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Photos of the Week Series: May 11, 2018

Associate Photo Editor Kristen McNicholas is responsible for looking at daily uploads so she has the first set of eyes on every image that the Your Shot community shares. She starts each day looking through thousands of photographs and this series will be a selection of her favorites from the past week. Each Friday she will be sharing her favorites here!

I have the privilege of guest curating Kristen’s Photos of the Week series this week (May 4-10, 2018). It was a lot of fun. Because Your Shot is a global community representing 195 countries, I love the concept that this series features moments from around the world — including Your Shot photographer and new father Wayne Muller introducing us to his daughter, Samara Blake Muller, who was born this past week on May 7, 2018. Congratulations Wayne.

To play off this concept, what I did was put 10 favorite shared memories from you in chronological order of being uploaded to Your Shot:

May 4, 2018: A Thousand Blue Bubbles | Photograph by Ceresi Claudio

May 5, 2018: Meeting Austin | Photograph by Meg Brock

May 5, 2018: Constant Raining Season | Photograph by Qian Wang

May 6, 2018: Zac Versus the Volcano | Photograph by Ian Plant

May 7, 2018: Family in Ritual | Photograph by Lopamudra Talukdar

May 7, 2018: Pony Portrait | Photograph by Maria Weber

May 8, 2018: Hello World | Photograph by Wayne Muller

May 9, 2018: Window Box | Photograph by Nguyen N.

May 10, 2018: Get Ready! | Photograph by Antonio Leong

May 10, 2018: Sleeping Giant | Photograph by Felix Inden

(Image caption: Cerebrospinal fluid exits the brain along cranial nerves (shown here in yellow), such as the optic and olfactory nerves, to reach the lymphatic system. Visualisation: Springer Medizin / Science Photo Library)

Exit through the lymphatic system

Our brain swims. It is fully immersed in an aqueous liquid known as cerebrospinal fluid. Every day, the human body produces about half a litre of new cerebrospinal fluid in the cerebral ventricles; this liquid originates from the blood. This same quantity then has to exit the cranial cavity again every day. Researchers in the group led by Michael Detmar, Professor of Pharmacogenomics, have now published a study showing that in mice, the cerebrospinal fluid exits the cranial cavity through the lymph vessels. The ETH researchers have thus identified another central role played by the lymphatic system, and refuted a decades-old dogma. The scientists have published their findings in the latest issue of the scientific journal Nature Communications.

Past research has inadequately explained how cerebrospinal fluid exits the cranial cavity. Scientists knew that two paths were available – blood vessels (veins) and lymphatic vessels, but for a long time, and due due to insufficient research tools, they had assumed that drainage through the veins was by far the predominant pathway.

Rewriting the anatomy textbooks

The researchers led by Steven Proulx, Senior Scientist in Detmar’s group, have now been able to refute this assumption. They injected tiny fluorescent dye molecules into the ventricles (cavities) of the brain in mice and observed how these molecules exited the cranial cavity. They used a sensitive non-invasive imaging technique to examine the blood vessels in the periphery of the animals’ bodies, as well as the lymphatic and blood vessels directly draining the skull. It turned out that the dye molecules appeared after just a few minutes in the lymphatic vessels and lymph nodes outside the brain. The researchers were unable to find any molecules in blood vessels so quickly after the injection.

They were also able to determine the exact path of the dye molecules and thus the cerebrospinal fluid: it leaves the skull along cranial nerve sheaths – in particular around the olfactory and optic nerves. “Once in tissue outside the brain, it is removed by the lymphatic vessels,” explains Qiaoli Ma, a doctoral student in Detmar’s group and lead author of the study.

The scientists are not entirely able to rule out whether a small portion of the cerebrospinal fluid also leaves the brain as previously assumed – through the veins. However, based on their research findings, they are convinced that the lion’s share travels through the lymphatic system, and that the anatomy textbooks will have to be rewritten.

Irrigation system for the brain

Scientists assume that the circulation of cerebrospinal fluid has a purifying function. “The immune system eliminates toxins elsewhere in the body, but the brain is considered to be largely disconnected from this system. Only a few immune cells have access under normal conditions,” explains Proulx. “The cerebrospinal fluid steps into the breach here. By constantly circulating, it flushes the brain and removes unwanted substances.”

This flushing function could offer a starting point for treatment of neurodegenerative diseases such as Alzheimer’s. Alzheimer’s is caused by misfolded proteins that accumulate in the brain. Proulx and his colleagues speculate that these misfolded proteins could be eliminated by, for example, drugs that induce lymphatic flow. Similarly, studies could be undertaken to examine whether it is possible to manage inflammatory diseases of the central nervous system, such as multiple sclerosis, through influence of the lymphatic flow.

Slower turnover in old age

The scientists also showed that much less cerebrospinal fluid flows out of the brain in older mice than in younger ones, presumably because less fluid is produced in old age. Since Alzheimer’s and other forms of dementia occur in old age, the researchers think it will be interesting to examine whether stimulation of the flow of cerebrospinal fluid could slow down the progression of dementia. This is the question the ETH scientists would like to explore next in a mouse model.

Detmar’s group has already shown that other diseases outside the brain can be treated by stimulation of the lymphatic flow. In the case of rheumatoid arthritis and psoriasis, the researchers succeeded in relieving symptoms through stimulation of the lymphatic flow.

Greater attention in research

The researchers say that studies on cerebrospinal outflow in humans may be conceivable in the future. The fluorescent marker molecule does not trigger an immune reaction and is efficiently eliminated by the body. Before the molecule can be used in humans, the scientists must first apply for the necessary approval.

It has been established that sleep deprivation slows down our reaction time, but it has been unclear exactly how the lack of sleep affects brain activity and subsequent behavior.

A new Tel Aviv University study published today in Nature Medicine finds that individual neurons themselves slow down when we are sleep deprived, leading to delayed behavioral responses to events taking place around us. The neural lapse, or slowdown, affects the brain’s visual perception and memory associations.

The study was an international collaboration led by Dr. Yuval Nir of TAU’s Sackler Faculty of Medicine and Sagol School of Neuroscience; Prof. Itzhak Fried of UCLA, TAU and Tel Aviv Medical Center; and sleep experts Profs. Chiara Cirelli and Giulio Tononi at the University of Wisconsin-Madison.

“When a cat jumps into the path of our car at night, the very process of seeing the cat slows us down. We’re therefore slow to hit the brakes, even when we’re wide awake,” says Dr. Nir. “When we’re sleep-deprived, a local intrusion of sleep-like waves disrupts normal brain activity while we’re performing tasks.”

Investigators recorded the brain activity of 12 epilepsy patients who had previously shown no or little response to drug interventions at UCLA. The patients were hospitalized for a week and implanted with electrodes to pinpoint the place in the brain where their seizures originated. During their hospitalization, their neuron activity was continuously recorded.

After being kept awake all night to accelerate their medical diagnosis, the patients were presented with images of famous people and places, which they were asked to identify as quickly as possible.

“Performing this task is difficult when we’re tired and especially after pulling an all-nighter,” says Dr. Nir. “The data gleaned from the experiment afforded us a unique glimpse into the inner workings of the human brain. It revealed that sleepiness slows down the responses of individual neurons, leading to behavioral lapses.”

In over 30 image experiments, the research team recorded the electrical activity of nearly 1,500 neurons, 150 of which clearly responded to the images. The scientists examined how the responses of individual neurons in the temporal lobe — the region associated with visual perception and memory — changed when sleep-deprived subjects were slow to respond to a task.

“During such behavioral lapses, the neurons gave way to neuronal lapses — slow, weak and sluggish responses,” says Prof. Fried. “These lapses were occurring when the patients were staring at the images before them, and while neurons in other regions of the brain were functioning as usual.”

Investigators then examined the dominant brain rhythms in the same circuits by studying the local electrical fields measured during lapses. “We found that neuronal lapses co-occurred with slow brain waves in the same regions,” Dr. Nir says. “As the pressure for sleep mounted, specific regions ‘caught some sleep’ locally. Most of the brain was up and running, but temporal lobe neurons happened to be in slumber, and lapses subsequently followed.

Scientists identify mechanism that helps us inhibit unwanted thoughts

Scientists have identified a key chemical within the ‘memory’ region of the brain that allows us to suppress unwanted thoughts, helping explain why people who suffer from disorders such as anxiety, post-traumatic stress disorder (PTSD), depression, and schizophrenia often experience persistent intrusive thoughts when these circuits go awry.

We are sometimes confronted with reminders of unwanted thoughts — thoughts about unpleasant memories, images or worries. When this happens, the thought may be retrieved, making us think about it again even though we prefer not to. While being reminded in this way may not be a problem when our thoughts are positive, if the topic was unpleasant or traumatic, our thoughts may be very negative, worrying or ruminating about what happened, taking us back to the event.

“Our ability to control our thoughts is fundamental to our wellbeing,” explains Professor Michael Anderson from the Medical Research Council Cognition and Brain Sciences Unit, which recently transferred to the University of Cambridge. “When this capacity breaks down, it causes some of the most debilitating symptoms of psychiatric diseases: intrusive memories, images, hallucinations, ruminations, and pathological and persistent worries. These are all key symptoms of mental illnesses such as PTSD, schizophrenia, depression, and anxiety.”

Professor Anderson likens our ability to intervene and stop ourselves retrieving particular memories and thoughts to stopping a physical action. “We wouldn’t be able to survive without controlling our actions,” he says. “We have lots of quick reflexes that are often useful, but we sometimes need to control these actions and stop them from happening. There must be a similar mechanism for helping us stop unwanted thoughts from occurring.”

A region at the front of the brain known as the prefrontal cortex is known to play a key role in controlling our actions and has more recently been shown to play a similarly important role in stopping our thoughts. The prefrontal cortex acts as a master regulator, controlling other brain regions – the motor cortex for actions and the hippocampus for memories.

In research published in the journal Nature Communications, a team of scientists led by Dr Taylor Schmitz and Professor Anderson used a task known as the ‘Think/No-Think’ procedure to identify a significant new brain process that enables the prefrontal cortex to successfully inhibit our thoughts.

In the task, participants learn to associate a series of words with a paired, but otherwise unconnected, word, for example ordeal/roach and moss/north. In the next stage, participants are asked to recall the associated word if the cue is green or to suppress it if the cue is red; in other words, when shown ‘ordeal’ in red, they are asked to stare at the word but to stop themselves thinking about the associated thought ‘roach’.

Using a combination of functional magnetic resonance imaging (fMRI) and magnetic resonance spectroscopy, the researchers were able to observe what was happening within key regions of the brain as the participants tried to inhibit their thoughts. Spectroscopy enabled the researchers to measure brain chemistry, and not just brain activity, as is usually done in imaging studies.

Professor Anderson, Dr Schmitz and colleagues showed that the ability to inhibit unwanted thoughts relies on a neurotransmitter – a chemical within the brain that allows messages to pass between nerve cells – known as GABA. GABA is the main ‘inhibitory’ neurotransmitter in the brain, and its release by one nerve cell can suppress activity in other cells to which it is connected. Anderson and colleagues discovered that GABA concentrations within the hippocampus – a key area of the brain involved in memory – predict people’s ability to block the retrieval process and prevent thoughts and memories from returning.

“What’s exciting about this is that now we’re getting very specific,” he explains. “Before, we could only say ‘this part of the brain acts on that part’, but now we can say which neurotransmitters are likely important – and as a result, infer the role of inhibitory neurons – in enabling us to stop unwanted thoughts.”  

“Where previous research has focused on the prefrontal cortex – the command centre – we’ve shown that this is an incomplete picture. Inhibiting unwanted thoughts is as much about the cells within the hippocampus – the ‘boots on the ground’ that receive commands from the prefrontal cortex. If an army’s foot-soldiers are poorly equipped, then its commanders’ orders cannot be implemented well.”

The researchers found that even within his sample of healthy young adults, people with less hippocampal GABA (less effective ‘foot-soldiers’) were less able to suppress hippocampal activity by the prefrontal cortex—and as a result much worse at inhibiting unwanted thoughts.

The discovery may answer one of the long-standing questions about schizophrenia. Research has shown that people affected by schizophrenia have ‘hyperactive’ hippocampi, which correlates with intrusive symptoms such as hallucinations. Post-mortem studies have revealed that the inhibitory neurons (which use GABA) in the hippocampi of these individuals are compromised, possibly making it harder for the prefrontal cortex to regulate activity in this structure. This suggests that the hippocampus is failing to inhibit errant thoughts and memories, which may be manifest as hallucinations.

According to Dr Schmitz: “The environmental and genetic influences that give rise to hyperactivity in the hippocampus might underlie a range of disorders with intrusive thoughts as a common symptom.”

In fact, studies have shown that elevated activity in the hippocampus is seen in a broad range of conditions such as PTSD, anxiety and chronic depression, all of which include a pathological inability to control thoughts – such as excessive worrying or rumination.

Yesterday Childish Gambino aka Donald Glover released a music video for his new song, “This Is America.”

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By scanning the brains of healthy volunteers, researchers at the National Institutes of Health saw the first, long-sought evidence that our brains may drain some waste out through lymphatic vessels, the body’s sewer system. The results further suggest the vessels could act as a pipeline between the brain and the immune system.

“We literally watched people’s brains drain fluid into these vessels,” said Daniel S. Reich, M.D., Ph.D., senior investigator at the NIH’s National Institute of Neurological Disorders and Stroke (NINDS) and the senior author of the study published online in eLife. “We hope that our results provide new insights to a variety of neurological disorders.”

Dr. Reich is a radiologist and neurologist who primarily uses magnetic resonance imaging (MRI) to investigate multiple sclerosis and other neurological disorders which are thought to involve the immune system. Led by post-doctoral fellows, Martina Absinta, Ph.D. and Seung-Kwon Ha, Ph.D., along with researchers from the National Cancer Institute, the team discovered lymphatic vessels in the dura, the leathery outer coating of the brain.

Lymphatic vessels are part of the body’s circulatory system. In most of the body they run alongside blood vessels. They transport lymph, a colorless fluid containing immune cells and waste, to the lymph nodes. Blood vessels deliver white blood cells to an organ and the lymphatic system removes the cells and recirculates them through the body. The process helps the immune system detect whether an organ is under attack from bacteria or viruses or has been injured.

In 1816, an Italian anatomist reported finding lymphatic vessels on the surface of the brain, but for two centuries, it was forgotten. Until very recently, researchers in the modern era found no evidence of a lymphatic system in the brain, leaving some puzzled about how the brain drains waste, and others to conclude that brain is an exceptional organ. Then in 2015, two studies of mice found evidence of the brain’s lymphatic system in the dura. Coincidentally, that year, Dr. Reich saw a presentation by Jonathan Kipnis, Ph.D., a professor at the University of Virginia and an author of one the mouse studies.

“I was completely surprised. In medical school, we were taught that the brain has no lymphatic system,” said Dr. Reich. “After Dr. Kipnis’ talk, I thought, maybe we could find it in human brains?”

To look for the vessels, Dr. Reich’s team used MRI to scan the brains of five healthy volunteers who had been injected with gadobutrol, a magnetic dye typically used to visualize brain blood vessels damaged by diseases, such as multiple sclerosis or cancer. The dye molecules are small enough to leak out of blood vessels in the dura but too big to pass through the blood-brain barrier and enter other parts of the brain.

At first, when the researchers set the MRI to see blood vessels, the dura lit up brightly, and they could not see any signs of the lymphatic system. But, when they tuned the scanner differently, the blood vessels disappeared, and the researchers saw that dura also contained smaller but almost equally bright spots and lines which they suspected were lymph vessels. The results suggested that the dye leaked out of the blood vessels, flowed through the dura and into neighboring lymphatic vessels.

To test this idea, the researchers performed another round of scans on two subjects after first injecting them with a second dye made up of larger molecules that leak much less out of blood vessels. In contrast with the first round of scans, the researchers saw blood vessels in the dura but no lymph vessels regardless of how they tuned the scanner, confirming their suspicions.

They also found evidence for blood and lymph vessels in the dura of autopsied human brain tissue. Moreover, their brain scans and autopsy studies of brains from nonhuman primates confirmed the results seen in humans, suggesting the lymphatic system is a common feature of mammalian brains.

“These results could fundamentally change the way we think about how the brain and immune system inter-relate,” said Walter J. Koroshetz, M.D., NINDS director.

Dr. Reich’s team plans to investigate whether the lymphatic system works differently in patients who have multiple sclerosis or other neuroinflammatory disorders.

Relax, you will be okay.

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