The brains of healthy people aged faster during the COVID-19 pandemic than did the brains of people analysed before the pandemic began, a study of almost 1,000 people suggests. The accelerated ageing occurred even in people who didn’t become infected.

The accelerated ageing, recorded as structural changes seen in brain scans, was most noticeable in older people, male participants and those from disadvantaged backgrounds. But cognitive tests revealed that mental agility declined only in participants who picked up a case of COVID-19, suggesting that faster brain ageing doesn’t necessarily translate into impaired thinking and memory.

The study “really underlines how significant the pandemic environment was for mental and neurological health”, says Mahdi Moqri, a computational biologist who studies ageing at Harvard Medical School in Boston, Massachusetts. It’s unclear whether the pandemic-associated brain ageing is reversible, because the study analysed scans taken at only two time points, adds Moqri...

COVID-19 is leaving all kinds of legacies on our health, both on our bodies and our brains. In a study published July 22 in Nature Communications, researchers report that living through the pandemic aged our brains—whether or not you were infected with COVID-19.

To investigate COVID-19's impact on the brain, researchers looked at brain scans from 1,000 people during and before the pandemic. They compared these to brain scans from other people taken during "normal" times as a model for typical brain aging.
​
Led by Ali-Reza Mohammadi-Nejad from the University of Nottingham School of Medicine in the U.K., the researchers looked at measures like brain function, gray and white matter volume, a person's cognitive skills, and their chronological age. Gray matter is critical for memory, emotions, and movement, while white matter is essential for helping nerves transmit electrical signals.

The pandemic-era brains aged about 5.5 months faster compared to the brains of those studied before the pandemic. The accelerated aging was documented in people who had COVID-19 infections as well as those who didn’t, which strongly suggests that pandemic-related factors other than biological or virus-driven ones—like high stress—were also at work. In fact, the changes in gray and white matter were similar in people who were and were not infected...

Coronavirus disease 2019 (COVID-19) is predominantly an acute respiratory disease caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and remains a significant threat to public health. COVID-19 is accompanied by neurological symptoms and cognitive decline, but the molecular mechanisms underlying this effect remain unclear. As aging induces distinct molecular signatures in the brain associated with cognitive decline in healthy populations, we hypothesized that COVID-19 may induce molecular signatures of aging. Here, we performed whole transcriptomic analysis of human frontal cortex, a critical area for cognitive function, in 12 COVID-19 cases and age- and sex-matched uninfected controls. COVID-19 induces profound changes in gene expression, despite the absence of detectable virus in brain tissue. Pathway analysis shows downregulation of genes involved in synaptic function and cognition and upregulation of genes involved in immune processes. Comparison with five independent transcriptomic datasets of aging human frontal cortex reveals striking similarities between aged individuals and severe COVID-19 patients. Critically, individuals below 65 years of age exhibit profound transcriptomic changes not observed among older individuals in our patient cohort. Our data indicate that severe COVID-19 induces molecular signatures of aging in the human brain and emphasize the value of neurological follow-up in recovered individuals...

Coronavirus disease 2019 (COVID-19) is predominantly an acute respiratory disease caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and remains a significant threat to public health. COVID-19 is accompanied by neurological symptoms and cognitive decline, but the molecular mechanisms underlying this effect remain unclear. As aging induces distinct molecular signatures in the brain associated with cognitive decline in healthy populations, we hypothesized that COVID-19 may induce molecular signatures of aging. Here, we performed whole transcriptomic analysis of human frontal cortex, a critical area for cognitive function, in 12 COVID-19 cases and age- and sex-matched uninfected controls. COVID-19 induces profound changes in gene expression, despite the absence of detectable virus in brain tissue. Pathway analysis shows downregulation of genes involved in synaptic function and cognition and upregulation of genes involved in immune processes. Comparison with five independent transcriptomic datasets of aging human frontal cortex reveals striking similarities between aged individuals and severe COVID-19 patients. Critically, individuals below 65 years of age exhibit profound transcriptomic changes not observed among older individuals in our patient cohort. Our data indicate that severe COVID-19 induces molecular signatures of aging in the human brain and emphasize the value of neurological follow-up in recovered individuals...

Aging is a major risk factor for the development of cognitive deficits and neurodegenerative diseases. Although the molecular changes in the brain upon COVID-19 cannot be readily assessed in recovered individuals, our data herein suggest that severe COVID-19 induces premature aging in the human brain, particularly among younger individuals. Together with previously reported residual cognitive deficits observed in recovered COVID-19 individuals, our results imply that increased long-term rates of cognitive decline and neurodegenerative disorders may be observed among COVID-19 patients as a consequence of long COVID. In light of this possibility, we advocate for neurological follow-up of recovered COVID-19 patients and suggest potential clinical value in modifying risk factors to reduce the risk or delay the development of aging-related neurological pathologies such as dementia...