See my Comment below for a link to the original article in NATURE.
5-methoxy-N, N-dimethyltryptamine (hereinafter referred to as 5-MeO-DMT) is a psychedelic substance found in the secretion from the parotoid glands of the Bufo alvarius toad. Inhalation of vapor from toad secretion containing 5-MeO-DMT has become popular in naturalistic settings as a treatment of mental health problems or as a means for spiritual exploration. However, knowledge of the effects of 5-MeO-DMT in humans is limited.
Researchers at UT Southwestern Medical Center have discovered that a crucial developmental process in the brain’s hypothalamus may influence how susceptible individuals are to obesity. Their preclinical findings, published in Neuron, show that a transcription factor called Otp acts as a molecular “switch” that directs immature hypothalamic neurons toward either appetite-suppressing or appetite-stimulating fates—their ultimate identities as specialized cells. The researchers found that disrupting this switch alters feeding behavior and protects mice from diet-induced obesity.
“These findings show that early developmental decisions in the hypothalamus have a long-lasting impact on energy balance,” said senior author Chen Liu, Ph.D., Associate Professor of Internal Medicine and Neuroscience and an Investigator in the Peter O’Donnell Jr. Brain Institute at UT Southwestern.
“By uncovering this fate-switching program, we can begin to understand how the brain establishes lifelong metabolic set points.”
“EE is a disabling form of reflex epilepsy with heterogeneous clinical, EEG and neuroimaging features, which are not necessarily substrate-specific. Findings from our study point to the presence of a wide epileptogenic network prominently involving perisylvian regions. Treatment outcomes in drug-refractory EE remain suboptimal, and further studies are needed for a better understanding and management of this complex entity.”
Read this original article from Epileptic Disorders at doi.org/10.1002/epd2.70132.
Objectives To evaluate the clinical, electroencephalographic (EEG), neuroimaging characteristics, and treatment outcomes of patients diagnosed with eating epilepsy (EE). Methods This retrospective study was conducted at a tertiary care epilepsy referral center in India. Patients diagnosed with EE between 2002 and 2025, with at least one EEG and magnetic resonance imaging (MRI) available for review, were consecutively included. Clinical data and multimodal evaluation findings including video EEG, brain MRI, positron emission tomography-MRI (PET-MRI), and magnetoencephalography (MEG) were systematically collected using a structured proforma. Seizure outcomes and treatment strategies were subsequently analyzed.
The brain’s ability to do everything from forming memories to coordinating movement relies on its cells producing the right proteins at the right time. But directly measuring this protein production, known as translation, across different types of brain cells has been a challenge.
Now, scientists at University of California School of Medicine, Scripps Research and their colleagues have developed a technology that reveals which proteins are generated by individual brain cells. The team used their method—called Ribo-STAMP—to create the first maps of protein production across nearly 20,000 individual cells in the mouse hippocampus, a brain region essential for learning and memory.
The study was published in Nature.
Cognitive Scientist, Dr. Donald Hoffman returns to the mind meld!
Are we, as Plato argued thousands of years ago, mistaking shadows on a cave wall for reality?
In this conversation with the brilliant Dr. Donald Hoffman, we question whether space-time and the world we experience with our senses is fundamental or merely a shallow projection of something deeper. Drawing on Plato’s cave, physics, cognitive science, mystical traditions, quantum theory, and Hoffman’s own framework of conscious agents, we explore the possibility that reality emerges from consciousness rather than the other way around. Don also shares what could be a mind blowing breakthrough in his theory.
What is reality? Will science ever find a final theory of everything? Are we locked inside a simulation designed for survival, not truth? If consciousness transcends space-time, what does that imply about our potential, our perception, our purpose and our fate as beings? We riff on all of this and more in this mind meld.
Links for Donald Hoffman:
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Don’s book, The Case Against Reality: https://a.co/d/0aGapviw.
Don’s UC Irvine page: https://sites.socsci.uci.edu/~ddhoff/
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This led to the discovery that myelin swellings have a dynamic character: they can not only grow, but also shrink and even recover completely. It also turns out that the activity of the underlying nerve fibre plays an important role; more activity of the nerve fibre leads to more and bigger swellings, while less activity allows for possible recovery.
The authors show that in human multiple sclerosis tissue, myelin swelling is also dynamic and is prominent around active lesions. Science Mission sciencenewshighlights.
An international research team have gained new insights into the dynamics of myelin swellings in the brain. Myelin swellings are considered as the precursor of lesions in the brain of people with multiple sclerosis (MS). The results have been recently published in the leading magazine Science.
MS is characterised by lesions in the brain and the spinal cord. Aside from these inflammations, damage can also be visible in the myelin; the protective layer surrounding nerve fibers. Myelin swellings are seen as a precursor for damaged myelin.
The research team used advanced microscopy techniques and different models – from zebrafish and mouse models to human brain tissue – to research the formation of this damage.
