Aging is a primary risk factor for multi-morbidity and declining quality of life. The geroscience hypothesis states that targeting biological aging mechanisms may prevent or delay morbidity; however, translating theory into practice remains challenging. Unknown long-term risks and a lack of well-validated, responsive, and practical surrogate endpoints especially hinder the field’s preventive aspirations. This review addresses these obstacles by introducing the regeneration model of aging—a novel framework that integrates biological aging processes and distills the complexity of aging into a series of fundamental steps. The model provides insights into potential trade-offs of anti-aging interventions and can guide strategies to slow aging across diverse populations.
In this episode of the New Earth Entrepreneurs podcast, we sit down with John Cumbers, founder of SynBioBeta, to discuss how synthetic biology is reshaping industries and creating sustainable solutions.
John shares insights into the role of bio-manufacturing in decarbonizing supply chains, government initiatives supporting bio-innovation, and the potential for space applications of synthetic biology.
Learn how SynBioBeta is building a passionate community of changemakers to engineer a better, more sustainable world.
The New Earth Entrepreneurs Podcast explores social entrepreneurship and corporate sustainability through engaging conversations with visionary leaders.
The Intelligence Revolution: Coupling AI and the Human Brain. New videos DAILY: https://bigth.ink. Join Big Think Edge for exclusive video lessons from top thinkers and doers: https://bigth.ink/Edge.
Edward Boyden is a Hertz Foundation Fellow and recipient of the prestigious Hertz Foundation Grant for graduate study in the applications of the physical, biological and engineering sciences. A professor of Biological Engineering and Brain and Cognitive Sciences at MIT, Edward Boyden explains how humanity is only at its infancy in merging with machines. His work is leading him towards the development of a “brain co-processor”, a device that interacts intimately with the brain to upload and download information to and from it, augmenting human capabilities in memory storage, decision making, and cognition. The first step, however, is understanding the brain on a much deeper level. With the support of the Fannie and John Hertz Foundation, Ed Boyden pursued a PhD in neurosciences from Stanford University.
EDWARD BOYDEN:
Edward Boyden is a professor of Biological Engineering and Brain and Cognitive Sciences at the MIT Media Lab and the McGovern Institute for Brain Research at MIT. He leads the Media Lab’s Synthetic Neurobiology group, which develops tools for analyzing and repairing complex biological systems, such as the brain, and applies them systematically both to reveal ground truth principles of biological function and to repair these systems.
These technologies, often created in interdisciplinary collaborations, include expansion microscopy (which enables complex biological systems to be imaged with nanoscale precision) optogenetic tools (which enable the activation and silencing of neural activity with light,) and optical, nanofabricated, and robotic interfaces (which enable recording and control of neural dynamics).
Boyden has launched an award-winning series of classes at MIT, which teach principles of neuroengineering, starting with the basic principles of how to control and observe neural functions, and culminating with strategies for launching companies in the nascent neurotechnology space. He also co-directs the MIT Center for Neurobiological Engineering, which aims to develop new tools to accelerate neuroscience progress.
Researchers at Istituto Italiano di Tecnologia (IIT-Italian Institute of Technology) have developed an innovative microscopy technique capable of improving the observation of living cells. The study, published in Optics Letters, paves the way for a more in-depth analysis of numerous biological processes without the need for contrast agents. The next step will be to enhance this technique using artificial intelligence, opening the door to a new generation of optical microscopy methods capable of combining direct imaging with innovative molecular information.
The study was conducted under the guidance of Alberto Diaspro, Research Director of the Nanoscopy Unit and Scientific Director of the Italian Nikon Imaging Center at IIT, by Nicolò Incardona (first author) and Paolo Bianchini.
Protein scientists could improve reproducibility and coordination across the field by rallying around a small, shared set of “model proteins,” according to a new Perspective by Connecticut College chemist Marc Zimmer.
The article appears in the 40th-anniversary issue of Protein Engineering, Design and Selection. Zimmer argues that protein science is ready to adopt a framework similar to the one that transformed research using model organisms such as fruit flies, mice, yeast and C. elegans.
Those organisms became powerful research tools not only because their biology is conserved, Zimmer notes, but because scientific communities coordinated around them. Shared protocols, databases and benchmarks made results easier to compare, reproduce and build upon.
New research provides evidence that women with high levels of psychopathy are more likely to engage in physical, verbal, and indirect aggression against other women. The study indicates that while women generally favor covert competitive tactics, those with specific dark personality traits may bypass these social norms to target rivals directly. These findings were published in Evolutionary Behavioral Sciences.
Evolutionary theory suggests that humans compete for access to romantic partners through a process known as intrasexual selection. This competition can manifest in various ways depending on the sex of the individual. For women, biological factors related to reproduction play a significant role in shaping these competitive strategies.
The theory of obligatory parental investment notes that women face higher biological costs in reproduction than men. Because women carry the fetus during gestation and often care for infants, they must protect their physical well-being to ensure the survival of their offspring. This biological reality implies that direct physical confrontation is a high-risk strategy for women.
Foams are everywhere: soap suds, shaving cream, whipped toppings and food emulsions like mayonnaise. For decades, scientists believed that foams behave like glass, their microscopic components trapped in static, disordered configurations.
Now, engineers at the University of Pennsylvania have found that foams actually flow ceaselessly inside while holding their external shape. More strangely, from a mathematical perspective, this internal motion resembles the process of deep learning, the method typically used to train modern AI systems.
The discovery could hint that learning, in a broad mathematical sense, may be a common organizing principle across physical, biological and computational systems, and provide a conceptual foundation for future efforts to design adaptive materials. The insight could also shed new light on biological structures that continuously rearrange themselves, like the scaffolding in living cells.
According to the new results, as epithelial tissue grows, cells are packed more tightly together, which increases the electrical current flowing through each cell’s membrane. A weak, old, or energy-starved cell will struggle to compensate, triggering a response that sends water rushing out of the cell, shriveling it up and marking it for death. In this way, electricity acts like a health checkup for the tissue and guides the pruning process.
“This is a very interesting discovery — finding that bioelectricity is the earliest event during this cell-extrusion process,” said the geneticist GuangJun Zhang of Purdue University, who studies bioelectrical signals in zebra fish development and wasn’t involved in the study. “It’s a good example of how a widening electronic-signaling perspective can be used in fundamental biology.”
The new discovery adds to the growing assortment of bioelectrical phenomena that scientists have discovered playing out beyond the nervous system, from bacteria swapping signals within a biofilm to cells following electric fields during embryonic development. Electricity increasingly appears to be one of biology’s go-to tools for coordinating and exchanging information between all kinds of cells.
The mucosal surfaces that line the body are embedded with defensive molecules that help keep microbes from causing inflammation and infections. Among these molecules are lectins—proteins that recognize microbes and other cells by binding to sugars found on cell surfaces.
One of these lectins, MIT researchers have found, has broad-spectrum antimicrobial activity against bacteria found in the GI tract. This lectin, known as intelectin-2, binds to sugar molecules found on bacterial membranes, trapping the bacteria and hindering their growth. Additionally, it can crosslink molecules that make up mucus, helping to strengthen the mucus barrier.
“What’s remarkable is that intelectin-2 operates in two complementary ways. It helps stabilize the mucus layer, and if that barrier is compromised, it can directly neutralize or restrain bacteria that begin to escape,” says Laura Kiessling, the Novartis Professor of Chemistry at MIT and the senior author of the study.
Viruses that infect bacteria can still do their job in microgravity, but space changes the rules of the fight.
In a new experiment conducted aboard the International Space Station, scientists found that viruses which infect bacteria can still successfully infect E. coli under near-weightless microgravity conditions. While infection still occurred, the interaction between viruses and bacteria unfolded differently than it does on Earth. The research, led by Phil Huss of the University of Wisconsin-Madison, U.S.A., was published today (January 13th) in the open-access journal PLOS Biology.
A microscopic arms race in an unusual environment.
