
- 25(OH)D levels, which is a measure of vitamin D
They found that younger age, higher education level, never having been a smoker, a greater number of working hours, and a higher level of physical exercise were linked to a greater HV and fewer brain lesions.
They also noted that iron deposition levels tended to increase with age and were higher among those smokers and ex-smokers, those with a higher level of education, more working hours, and higher levels of strenuous exercise.
When asked how iron builds up in the brain, Amanda Lumsden, Ph.D., a research fellow in clinical and health sciences at the University of South Australia (UniSA), one of the study’s authors, told Medical News Today:
“We don’t really know why [iron] builds up or whether it causes dementia. Iron is the most abundant metal in our body and is vital for the production of energy, neurotransmitters and myelin, oxygen transport, and many other fundamental processes. Because of its importance, too little can be detrimental. On the other hand, too much [iron] can be toxic to cells (such as neurons), and since brain iron accumulation has been linked to Alzheimer’s disease and several other neurodegenerative disorders, it is thought that iron accumulation may play a role in neurodegeneration.”
In addition, the researchers further found that high triglycerides, high BMI, poor liver and kidney function, and high levels of inflammation were linked to the most adverse brain outcomes.
High triglycerides and liver dysfunction, in particular, were linked to the highest levels of iron deposition, brain lesions, and GMV loss.
The researchers noted that higher BMR was linked to more iron deposition, lower GMV, and lower HV than obesity.
They also noted that lower vitamin D levels were linked to more brain lesions and lower TBV and GMV.
When asked how iron builds up in the brain, Dr. Russel H. Swerdlow, director at the University of Kansas Alzheimer’s Disease Research Center, University of Kansas School of Medicine, who was not involved in the study, told MNT:
“[The brain needs iron] to build certain structures called ‘respiratory chain enzymes’ [proteins that play a role in cell metabolism] which are defective in Alzheimer’s. If one can’t properly form their respiratory chain enzymes, iron levels will begin to rise.”
Dr. Mikhail Kolonin, professor and director at the Center for Metabolic and Degenerative Diseases at The University of Texas, who was also not involved in the study, added:
“Normally, the blood–brain barrier (BBB) limits iron access to brain cells. Recurrent microbleeds may be one explanation for increased iron accumulation occurring in older age. However, chronic aging-associated metabolic and inflammatory dysfunction jeopardizing [cells that form the BBB], which results in increased brain iron entry, may be more important.”
“Iron accumulation, oxidative damage [from excessive iron accumulation] further promotes cell death, the processes underlying all neurodegenerative diseases.”
— Dr. Mikhail Kolonin
The researchers noted that most of their findings are in line with
“Basal metabolic rate decreases with age, and athletes are known to have a significantly higher basal metabolism, which makes the study’s findings counterintuitive. It is apparent that basal metabolic rate may be modulated by both health-promoting and pathogenic processes,” he said.
“Further research will be needed to identify markers more selectively predicting the risk of neurophysiological dysfunction,” he added.
The researchers noted that while BMR is essential for neuronal function, higher BMR may promote oxidative stress if not adequately counterbalanced by antioxidants in the body. They agreed, however, that further studies are needed to explore this link.
The researchers concluded that metabolic markers such as BMR and BP might provide valuable insights into the development of dementia.
When asked about the study’s limitations, Dr. Kolonin said:
“One of its limitations is the exclusion of individuals with a history of dementia or stroke. One could expect useful clinical information from a separate analysis including this group. Another issue is that the U.K. Biobank cohort may not reflect the general population because it is limited to participants of white British ancestry and is subject to healthy volunteer bias. Therefore, these findings need to be re-assessed in independent datasets containing other ethnic and socioeconomic groups.”
Dr. Swerlow added that while the study found a link between metabolic measures and brain imaging data suggestive of cognitive impairment, it did not address causation.
“The best way to maintain a healthy metabolism is to avoid excess weight accumulation through a healthy diet and physical activity. Indeed, exercise is perhaps the most effective approach to the prevention of Alzheimer’s disease,” said Dr. Kolonin.
“The mechanisms of its effect are not completely understood. However, they are likely to involve the reduction of blood glucose levels and normalization of vascular function. This possibly leads to improvement of the BBB, [and thus a decreased] risk of vascular dementia and other neurodegenerative diseases,” he added.
Dr. Swerdlow agreed that a healthy lifestyle is key to improving metabolic health. He said: “Things like constantly overeating, a sedentary lifestyle, smoking, walking around with uncontrolled hypertension, and things of that ilk certainly seem to have a negative impact on metabolism.”
“While there is still an ongoing debate, tantalizing data—including some generated at our Alzheimer’s Disease Research Center—suggest doing things that benefit metabolism, and avoiding things that hurt metabolism, may lower one’s dementia risk.”
— Dr. Russel H. Swerdlow