Hidden within ancient microbial structures, scientists have uncovered a partnership that may mirror one of life’s most transformative moments, the emergence of complex cells.
Category: biological
Ray Kurzweil: “The Biological Singularity Is Almost Here”
To support the channel and help us make more videos like this, check out our Patreon: https://patreon.com/Technomics?utm_me…
👉 Get The AI Career Survival Guide: https://technomics.gumroad.com/l/ai-s…
Are we transcending human biology, or are we engineering our own obsolescence? The Biological Singularity is no longer science fiction. AI systems like AlphaFold 3 and ESM3 are actively rewriting the human source code, turning biology into a programmable engineering discipline. But as we approach the death of aging and the dawn of designer reality, a terrifying question emerges: what happens to the global population when the elite become mathematically and biologically superior? We explore Yuval Noah Harari’s warning of the \.
Fields as Formal Causes, with David Bentley Hart
In this conversation, Rupert Sheldrake and David Bentley Hart delve into the concept of fields in physics, discussing their nature as non-material formative causes and their historical context in scientific thought. They explore the idea that fields, such as gravitational and electromagnetic, act as top-down causes, aligning with Aristotle’s formal and final causes, and argue for a re-evaluation of these ancient concepts in modern science.
Chapter List:
00:00 — Introduction.
01:14 — Exploring Fields as Causes in Nature.
02:08 — Magnetic Fields and Formative Processes.
04:19 — Gravitational Fields and Formative Effects.
06:10 — Aristotle’s Formal and Final Causes.
07:32 — Challenges in Understanding Fields.
09:09 — Fields as Top-Down Causes.
10:34 — Morphic Fields and Formative Causation.
12:23 — Information Theory vs. Form.
14:15 — Fields and Order in Physics.
17:15 — Semantic and Syntactic Information.
18:18 — Universal Gravitational Field.
19:44 — Strong and Weak Nuclear Fields.
21:18 — History of Field Theory and Ether.
23:14 — Gilbert’s Magnetic Theory.
24:46 — Mind-like Structure in Nature.
25:39 — Combination of Top-Down and Bottom-Up Theories.
27:07 — Mechanistic Models and Their Limitations.
28:52 — Recovering Aristotelian Causality.
31:39 — Conclusion and Reflection on Fields as Modern Souls.
—
Dr Rupert Sheldrake, PhD, is a biologist and author best known for his hypothesis of morphic resonance. At Cambridge University, as a Fellow of Clare College, he was Director of Studies in biochemistry and cell biology. As the Rosenheim Research Fellow of the Royal Society, he carried out research on the development of plants and the ageing of cells, and together with Philip Rubery discovered the mechanism of polar auxin transport. In India, he was Principal Plant Physiologist at the International Crops Research Institute for the Semi-Arid Tropics, where he helped develop new cropping systems now widely used by farmers. He is the author of more than 100 papers in peer-reviewed journals and his research contributions have been widely recognized by the academic community, earning him a notable h-index for numerous citations. On ResearchGate his Research Interest Score puts him among the top 4% of scientists.
Physicists can’t find “now” anywhere in the universe | Jim Al-Khalili
Become a Big Think member to unlock expert classes, premium print issues, exclusive events and more: https://bigthink.com/membership/?utm_…
We would hope that the moment that we eternally live in, the “now,” would have a concrete scientific explanation. But the truth is far more complicated, says the relativity of simultaneity.
Jim Al-Khalili explains how the past and future are more fluid than we may think.
Preorder Jim Al-Khalili’s forthcoming book, On Time: The Physics That Makes the Universe, here: https://www.amazon.com/Time-Physics-T?tag=lifeboatfound-20…
About Jim Al-Khalili: Jim is a multiple award-winning science communicator renowned for his public engagement around the world through writing and broadcasting and a leading academic making fundamental contributions to theoretical physics, particularly in nuclear reaction theory, quantum effects in biology, open quantum systems and the foundations of quantum mechanics. Jim is a theoretical physicist at the University of Surrey where he holds a Distinguished Chair in physics as well as a university chair in the public engagement in science. He received his PhD in nuclear reaction theory in 1989 and has published widely in the field. His current interest is in open quantum systems and the application of quantum mechanics in biology.
About Jim Al-Khalili:
Fluorescent technique reveals hidden scale of microfiber pollution from our clothes
Pollution released from our textiles is smaller and more irregular in shape than previously thought, according to new research led by The University of Manchester. In a study published in Scientific Reports, Manchester researchers—in collaboration with researchers from the University of East Anglia and Manchester Metropolitan University—have developed a new fluorescence-based method that dramatically improves the detection of microfibers released from textiles during washing and wear.
The findings suggest that conventional testing methods may have been missing a large proportion of the smallest fiber fragments, the particles most likely to persist in the environment and enter living organisms.
Every time clothes are worn or washed, microscopic fibers shed from fabrics and enter water, air and soil. Until now, accurately measuring the smallest of these fibers has been extremely difficult, limiting our understanding of their true environmental impact.
Protein clusters reshape cell movement and may help cells build amino acids faster
Cells can be thought of as cities, with factories, a transport system, and lots of building activity. An international team led by scientists at the University of Groningen studied cells growing under different conditions and measured the speed of molecule transport. They found that some conditions led to changes in the mobility inside the cells, caused by the clustering of proteins that produce the building materials for growth. It could be that clustering enables the proteins to produce those building blocks more efficiently. The research is published in the journal Molecular Cell.
The research started with a seemingly simple question. How much movement is there within a cell? “We provided bacteria with different nutrients and this resulted in different growth rates,” explains Matthias Heinemann, Professor of Molecular Systems Biology. Movement was measured by inserting tiny (40 nanometers) fluorescent particles in the cells that could be tracked under the microscope. “To our surprise, we found that particle movement under different conditions could vary by a factor of three.”
The scientific literature could not explain this observation. By analyzing the cell content, the scientists found a correlation between movement of the fluorescent particles and the number of proteins that are involved in the production of amino acids. “More of these proteins meant less movement inside the cell,” says Heinemann. “This led us to the question of why this happens. Our hypothesis was that these proteins form clusters that act as obstacles to movement inside the cells.”
Math model reveals how life may have switched on from Earth’s primordial soup
Isolating the first spark of life on Earth is a matter of biology, geology, and chemistry—but it’s also an amazing math problem. At least, that’s how Varun Varanasi viewed it when he was a Yale undergraduate. The question, in a nutshell, is this: How did the primordial soup of interacting molecules on the Earth’s surface billions of years ago transform itself from complete chaos to an organized system of self-sustaining, reproducing chemicals? Did this occur gradually over millions of years, or was it abrupt?
From ship wakes to soft tissues: Exploring fluid and solid surface-wave physics
A new study by scientists in the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) shows that when a pressure disturbance moves across an ultrasoft elastic material, such as a gel or a biological tissue, it generates a V-shaped wake that’s strikingly similar to the waves that travel behind a boat.
Published in Physical Review Letters, the study offers a unified perspective, combining experiments and theory, on surface motion that spans fluids, solids, and the soft materials that lie between. It opens the door to new approaches to imaging and understanding the behavior of both natural and engineered soft materials.
The research was led by L. Mahadevan, the Lola England de Valpine Professor of Applied Mathematics, Organismic and Evolutionary Biology, and Physics, in SEAS and FAS, and includes first author and former postdoctoral researcher Aditi Chakrabarti; postdoctoral researcher Divya Jaganathan, and SEAS research associate Robert Haussman.
A nanoscale robotic cleaner can hunt, capture and remove bacteria
Tiny robots—around 50 times smaller than the diameter of a human hair—open up fascinating possibilities: they enable the controlled manipulation of objects far too small for human hands. This brings us closer to a long-standing dream—the direct interaction with the microscopic world.
Particularly relevant are biological objects in aqueous environments, such as single cells or bacteria. Handling such objects in a controlled and targeted way has remained a major challenge.
A team of researchers have demonstrated how such microscopic cleaners can be employed and precisely controlled. The study is published in the journal Nature Communications. The nanorobots presented demonstrate that controlled manipulation, including collection and relocation of bacteria, is already achievable.