A Centre for Healthy Brain Ageing (CHeBA) study provides compelling evidence for clinical practice to direct efforts toward preventing white matter damage in individuals with hypertension, to protect against cognitive decline and dementia.
High blood pressure has a negative effect on many aspects of health and is also known to affect both the grey and white matter in the brain during the ageing process. Grey matter is where the brain cells exist, whereas white matter constitutes the network of nerve fibres that provides the communication connection between different areas of grey matter.
The study, led by Dr Jing Du and Associate Professor Wei Wen and published today in , found that compared with grey matter, white matter is more vulnerable to raised blood pressure.
Because grey matter has a greater amount of small blood vessels, and therefore a greater supply of blood compared to white matter, we wanted to see if white matter is more susceptible to damage from reduced blood flow caused by high blood pressure.
Dr Jing Du
Brain age is an emerging neuroimaging derived measure using deep learning techniques that has gained significant attention in recent years.
According to Associate Professor Wen, who is Leader of the Neuroimaging Group at CHeBA, brain age is calculated from MRI scans and is considered a powerful index for estimating the underlying biological health of brain tissues.
We applied advanced technology known as the 3D-CNN deep learning model to measure the grey matter and white matter brain ages separately.
Dr Jing Du
The researchers looked at brain scans from nearly 40,000 people with varying levels of blood pressure, ranging from normal to high. They found that as blood pressure increased, both grey and white matter showed signs of ageing, with white matter appearing to age faster.
The findings suggest that memory and thinking problems are more likely to occur as a result of high blood pressure’s impact on white matter, rather than grey matter.
The researchers also investigated how different aspects of blood pressure affect brain ageing. They found that systolic blood pressure had a linear relationship with both grey and white matter ageing – meaning as blood pressure increases, so does brain ageing. On the other hand, diastolic blood pressure had a U-shaped relationship, suggesting an optimal range for maintaining brain health.
The study suggests that white matter in the brain is particularly vulnerable to high blood pressure. To preserve brain health, it is crucial to keep blood pressure within an optimal range.
Managing blood pressure effectively could help protect against cognitive decline and future efforts should focus on monitoring and managing white matter health in people with high blood pressure.
Dr Jing Du