Showing posts with label science. Show all posts
Showing posts with label science. Show all posts

Thursday, February 29

In The NEWS


Sports, Entertainment, & Culture

> Sony's PlayStation division to lay off 900 employees, roughly 8% of its workforce after missing its sales target for the PS5 console (More) | Disney's film production president Sean Bailey steps down after 15 years (More)

> Willie Nelson and Bob Dylan headline 2024 Outlaw Music Festival Tour; see full list of performers and concert dates (More)

> Spotify generates $4.5B for independent labels and artists (More) | Sean "Diddy" Combs accused by male music producer of sexual assault, now the fifth such lawsuit against Combs (More)


Science & Technology
> OpenAI asks judge to dismiss key part of New York Times copyright infringement lawsuit, accusing the news organization of "hacking" ChatGPT to produce copyrighted results (More) | See case background (More)

> Hearing live music triggers more brain activity in regions responsible for processing emotions than recordings of the same song, MRI study suggests (More)

> Researchers find striped marlin communicate with each other by changing the shade of their stripes during high-speed hunting; discovery sheds light on the evolution of predatory group behaviors in fish (More)


Business & Markets
> US stock markets close mixed (S&P 500 +0.2%, Dow -0.3%, Nasdaq +0.4%) as investors await this week's inflation data (More)

> Macy's to close 150 underperforming namesake stores, or about 30% of its total stores, by 2026; company expects to add new locations of higher-end department store Bloomingdale’s and beauty chain Bluemercury (More)

> Apple cancels decadelong project to develop autonomous electric vehicle, pivots to artificial intelligence (More) | Financial Times launches new investment arm for media and technology companies, makes first investment in future-of-work startup Charter (More)


SOURCE:  1440 News

Tuesday, November 28

New Science


Scientists identify almost 200 new CRISPR molecules after searching through databases of rare and unusual bacterial systems; may open new types of gene editing applications in mammals (More) |CRISPR 101 (More)



Study finds bladder-like cells on resilient plants like quinoa fend off insects and disease, are not used to store water for droughts; findings overturn a century-old theory in plant biology (More)



Astronomers detect second-most energetic cosmic ray on record; origins of the subatomic particle traveling near the speed of light remain a mystery (More)

Tuesday, July 19

Eating Pumpkin Seeds


When people think of pumpkins, most people think of those orange gourds that are fun for picking and carving during the autumn season. Pumpkins are also great for making delicious and flavorful recipes. However, did you know that the pumpkin can also be used for its seeds?

You've heard of eating sunflower seeds, chia seeds, and other various types, but it may be time to add pumpkin seeds to your list if you haven't already. The dietitians on our Medical Expert Board gave us insight into what would happen if you added them to your diet. Read on to see what the effects of pumpkin seeds are. Then, be sure to check out Surprising Side Effects of Eating Flax Seeds, Says Science.

According to Lauren Manaker, MS, RDN, LDN, CLEC, CPT, author of The First Time Mom's Pregnancy Cookbook, The 7 Ingredient Healthy Pregnancy Cookbook, and Fueling Male Fertility, pumpkin seeds contain zinc, a nutrient that supports immune health.

"Eating them consistently may help you take in enough of this key mineral and support your immune health," says Manaker.

"Pumpkin seeds are high in fiber which can be a good thing, but practicing portion control is important," says Lisa Young, PhD, RDN, author of Finally Full, Finally Slim, and a nutritionist in private practice.

If you do consume too many pumpkin seeds at once, Dr. Young suggests that it may lead to gas and stomach discomfortREAD MORE...

Friday, March 18

Computer Program Predicts Civilization End

In 1704, Isaac Newton predicted the end of the world sometime around (or after, “but not before”) the year 2060, using a strange series of mathematical calculations. Rather than study what he called the “book of nature,” he took as his source the supposed prophecies of the book of Revelation. 

While such predictions have always been central to Christianity, it is startling for modern people to look back and see the famed astronomer and physicist indulging them. For Newton, however, as Matthew Stanley writes at Science, “laying the foundation of modern physics and astronomy was a bit of a sideshow. He believed that his truly important work was deciphering ancient scriptures and uncovering the nature of the Christian religion.”

Over three hundred years later, we still have plenty of religious doomsayers predicting the end of the world with Bible codes. But in recent times, their ranks have seemingly been joined by scientists whose only professed aim is interpreting data from climate research and sustainability estimates given population growth and dwindling resources. 

The scientific predictions do not draw on ancient texts or theology, nor involve final battles between good and evil. Though there may be plagues and other horrible reckonings, these are predictably causal outcomes of over-production and consumption rather than divine wrath. Yet by some strange fluke, the science has arrived at the same apocalyptic date as Newton, plus or minus a decade or two.

The “end of the world” in these scenarios means the end of modern life as we know it: the collapse of industrialized societies, large-scale agricultural production, supply chains, stable climates, nation states…. Since the late sixties, an elite society of wealthy industrialists and scientists known as the Club of Rome (a frequent player in many conspiracy theories) has foreseen these disasters in the early 21st century. 

One of the sources of their vision is a computer program developed at MIT by computing pioneer and systems theorist Jay Forrester, whose model of global sustainability, one of the first of its kind, predicted civilizational collapse in 2040. “What the computer envisioned in the 1970s has by and large been coming true,” claims Paul Ratner at Big Think.    TO READ MORE ABOUT THIS, CLICK HERE...

Thursday, December 30

STEM Education in the USA

VISION STATEMENT

“All citizens can contribute to our nation’s progress and vibrancy. To be prepared for the STEM careers of the future, all learners must have an equitable opportunity to acquire foundational STEM knowledge. The STEM Education of the Future brings together our advanced understanding of how people learn with modern technology to create more personalized learning experiences, to inspire learning, and to foster creativity from an early age. It will unleash and harness the curiosity of young people and adult learners across the United States, cultivating a culture of innovation and inquiry, and ensuring our nation remains the global leader in science and technology discovery and competitiveness.”


Rapid technological advancements and societal changes are our daily reality. While the future of work, the economy, and society is uncertain, one thing is not: To maintain the nation’s leadership in science and technology discovery, we must create an approach to science, technology, engineering, and math (STEM) education that prepares and advances the U.S. for this future.

Experts agree that science, technology, engineering and math will drive new innovations across disciplines, making use of computational power to accelerate discoveries and finding creative ways to work across disciplinary silos to solve big challenges. To remain competitive going forward, our nation must continue to design and build a thriving innovation economy, supported by a citizenry that is invested in the STEM enterprise. To succeed, the nation must invest in new research and innovation infrastructures that include all people, regardless of their background.

HOW DO WE ACHIEVE THIS VISION?

We instill creativity, innovation, and a passion for STEM from an early age, and we maintain that engagement and enthusiasm throughout their lives. Doing so will unleash an innovation culture, teaching learners of all ages to take risks, be creative, and problem-solve. Today, we are far from this goal. 

Many Americans are entering the workforce without a basic grasp of STEM facts and approaches. Equally worrisome, amid the stagnant or dipping numbers of U.S.-born STEM workers, there is a critical lack of women, people with disabilities and African Americans, Hispanic Americans, and Native Americans who remain underrepresented in STEM. This underrepresentation is especially evident in several strategic areas critical for U.S. progress and security, including computer science, mathematics, and engineering. 

We are in dire need of STEM role models and leaders for the future. By 2060,1 Black and Hispanic youth will comprise nearly half of all U.S. school-age children. However, STEM faculty from these backgrounds are currently scarce, and trends among the number of domestic students who pursue advanced research degrees in STEM disciplines—particularly computer science, mathematics, and engineering...  READ MORE...

Tuesday, November 2

Consciousness


Explaining how something as complex as consciousness can emerge from a grey, jelly-like lump of tissue in the head is arguably the greatest scientific challenge of our time. 

The brain is an extraordinarily complex organ, consisting of almost 100 billion cells – known as neurons – each connected to 10,000 others, yielding some ten trillion nerve connections.

We have made a great deal of progress in understanding brain activity, and how it contributes to human behaviour. But what no one has so far managed to explain is how all of this results in feelings, emotions and experiences. 

How does the passing around of electrical and chemical signals between neurons result in a feeling of pain or an experience of red?

There is growing suspicion that conventional scientific methods will never be able answer these questions. Luckily, there is an alternative approach that may ultimately be able to crack the mystery.

For much of the 20th century, there was a great taboo against querying the mysterious inner world of consciousness – it was not taken to be a fitting topic for “serious science”. 
Things have changed a lot, and there is now broad agreement that the problem of consciousness is a serious scientific issue. 

But many consciousness researchers underestimate the depth of the challenge, believing that we just need to continue examining the physical structures of the brain to work out how they produce consciousness.  READ MORE...

Saturday, October 23

Wanting out Attention


The energetic phenomena known as Fast Radio Bursts (FRBs) are one of the greatest cosmic mysteries today. These mysterious flashes of light are visible in the radio wave part of the spectrum and usually last only a few milliseconds before fading away forever. 

Since the first FRB was observed in 2007, astronomers have looked forward to the day when instruments of sufficient sensitivity would be able to detect them regularly.

That day has arrived with the completion of the 500-Meter FAST Radio Telescope (aka. Tianyan, “Eye of Heaven”). Since it commenced operations, this observatory has vastly expanded the number of detected FRBs. 

In fact, according to research led by the National Astronomical Observatories of the Chinese Academy of Sciences (NAO/CAS), the observatory detected a total of 1,652 independent bursts from a single source in 47 days.

The research, which recently appeared in the journal Science, was conducted by researchers from the Commensal Radio Astronomy FAST Survey (CRAFTS) project. 

CRAFTS includes researchers from the Cornell Center for Astrophysics and Planetary Science, the Max-Planck-Institut für Radioastronomie, the Commonwealth Scientific and Industrial Research Organisation (CSIRO), and multiple universities in China, Australia, and the U.S.  TO READ MORE, CLICK HERE...

Friday, October 22

We Know Where to Look on Mars

"We're definitely in the right place."

There's an air of relief in the science team running the American space agency's (Nasa) Perseverance rover on Mars.

The researchers are sure now they've sent the robot to a location that provides the best possible opportunity to find signs of ancient life.

"Percy" touched down in Jezero Crater in February and ever since has been snapping thousands of images of its surroundings.

The interpretation of these pictures forms the basis of the first scholarly paper to make it into print, in this week's edition of Science Magazine.

The analysis confirms the rover is sitting on the floor of a once great lake that was fed by a meandering river entering the deep bowl from the west. We're talking of events over 3.5 billion years ago when the Red Planet's climate was far more benign.



From Perseverance's observations, it's now certain that where the river system met the lake water, the flows suddenly slowed and the sediment in suspension fell out to form a delta - the kind of wedge-shaped "landform" you'll see all over the Earth.  READ MORE...


Tuesday, September 21

Science Behind Religion

This story is adapted from How God Works: The Science Behind the Benefits of Religion, by David DeSteno.

EVEN THOUGH I was raised Catholic, for most of my adult life, I didn’t pay religion much heed. Like many scientists, I assumed it was built on opinion, conjecture, or even hope, and therefore irrelevant to my work. That work is running a psychology lab focused on finding ways to improve the human condition, using the tools of science to develop techniques that can help people meet the challenges life throws at them. 

But in the 20 years since I began this work, I’ve realized that much of what psychologists and neuroscientists are finding about how to change people’s beliefs, feelings, and behaviors—how to support them when they grieve, how to help them be more ethical, how to let them find connection and happiness—echoes ideas and techniques that religions have been using for thousands of years.

David DeSteno is a professor of psychology at Northeastern University and author of How God Works: The Science Behind the Benefits of Religion.

Science and religion have often been at odds. But if we remove the theology—views about the nature of God, the creation of the universe, and the like—from the day-to-day practice of religious faith, the animosity in the debate evaporates. What we’re left with is a series of rituals, customs, and sentiments that are themselves the results of experiments of sorts.

 Over thousands of years, these experiments, carried out in the messy thick of life as opposed to sterile labs, have led to the design of what we might call spiritual technologies—tools and processes meant to sooth, move, convince, or otherwise tweak the mind. And studying these technologies has revealed that certain parts of religious practices, even when removed from a spiritual context, are able to influence people’s minds in the measurable ways psychologists often seek.

My lab has found, for example, that having people practice Buddhist meditation for a short time makes them kinder. After only eight weeks of study with a Buddhist lama, 50 percent of those who we randomly assigned to meditate daily spontaneously helped a stranger in pain. Only 16 percent of those who didn’t meditate did the same. (In reality, the stranger was an actor we hired to use crutches and wear a removable foot cast while trying to find a seat in a crowded room.) 

Compassion wasn’t limited to strangers, though; it also applied to enemies. Another study showed that after three weeks of meditation, most people refrained from seeking revenge on someone who insulted them, unlike most of those who did not meditate. Once my team observed these profound impacts, we began looking for other linkages between our previous research and existing religious rituals.


Gratitude, for instance, is something we had studied closely, and a key element of many religious practices. Christians often say grace before a meal; Jews give thanks to God with the Modeh Ani prayer every day upon awakening. When we studied the act of giving thanks, even in a secular context, we found it made people more virtuous. 

In a study where people could get more money by lying about the results of a coin flip, the majority (53 percent) cheated. But that figure dropped dramatically for people who we first asked to count their blessings. Of these, only 27 percent chose to lie. We’ve also found that when feeling gratitude to a person, to fate, or to God, people become more helpful, more generous, and even more patientREAD MORE



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Thursday, August 26

What We Are

“We’ve barely begun to understand our place in the cosmos. As we continue to look out from our planet and contemplate the nature of reality, we should remember that there is a mystery right here where we stand.”



“Meditate often on the interconnectedness and mutual interdependence of all things in the universe,” the aging Marcus Aurelius instructed.

“Any live mind today is of the very same stuff as Plato’s & Euripides,” the young Virginia Woolf meditated in her diary two millennia later. “It is this common mind that binds the whole world together; & all the world is mind.”

Two years earlier, in the first year of the twentieth century and the final year of his life, the uncommonly minded Canadian psychiatrist Maurice Bucke had formalized this notion in his visionary, controversial book Cosmic Consciousness: A Study in the Evolution of the Human Mind, which influenced generations of thinkers ranging from Albert Einstein to Abraham Maslow to Steve Jobs.

Bucke himself had been greatly influenced by, then befriended and in turn influenced, Walt Whitman — a poet enraptured by how science illuminates the interconnectedness of life, who contemplated the strangest and most paradoxical byproduct of consciousness “lifted out from all else, calm, like the stars, shining eternal”: our sense of self.

Science was young then — it still is — and the world was old, and the mind was old, its dwelling-place practically unchanged since the cranium of early Homo sapiens began accommodating a brain comparable to our own some three hundred thousand years ago. 

With neuroscience yet to be born, it fell on the poets and the philosophers to meditate on the complexities of consciousness — the sole valve between reality and our experience, made of the same matter as the stars. Today, neuroscience remains a young and insecure science, as crude as Galilean astronomy — and as revolutionary in the revelations it has already contoured, yet to be shaded in with the nuances of understanding that might, just might, one day illuminate the fundaments of consciousness.  READ MORE

Friday, August 6

Brain Cancer and Mitochondria

 
One in Five Brain Cancers Fueled by Overactive Mitochondria



A new study has found that up to 20% of glioblastomas—an aggressive brain cancer—are fueled by overactive mitochondria and may be treatable with drugs currently in clinical trials.

Mitochondria are responsible for creating the energy that fuels all cells. Though they are usually less efficient at producing energy in cancer, tumor cells in this newly identified type of glioblastoma rely on the extra energy provided by overactive mitochondria to survive.

The study, by cancer scientists at Columbia University’s Vagelos College of Physicians and Surgeons and Herbert Irving Comprehensive Cancer Center, was published in Nature Cancer.

The study also found that drugs that inhibit mitochondria—including a currently available drug and an experimental compound that are being tested in clinical trials—had a powerful anti-tumor effect on human brain cancer cells with overactive mitochondria. (Follow-up, unpublished work found that the same drugs are also active against mitochondrial tumors in glioblastomas growing in mice).

Such drugs are being tested in patients who have a rare gene fusion—previously discovered by the same researchers—that also sends mitochondria into overdrive.

“We can now expand these clinical trials to a much larger group of patients, because we can identify patients with mitochondria-driven tumors, regardless of the underlying genetics,” says Antonio Iavarone, MD, professor of neurology, who led the study with Anna Lasorella, MD, professor of pediatrics. Both are members of Columbia’s Institute for Cancer Genetics.

Study finds four types of brain cancer

The study found that all brain cancers fall into one of four groups, including the mitochondrial subtype.

By classifying brain cancers based on their core biological features, and not just genetic alterations or cell biomarkers, the researchers have gained new insights into what drives each subtype and the prognosis for patients.

“Existing classifications for brain cancer are not informative. They don’t predict outcomes; they don’t tell us which treatments will work best,” Lasorella says.

The importance of an accurate classification system is best illustrated by the example of breast cancer. Breast cancers have very well-defined subtypes that led to the development of therapies that target the key hallmarks, such as estrogen receptors or HER2, that sustain specific subtypes.

“We feel that one of the reasons therapeutic progress in brain cancer has been so slow is because we don't have a good way to classify these tumors,” Iavarone says.

Glioblastoma is the most common—and most lethal—primary brain tumor in adults. Median survival for individuals with glioblastoma is only 15 months.

The new study showed that glioblastoma can be classified in four biological groups. Two of them recapitulate functions active in the normal brain, either stem cells or neurons, respectively. The two other groups include mitochondrial tumors and a group of tumors with multiple metabolic activities (“plurimetabolic”) that are highly resistant to current therapies.

Patients with the mitochondrial tumors had a slightly better prognosis—and lived for a few more months—than patients with the other three types.

“We are excited about the mitochondrial group, because we have drugs for that group in clinical trials already,” Lasorella says, “but the classification now gives us ideas about how to target these other three and we are starting to investigate these more intensely.”

“We’re going beyond one mutation, one drug concept,” she says. “Sometimes it’s possible to get a response that way. But it’s time to target tumors based on the commonalities of their core biology, which can be caused by multiple different genetic combinations.”

Single-cell analyses opens new view of brain cancer
The new findings were only possible by utilizing recent advances in single-cell analyses, which allowed the scientists to understand—cell by cell—the biological activity of thousands of cells from a single tumor.

Overall, the scientists characterized the biological properties of 17,367 individual cells from 36 different tumors.

In addition to analyzing each cell’s genetic mutations and levels of gene activity, the researchers looked at other modifications made to the cells’ genomes and the proteins and noncoding RNAs made by each cell.

Using the data, the researchers devised a computational approach to identify core biological processes, or pathways, in the cells rather than the more common approach of identifying gene signatures. “In this way, we can classify each individual tumor cell based on the real biology that sustains them,” Iavarone says.

Most tumors, the researchers found, were dominated by cells from one of the four subtypes, with a smattering of cells from the other three.

Applying same techniques to other cancers
Lasorella and Iavarone are now applying the same techniques to multiple different aggressive cancers.

This “pan-cancer” approach, they say, should identify commonalities among different types of cancer regardless of the tumor’s origin. If such common pathways exist, drugs that treat mitochondrial brain cancer may also be able to treat mitochondrial types of lung cancer, for example.

“When we classify based on the cell’s core biological activities, which all cells rely on to survive and thrive, we may find that cancers share more in common than was previously apparent by just looking at their genes,” Lasorella says.

Thursday, July 29

Hear What We Want to Hear


Humans depend on their senses to perceive the world, themselves and each other. Despite senses being the only window to the outside world, people do rarely question how faithfully they represent the external physical reality. During the last 20 years, neuroscience research has revealed that the cerebral cortex constantly generates predictions on what will happen next, and that neurons in charge of sensory processing only encode the difference between our predictions and the actual reality.

A team of neuroscientists of TU Dresden headed by Prof Katharina von Kriegstein presents new findings that show that not only the cerebral cortex, but the entire auditory pathway, represents sounds according to prior expectations.

For their study, the team used functional magnetic resonance imaging (fMRI) to measure brain responses of 19 participants while they were listening to sequences of sounds. The participants were instructed to find which of the sounds in the sequence deviated from the others. Then, the participants’ expectations were manipulated so that they would expect the deviant sound in certain positions of the sequences. The neuroscientists examined the responses elicited by the deviant sounds in the two principal nuclei of the subcortical pathway responsible for auditory processing: the inferior colliculus and the medial geniculate body. Although participants recognised the deviant faster when it was placed on positions where they expected it, the subcortical nuclei encoded the sounds only when they were placed in unexpected positions.

These results can be best interpreted in the context of predictive coding, a general theory of sensory processing that describes perception as a process of hypothesis testing. Predictive coding assumes that the brain is constantly generating predictions about how the physical world will look, sound, feel, and smell like in the next instant, and that neurons in charge of processing our senses save resources by representing only the differences between these predictions and the actual physical world.

Dr Alejandro Tabas, first author of the publication, states on the findings: "Our subjective beliefs on the physical world have a decisive role on how we perceive reality. Decades of research in neuroscience had already shown that the cerebral cortex, the part of the brain that is most developed in humans and apes, scans the sensory world by testing these beliefs against the actual sensory information. We have now shown that this process also dominates the most primitive and evolutionary conserved parts of the brain. All that we perceive might be deeply contaminated by our subjective beliefs on the physical world."

These new results open up new ways for neuroscientists studying sensory processing in humans towards the subcortical pathways. Perhaps due to the axiomatic belief that subjectivity is inherently human, and the fact that the cerebral cortex is the major point of divergence between the human and other mammal's brains, little attention has been paid before to the role that subjective beliefs could have on subcortical sensory representations.

Given the importance that predictions have on daily life, impairments on how expectations are transmitted to the subcortical pathway could have profound repercussion in cognition. Developmental dyslexia, the most wide-spread learning disorder, has already been linked to altered responses in subcortical auditory pathway and to difficulties on exploiting stimulus regularities in auditory perception. The new results could provide with a unified explanation of why individuals with dyslexia have difficulties in the perception of speech, and provide clinical neuroscientists with a new set of hypotheses on the origin of other neural disorders related to sensory processing.

Friday, July 23

Adult Brains


(Image caption: A 3-D animated image showing our synapse phagocytosis reporter in mouse hippocampus. Presynapses in green, astrocytes in white, and microglia in blue. Phagocytosed presynapses by glia were shown in red.)


Astrocytes Eat Connections to Maintain Plasticity in Adult Brains
Developing brains constantly sprout new neuronal connections called synapses as they learn and remember. Important connections — the ones that are repeatedly introduced, such as how to avoid danger — are nurtured and reinforced, while connections deemed unnecessary are pruned away. Adult brains undergo similar pruning, but it was unclear how or why synapses in the adult brain get eliminated.

Now, a team of KAIST researchers has found the mechanism underlying plasticity and, potentially, neurological disorders in adult brains. They published their findings in Nature.

“Our findings have profound implications for our understanding of how neural circuits change during learning and memory, as well as in diseases,” said paper author Won-Suk Chung, an assistant professor in the Department of Biological Sciences at KAIST. “Changes in synapse number have strong association with the prevalence of various neurological disorders, such as autism spectrum disorder, schizophrenia, frontotemporal dementia, and several forms of seizures.”

Gray matter in the brain contains microglia and astrocytes, two complementary cells that, among other things, support neurons and synapses. Microglial are a frontline immunity defense, responsible for eating pathogens and dead cells, and astrocytes are star-shaped cells that help structure the brain and maintain homeostasis by helping to control signaling between neurons. According to Professor Chung, it is generally thought that microglial eat synapses as part of its clean-up effort in a process known as phagocytosis.

“Using novel tools, we show that, for the first time, it is astrocytes and not microglia that constantly eliminate excessive and unnecessary adult excitatory synaptic connections in response to neuronal activity,” Professor Chung said. “Our paper challenges the general consensus in this field that microglia are the primary synapse phagocytes that control synapse numbers in the brain.”

Professor Chung and his team developed a molecular sensor to detect synapse elimination by glial cells and quantified how often and by which type of cell synapses were eliminated. They also deployed it in a mouse model without MEGF10, the gene that allows astrocytes to eliminate synapses. Adult animals with this defective astrocytic phagocytosis had unusually increased excitatory synapse numbers in the hippocampus. Through a collaboration with Dr. Hyungju Park at KBRI, they showed that these increased excitatory synapses are functionally impaired, which cause defective learning and memory formation in MEGF10 deleted animals.

“Through this process, we show that, at least in the adult hippocampal CA1 region, astrocytes are the major player in eliminating synapses, and this astrocytic function is essential for controlling synapse number and plasticity,” Chung said.

Professor Chung noted that researchers are only beginning to understand how synapse elimination affects maturation and homeostasis in the brain. In his group’s preliminary data in other brain regions, it appears that each region has different rates of synaptic elimination by astrocytes. They suspect a variety of internal and external factors are influencing how astrocytes modulate each regional circuit, and plan to elucidate these variables.

“Our long-term goal is understanding how astrocyte-mediated synapse turnover affects the initiation and progression of various neurological disorders,” Professor Chung said. “It is intriguing to postulate that modulating astrocytic phagocytosis to restore synaptic connectivity may be a novel strategy in treating various brain disorders.”

Monday, May 31

Consciousness



The history of science includes numerous challenging problems, including the “hard problem” of consciousness: Why does an assembly of neurons—no matter how complex, such as the human brain—give rise to perceptions and feelings that are consciously experienced, such as the sweetness of chocolate or the tenderness of a loving caress on one's cheek? Beyond satisfying this millennia-old existential curiosity, understanding consciousness bears substantial medical and ethical implications, from evaluating whether someone is conscious after brain injury to determining whether nonhuman animals, fetuses, cell organoids, or even advanced machines are conscious.

A comprehensive and agreed-upon theory of consciousness is necessary to answer the question of which systems—biologically evolved or artificially designed—experience anything and to define the ethical boundaries of our actions toward them. The research projects described here will hopefully point the way and indicate whether some of today's major theories hold water or not.

After prosperous decades of focused scientific investigation zeroing in on the neural correlates of consciousness, a number of candidate theories of consciousness have emerged. These have independently gained substantial empirical support, led to empirically testable predictions, and resulted in major improvements in the evaluation of consciousness at the bedside.

Notwithstanding this progress, the conjectures being put forward by the different theories make diverging claims and predictions that cannot all be simultaneously true. Moreover, the theories evolve and continue to adapt as further data accumulates, with hardly any cross-talk between them. How can we then narrow down on which theory better explains conscious experience?

The road to a possible solution may be paved by means of a new form of cooperation among scientific adversaries. Championed by Daniel Kahneman in the field of behavioral economics and predated by Arthur Eddington's observational study to test Einstein's theory of general relativity against Newton's theory of gravitation, adversarial collaboration rests on identifying the most diagnostic points of divergence between competing theories, reaching agreement on precisely what they predict, and then designing experiments that directly test those diverging predictions.

During the past 2 years, several groups have adopted this approach, following an initiative that aims to accelerate research in consciousness. So far, several theories of consciousness are being evaluated in this manner to test competing explanations for where and when neural activity gives rise to subjective experience.  TO READ MORE, CLICK HERE...

Thursday, May 27

Explaining Consciousness

Explaining how something as complex as consciousness can emerge from a grey, jelly-like lump of tissue in the head is arguably the greatest scientific challenge of our time. The brain is an extraordinarily complex organ, consisting of almost 100 billion cells – known as neurons – each connected to 10,000 others, yielding some ten trillion nerve connections.

We have made a great deal of progress in understanding brain activity, and how it contributes to human behaviour. But what no one has so far managed to explain is how all of this results in feelings, emotions and experiences. How does the passing around of electrical and chemical signals between neurons result in a feeling of pain or an experience of red?

There is growing suspicion that conventional scientific methods will never be able answer these questions. Luckily, there is an alternative approach that may ultimately be able to crack the mystery.

For much of the 20th century, there was a great taboo against querying the mysterious inner world of consciousness – it was not taken to be a fitting topic for “serious science”. Things have changed a lot, and there is now broad agreement that the problem of consciousness is a serious scientific issue. But many consciousness researchers underestimate the depth of the challenge, believing that we just need to continue examining the physical structures of the brain to work out how they produce consciousness.  TO READ MORE, CLICK HERE...

Wednesday, April 1

QUANTUM MECHANICS

Quantum Mechanics or QM, describes how the Universe works at the level smaller than atoms. It is also called "quantum physics" or "quantum theory". A quantum of energy is a specific amount of energy, and Quantum Mechanics describes how that energy moves and interacts at the sub-atomic level.


The new theory ignored the fact that electrons are particles and treated them as waves. By 1926 physicists had developed the laws of quantum mechanics, also called wave mechanics, to explain atomic and subatomic phenomena.  When X-rays are scattered, their momentum is partially transferred to the electrons.

The world as we know it has three dimensions of space—length, width and depth—and one dimension of time. But there's the mind-bending possibility that many more dimensions exist out there. According to string theory, one of the leading physics model of the last half century, the universe operates with 10 dimensions.


String theory is a set of attempts to model the four known fundamental interactions—gravitation, electromagnetism, strong nuclear force, weak nuclear force—together in one theory.  Einstein had sought a unified field theory, a single model to explain the fundamental interactions or mechanics of the universe.



One notable feature of string theories is that these theories require extra dimensions of spacetime for their mathematical consistency. In bosonic string theory, spacetime is 26-dimensional, while in superstring theory it is 10-dimensional, and in M-theory it is 11-dimensional.


M-theory is a new idea in small-particle physics that is part of superstring theory that was initially proposed by Edward Witten. The idea, or theory, often causes arguments among scientists, because there is no way to test it to see if it is true.


A type of spacetime symmetry, supersymmetry is a possible candidate for undiscovered particle physics, and seen by some physicists as an elegant solution to many current problems in particle physics if confirmed correct, which could resolve various areas where current theories are believed to be incomplete.