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Association between Coffee Consumption and Brain MRI Parameters in the Hamburg City Health Study

Despite the association of regular coffee consumption with fewer neurodegenerative diseases, it remains unclear how coffee is associated with pre-clinical brain pathologies such as lesions in the white matter, degeneration of the cortex, or alterations of the microstructural integrity. White matter hyperintensities (WMH) are hyperintense lesions on T2-weighted images and are associated with an increased risk for stroke and depression, cognitive deterioration, and gait disorders [13,14,15]. As a marker of cerebral small vessel disease (CSVD) and vascular brain damage, WMH can vary in the degree of expression, depending on the age and the presence of cardiovascular risk factors, e.g., smoking or hypertension [16,17,18]. Previous studies have reported diverging results on the association of consumed coffee with imaging markers of CSVD. They found either beneficial associations of coffee with lacunar infarcts [7], beneficial [19] or detrimental [20] associations with WMH volume, or no significant associations at all [21,22].

A recently developed and valid imaging marker of microstructural integrity is the peak width of skeletonized mean diffusivity (PSMD), calculated as the distribution of the mean diffusivity (MD) between the 5th and 95th percentile in the white matter skeleton [23]. Only one study analyzed the association of coffee consumption with microstructural integrity, as quantified by fractional anisotropy, with a higher coffee consumption being associated with higher integrity of the white matter microstructure [24].

Damage to the brain structure is not restricted to white matter, but also extents to the cortex, e.g., in the form of atrophy. Except for one study focusing on the quantification of cortical thickness in regions susceptible for Alzheimer’s Disease [22], the link between coffee consumption and cortical thickness was only indirectly examined by measuring total brain volume or grey matter volume, with incongruent results between studies [7, 21,25,26]. This study aimed at investigating whether coffee consumption is associated with multiple brain MRI markers of vascular brain damage and neurodegeneration, including WMH, PSMD, and cortical thickness in a large, population-based cohort.

Rare seasonal brain shrinkage in shrews is driven by water loss

Water cure: The study found that common shrews shrink their brains in winter not by losing cells, but by losing water.

Brain scans: The team used MRI scanning, the same technology used in hospitals, to peer inside the brains of live shrews across seasons.

What humans can learn: Brain shrinkage in humans is typically a sign of disease, like Alzheimer’s. But shrews can shrink their brain without compromising function or causing damage. Shrews could become a model system for exploring potential pathways for medica treatment of human brain disease.


Knowing how shrews loose brain volume over winter is the first step to understanding how they reverse this loss and regrow healthy brains in summer.

Brain.

Your Mother’s Germs May Have Influenced Your Brain’s Development

Our bodies are colonized by a teeming, ever-changing mass of microbes that help power countless biological processes. Now, a new study has identified how these microorganisms get to work shaping the brain before birth.

Researchers at Georgia State University studied newborn mice specifically bred in a germ-free environment to prevent any microbe colonization. Some of these mice were immediately placed with mothers with normal microbiota, which leads to microbes being transferred rapidly.

That gave the study authors a way to pinpoint just how early microbes begin influencing the developing brain. Their focus was on the paraventricular nucleus (PVN), a region of the hypothalamus tied to stress and social behavior, already known to be partly influenced by microbe activity in mice later in life.

Neuroscientists show for first time that precise timing of nerve signals determines how brain processes information

It has long been known that the brain preferentially processes information that we focus our attention on—a classic example is the so-called cocktail party effect.

“In an environment full of voices, music, and , the brain manages to concentrate on a single voice. The other noises are not objectively quieter, but are perceived less strongly at that moment,” explains brain researcher Dr. Eric Drebitz from the University of Bremen.

The brain focuses its processing on the information that is currently relevant—in this case, the voice of the conversation partner—while other signals are received but not forwarded and processed to the same extent.

Comprehensive molecular atlas of human hippocampus maps cell subtypes and organization

The hippocampus is an important brain region known to support various cognitive (i.e., mental) processes, including the encoding and retrieval of memories, learning, decision-making and the regulation of emotional states. While extensive research has tried to delineate the structure, functions and organization of the hippocampus, the cell types contained within it and their connections with other neurons have not yet been fully mapped out.

Over the past decades, available methods for studying cell subpopulations, the expressions of genes within them and their connectivity have become increasingly advanced. One of these methods, known as spatially resolved transcriptomics, works by measuring the expression of genes in cells while preserving their arrangement in space. Another called single-nucleus RNA-sequencing (snRNA-seq), allows scientists to examine RNA molecules inside individual cell nuclei to detect differences between them and categorize cells into different subtypes.

Researchers at Johns Hopkins Bloomberg School of Public Health, the Lieber Institute for Brain Development and Johns Hopkins School of Medicine recently used a combination of these two experimental techniques to examine cells in tissue extracted from the hippocampus. Their paper, published in Nature Neuroscience, introduces a comprehensive molecular atlas of the hippocampus that maps different cell subtypes and their organization.

Depression linked to presence of immune cells in the brain’s protective layer

Immune cells released from bone marrow in the skull in response to chronic stress and adversity could play a key role in symptoms of depression and anxiety, say researchers.

The discovery—found in a study in mice—sheds light on the role that inflammation can play in mood disorders and could help in the search for new treatments, in particular for those individuals for whom current treatments are ineffective.

Around 1 billion people will be diagnosed with a mood disorder such as or anxiety at some point in their life. While there may be many underlying causes, —when the body’s immune system stays active for a long time, even when there is no infection or injury to fight—has been linked to depression. This suggests that the immune system may play an important role in the development of mood disorders.

Exploring criminal behavior in patients with dementia

A suspected perpetrator who can barely remember his name, several traffic violations committed by a woman in her mid-fifties who is completely unreasonable and doesn’t understand her behavior—should such cases be brought before a court? And how does the state deal with people who commit acts of violence without meaning to?

Those questions come to mind if one hears those examples from everyday clinical praxis with persons suffering from . Neurodegenerative diseases might affect several functions of the brain, ranging from memory in Alzheimer’s disease to behavior, such as in behavioral variant frontotemporal dementia, and to sensorimotor function in Parkinson’s disease.

One of the most interesting consequences of these alterations is the fact that persons affected by these diseases might develop criminal risk behavior like harassment, traffic violation, theft or even behavior causing harm to other people or animals, even as the first disease sign.

Teenager with hyperthymesia exhibits extraordinary mental time travel abilities

Scientists in France have documented the case of a teenager with extraordinary autobiographical memory. She can vividly reexperience past events and imagine future ones in detail, highlighting a rare form of mental time travel and emotional memory organization.

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