The fellowship of the fish chair
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Misplaced Lens Cap
Aqua Utopia|海の底で記憶を紡ぐ
KIROKAZE
2025 on Tumblr: Trends That Defined the Year
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Origami Around
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PUT YOUR BEARD IN MY MOUTH
One Nice Bug Per Day

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The fellowship of the fish chair
This is slow moving. You might want to skip ahead to the manufacturing process which is the interesting part - watching the concrete printer work. Concept art is included, but no finished products.
This actor was suicidal because of how people criticized him for his portrayal of a computer generated character in the Star Wars prequels. This is his survival story. We must stop destroying people with our words.
Why Machines That Bend Are Better
This is a very good talk that asks the question, “Are we destroying the environment to save the climate?” As a bonus, for such a hot button topic, this does a pretty good job of staying apolitical.
Treating dementia with the healing waves of sound
Ultrasound waves applied to the whole brain improve cognitive dysfunction in mice with conditions simulating vascular dementia and Alzheimer’s disease. The research, conducted by scientists at Tohoku University in Japan, suggests that this type of therapy may also benefit humans.
The team, led by cardiologist Hiroaki Shimokawa, found that applying low-intensity pulsed ultrasound (LIPUS) to the whole brain of the mice improved blood vessel formation and nerve cell regeneration without having obvious side effects.
“The LIPUS therapy is a non-invasive physiotherapy that could apply to high-risk elderly patients without the need for surgery or anaesthesia, and could be used repeatedly,” says Shimokawa.
Dementia affects about 50 million people worldwide, with 10 million new cases occurring every year. But there are currently no curative treatments available for vascular dementia or Alzheimer’s disease, the most common causes of dementia. Also, the cells lining the brain’s blood vessels are tightly packed, forming a blood-brain barrier that prevents large molecules from crossing into the brain tissue. This limits the types of drugs and cell therapies that could be made available to treat dementia.
Shimokawa and his team had conducted previous studies showing that LIPUS improved blood vessel formation in pigs with myocardial ischemia, a condition where there is reduced blood flow to the heart. Other studies have reported that LIPUS increases the production of proteins involved in nerve cell survival and growth, in addition to a role in promoting nerve regeneration. Focusing LIPUS treatment on a region in the brain called the hippocampus, which is involved in memory, has also been found to improve dementia in mice, but the details of how it does this need to be more fully investigated.
The Tohoku University team wanted to find out if whole-brain rather than focused LIPUS is effective in treating mouse models of dementia, and if it was, what was happening at the molecular levels to achieve this.
They found that cognitive impairment markedly improved in mice with conditions similar to vascular dementia and Alzheimer’s disease when LIPUS was applied to the whole brain three times a day for 20 minutes each time. The mice with vascular dementia received the treatment on the first, third and fifth days following a surgical procedure that limited the brain’s blood supply. The mice with a condition simulating Alzheimer’s disease in humans received 11 LIPUS treatments over a period of three months.
At the molecular level, genes related to the cells lining blood vessels were turned on. Also, there was increased expression of an enzyme involved in blood vessel formation and a protein involved in nerve cell survival and growth. The researchers conclude that their study, recently published in the journal Brain Stimulation, provides the first experimental evidence that whole-brain LIPUS therapy markedly improves cognitive dysfunctions without serious side effects by enhancing specific cells related to dementia’s pathology. The first clinical trials to evaluate the effectiveness and safety of the LIPUS treatment are already underway.
Dementia therapy using low-intensity pulsed ultrasound (LIPUS). But will it help prevent?
Smart and passionate weatherman tells the Canadian weather story of the day, via LaughingSquid.com
Interesting C-SPAN interview with the author of an award winning magazine article about the trend in people being attacked online. She tells her own story and other stories including a man who committed suicide after becoming unemployed and unhireable for throwing a sandwich at someone.
She says that 90% of the time these people lose their jobs, not because what they did was so terrible, but because the employers just want their phones to stop ringing.
What science can tell us about how other creatures experience the world
New research detects brain cell that improves learning
The workings of memory and learning have yet to be clarified, especially at the neural circuitry level. But researchers at Uppsala University have now, jointly with Brazilian collaborators, discovered a specific brain neuron with a central role in learning. This study, published in Neuron, may have a bearing on the potential for counteracting memory loss in Alzheimer’s disease.
When a person with dementia forgets having just eaten dinner, it is due to hippocampus damage. In contrast, the same person can describe in vivid detail a fishing trip to Norway 40 years ago. Both cases entail the use of episodic memory, the brain’s storage of events in which we have been personally involved. Dementia diseases impair the ability to form new memories, especially of events since the onset of the disease.
Researchers at Uppsala University have now, jointly with Brazilian colleagues, found certain neurons in the brain that play a crucial part in learning. The same research group had previously discovered ‘gatekeeper cells’ or, in technical parlance, OLM (Oriens-lacunosum moleculare) cells. These are located in the hippocampus, the brain area known to be active in forming new memories. The new findings from Klas Kullander’s research group show that OLM cells’ activity affects the encoding of memories in the brain.
When the OLM cells were overactivated in experiments on laboratory mice, the mice’s memory and learning functions deteriorated. When these cells were inactivated instead, the function of new memory formation improved. This research has enhanced understanding of how a single component in the memory circuits can affect memory formation.
“We had expected to be able to impair learning, since it seemed likely that the effect of our experiment at the cellular level would disturb the normal function of the nervous system. However, we were surprised to find that learning and memory also could be improved,” says Klas Kullander.
It also offers hope of being able to counteract the loss of memory formation in Alzheimer’s disease and dementia. The first symptoms of Alzheimer’s, the most common and familiar dementia disease, are associated with poor memory. Short-term memory is particularly impaired. For those who suffer from dementia symptoms, losing memory functions is a major everyday problem. Unfortunately, there are no curative treatments or medicines that can stop dementia diseases from developing.
“The next step is therefore to investigate this more closely, in further experiments on animal subjects comparable to humans. We need more knowledge before experiments can be done to stimulate the OLM cell artificially in humans,” Kullander says.
More from 30000fps for your wintery delight.
Brief introduction to cerebrospinal fluid flow change in the brain and how it's being studied.
Ignore the horrendous headline. Worth three minutes if you know nothing about this topic. Let me know if you delve further into this and find something of interest to a garden variety polymath. The part about cilia in the brain isn't very interesting and not the main thrust of this story.
The ceremony wasn't legally recognized. The gentleman says he married the cartoon character to give others courage to do the same.
Human Drug Addiction Behaviors Closely Tied to Specific Impairments Within Six Large-Scale Brain Networks
Specific impairments within six large-scale brain networks during drug cue exposure, decision-making, inhibitory control, and social-emotional processing are associated with drug addiction behaviors, according to a systematic review of more than 100 published neuroimaging studies by experts at the Icahn School of Medicine at Mount Sinai and published Wednesday, June 6 in the journal Neuron.
Drug addiction is a disorder that encompasses not only excessive drug-seeking and taking, but also fundamental changes in cognition and emotional processing. It comprises core clinical symptoms and behavioral manifestations including a chronically relapsing cycle of intoxication, bingeing, withdrawal, and craving that propels uncontrollable drug use despite adverse consequences and a reduction in the pleasure derived from the drug. While much of the early research on drug addiction focused on understanding the rewarding properties of the drug, recent research has made it increasingly clear that cognitive and emotional impairments support the initiation, escalation, and maintenance of the cycle of addiction. A better understanding of the underlying impaired neural mechanisms in human drug addiction is critical to paving the way for the development of more targeted, evidence-based treatment interventions and timely prevention approaches.
The Impaired Response Inhibition and Salience Attribution (iRISA) model, first published in 2002 by Rita Goldstein, PhD, Professor of Psychiatry and Neuroscience and Director of the Neuropsychoimaging of Addiction and Related Conditions research program at the Icahn School of Medicine at Mount Sinai, and Nora Volkow, Director of NIDA, proposed that impairments of two broad neuropsychological functions—response inhibition (a cognitive process that permits individuals to inhibit their impulses) and salience attribution (the property of tagging something as valuable or important)—and their underlying neural substrates contribute to the cycle of addiction across a broad range of substances of abuse. The iRISA model uses multiple neuroimaging modalities including magnetic resonance imaging, electroencephalogram (EEG) and derived event-related potentials, positron emission tomography, and neuropsychological testing to explore the underlying neurobiology of human drug addiction and the shift to excessive salience attributed to the drug and drug-related cues at the expense of other salient reinforcers as associated with impaired self-control (especially in a drug related context) and increased drug taking in drug addicted individuals.
“We conducted the current review to update the iRISA model with the most recent evidence from the neuroimaging literature by systematically reviewing 105 task-related neuroimaging studies published since 2010,” says Dr. Goldstein, last and senior author of the paper. “We found consistent impairments in brain function in six large-scale brain networks during performance of different tasks. While the involvement of these specific brain networks was task-specific, we generally observed that in a drug-related context (e.g., during exposure to drug cues) drug addicted individuals had increased engagement of the brain networks underlying decision making, inhibitory control, and social-emotional processing, but a blunted response during non-drug related tasks, as predicted by the iRISA model.”
Specifically, the Mount Sinai study team assessed brain function in drug addiction across a number of brain networks, including findings from whole-brain analyses of significant group differences. They organized the results across six large-scale brain networks that showed impairment of brain function in addiction, encompassing the “reward network,” which includes subcortical and cortical brain regions activated during the appraisal of subjective value; the striatal “habit network,” which underlies learning of automated behavior; the “salience network,” regions involved in (re)directing attentional resources toward salient stimuli; and the “executive network,” which supports the selection of possible behavioral responses (often also named the inhibitory control network).
Two additional networks, which were not discussed in prior reviews of the iRISA model, were found to be relevant to brain function in drug addiction: the “self-directed network,” which is activated during self-directed/referential cognitive processes, and the “memory network,” involved in flexible, multi-cue learning and memory.
“Our review is the first systematic approach to integrate what we know about the function of each of these networks into a comprehensive model underlying drug addiction symptomatology across the addiction cycle,” says Anna Zilverstand, PhD, Assistant Professor of Psychiatry at the Icahn School of Medicine at Mount Sinai and first author of the paper. “We demonstrated common deficits underlying drug addiction independent of the primary drug of choice, which are associated with measures of daily, real-life, drug use and which predict onset, escalation, and relapse into drug use. Our work could inform the development of treatments specifically targeted to alleviate these brain-behavioral deficits.”
It's the Bicentennial of "Silent Night". The classic Christmas tune was first composed as a poem, and it was set to music for the first time (on guitar) in the winter of 1818. More in this article from the Smithsonian.