A lab named E11 is working on a novel technique to produce a detailed map of a mouse brain.
Category: neuroscience – Page 63
A brilliant young scientist believes that if we preserve our brains, they could be revived in the future, helping us live for centuries.
“In vivo measurement of basement membrane stiffness showed that ISCs reside in a more rigid microenvironment at the bottom of the crypt,” the article’s authors wrote. “Three-dimensional and two-dimensional organoid systems combined with bioengineered substrates and a stretching device revealed that PIEZO channels sense extracellular mechanical stimuli to modulate ISC function.”
The paper’s first author is Meryem Baghdadi, PhD, a former researcher at SickKids, and the paper’s senior authors are Tae-Hee Kim, PhD, a senior scientist at SickKids, and Danijela Vignjevic, PhD, a research director at Institut Curie. The study they led expanded on the work of one of the paper’s co-authors, Xi Huang, PhD, a senior scientist at SickKids.
In 2018, Huang found that PIEZO ion channels influence tumor stiffening in brain cancer. Inspired by this research, the collaborators in the current study set out to explore how stem cells in the intestines use PIEZO channels to stay healthy and function properly.
Researchers have suspected for some time that the link between our gut and brain plays a role in the development of Parkinson’s disease.
A recent study identified gut microbes likely to be involved and linked them with decreased riboflavin (vitamin B2) and biotin (vitamin B7), pointing the way to an unexpectedly simple treatment that may help: B vitamins.
“Supplementation of riboflavin and/or biotin is likely to be beneficial in a subset of Parkinson’s disease patients, in which gut dysbiosis plays pivotal roles,” Nagoya University medical researcher Hiroshi Nishiwaki and colleagues write in their paper published in May.
👋👋 ✍️ Fabio Remondino et al.
This paper presents a critical analysis of image-based 3D reconstruction using neural radiance fields (NeRFs), with a focus on quantitative comparisons with respect to traditional photogrammetry. The aim is, therefore, to objectively evaluate the strengths and weaknesses of NeRFs and provide insights into their applicability to different real-life scenarios, from small objects to heritage and industrial scenes. After a comprehensive overview of photogrammetry and NeRF methods, highlighting their respective advantages and disadvantages, various NeRF methods are compared using diverse objects with varying sizes and surface characteristics, including texture-less, metallic, translucent, and transparent surfaces. We evaluated the quality of the resulting 3D reconstructions using multiple criteria, such as noise level, geometric accuracy, and the number of required images (i.e.
For the first time, scientists have invented a liquid ink that doctors can print onto a patient’s scalp to measure brain activity. The technology, presented December 2 in the journal Cell Biomaterials, offers a promising alternative to the cumbersome process currently used for monitoring brainwaves and diagnosing neurological conditions. It also has the potential to enhance non-invasive brain-computer interface applications.
“Our innovations in sensor design, biocompatible ink, and high-speed printing pave the way for future on-body manufacturing of electronic tattoo sensors, with broad applications both within and beyond clinical settings,” says Nanshu Lu, the paper’s co-corresponding author at the University of Texas at Austin.
Electroencephalography (EEG) is an important tool for diagnosing a variety of neurological conditions, including seizures, brain tumors, epilepsy, and brain injuries. During a traditional EEG test, technicians measure the patient’s scalp with rulers and pencils, marking over a dozen spots where they will glue on electrodes, which are connected to a data-collection machine via long wires to monitor the patient’s brain activity. This setup is time consuming and cumbersome, and it can be uncomfortable for many patients, who must sit through the EEG test for hours.
During an EEG test, technicians normally use rulers and pencils to mark up a person’s head before gluing electrodes across the scalp. These electrodes are then connected via long wires to a machine that records brain activity. Alternatively, a cap with electrodes can be directly placed on the head.
However, this whole process is time-consuming and inconvenient, say the developers of the new technology. It generally takes around one to two hours to set up an EEG test, said co-developer Nanshu Lu, a professor of engineering at the University of Texas at Austin. The electrodes then need to be monitored about every two hours because the glue that attaches them to the scalp dries up, she told Live Science in an email.
A cancer therapy that prompts the body’s immune defenses against viruses and bacteria to attack tumors can make patients more vulnerable to heart attack and stroke. A possible explanation for this side effect is that the treatment interferes with immune regulation in the heart’s largest blood vessels, a new study suggests.
Led by researchers at NYU Langone Health and its Perlmutter Cancer Center, the new work focused on a potent class of cancer-fighting drugs called immune checkpoint inhibitors. These medications work by blocking molecules embedded on the surface of cells—immune checkpoints—which normally serve as “brake pedals” that prevent excess immune activity, or inflammation. Some tumors are known to hijack these checkpoints to weaken the body’s defenses, so by blocking the checkpoints, the treatments enable the immune system to kill tumor cells.
However, this treatment type may also trigger damaging levels of inflammation in the heart, brain, stomach, and other organs, the researchers say. For example, past studies have shown that about 10% of those with atherosclerosis, the buildup of hardened fatty deposits (plaques) within artery walls, have a heart attack or stroke following cancer treatment. However, the specific mechanisms behind this issue had until now remained unclear.
Summary: Researchers identified specific plant compounds that provide antioxidant and neuroprotective effects, contributing to brain health beyond basic nutrition. By analyzing plant-based foods like lemon balm, sage, and elderberry, scientists linked compounds such as phenolics and terpenes to benefits like reducing oxidative stress and scavenging harmful reactive species.
Quercetin-rich foods, such as Queen Garnet plum and clove, showed strong potential to prevent neuron-like cell damage. This study sheds light on how plant-based diets and supplements could support brain health and manage neuroinflammation-related conditions.
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#brainstimulation #brainfunction #deepbrainstimulation #memory #magneticstimulation #centralnervoussystem #agerelatedmemorydecline
Advances in Neurostimulation in Aging: From Basic Science to Clinical Applications
Guest Editors Dr. Orestis Stylianou and Dr. Gianluca Susi and Associate Editors Dr. Peter Mukli and Dr. Frigyes Samuel Racz and the editorial team of GeroScience (Official Journal of the American Aging Association, published by Springer) invite submission of original research articles and review articles related to basic and clinical research focused on neurostimulation in aging.
Over the past two decades, studies have shown the potential benefits of invasive and non-invasive brain stimulation techniques in addressing age-related alterations in brain function. While invasive techniques were previously dominant in small-scale clinical investigations, recent advances have significantly reduced the invasiveness of these techniques, making them safer and more accessible for research and medical applications. Transcranial current and magnetic stimulation (tCS and tMS) as well as deep brain stimulation (DBS) have shown promising results in improving various types of memory in the elderly population, including but not limited to working, episodic, associative, semantic, and procedural memory. These interventions have the potential to play a vital role in enhancing healthy brain aging and treating age-related pathological conditions affecting the central nervous system.