Lifeboat Foundation: Safeguarding Humanity
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Category: bioengineering

Aging is a natural process, but for centuries, humans have been searching for ways to slow it down or even reverse it. Recent advancements in stem cell research and regenerative medicine have given scientists unprecedented insights into aging and potential interventions. With breakthroughs in cellular therapy, gene editing, and tissue engineering, we are closer than ever to finding ways to rejuvenate the human body. But how close are we to reversing aging, and what challenges remain?

Stem cells are the body’s raw materials from which all other specialized cells are generated. They have the unique ability to divide and create identical copies of themselves (self-renewal) or differentiate into specialized cell types. However, as we age, our stem cells decline in both number and efficiency, contributing to tissue degeneration, slower healing, and an increased risk of age-related diseases.

Researchers have been investigating how stem cells can be manipulated to repair damaged tissues, regenerate organs, and potentially reverse signs of aging. By harnessing stem cells, scientists aim to restore youthful function in various tissues and organs, offering promising anti-aging therapies.

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When the immune system becomes unbalanced, it can lead to serious problems, such as type 1 diabetes, other autoimmune diseases, or organ rejection after a transplant. Current treatments often involve suppressing the entire immune system, which can cause severe side effects, including a higher risk of infections and other complications. A better approach would be to regulate the immune response in a precise and targeted way. That’s exactly what researchers have now achieved by engineering specialized immune cells designed to restore balance without compromising overall immunity.

Engineering Immune Cells to Protect Rather Than Attack

The immune system defends the body against viruses, bacteria, and other threats by identifying harmful invaders and mounting a response. It also distinguishes between the body’s own cells and foreign ones, adjusting its reaction as needed. However, when the immune system becomes dysregulated, it can mistakenly attack the body’s own tissues. This happens in conditions like type 1 diabetes, where the immune system destroys insulin-producing beta cells in the pancreas. It can also reject transplanted organs, treating them as foreign threats. While immunosuppressant drugs can prevent these harmful reactions, they come with serious risks, including increased vulnerability to infections and cancer.

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Synthetically replicating transmembrane protein signal transduction is a gaol of synthetic biology. Here, the authors show how the dimerization of synthetic transmembrane DNA receptors can be used to engineer sensing and actuation cascades in response to external molecular signals.

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Manu Prakash, an assistant professor of bioengineering at Stanford, and his students have developed a synchronous computer that operates using the unique physics of moving water droplets. Their goal is to design a new class of computers that can precisely control and manipulate physical matter. For more info: http://news.stanford.edu/news/2015/ju

Music: “Union Hall Melody” by Blue Dot Sessions.

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A new technology developed at MIT enables scientists to label proteins across millions of individual cells in fully intact 3D tissues with unprecedented speed, uniformity, and versatility. Using the technology, the team was able to richly label large tissue samples in a single day. In their new study in Nature Biotechnology, they also demonstrate that the ability to label proteins with antibodies at the single-cell level across large tissue samples can reveal insights left hidden by other widely used labeling methods.

Profiling the proteins that cells are making is a staple of studies in biology, neuroscience, and related fields because the proteins a cell is expressing at a given moment can reflect the functions the cell is trying to perform or its response to its circumstances, such as disease or treatment. As much as microscopy and labeling technologies have advanced, enabling innumerable discoveries, scientists have still lacked a reliable and practical way of tracking protein expression at the level of millions of densely packed individual cells in whole, 3D intact tissues. Often confined to thin tissue sections under slides, scientists therefore haven’t had tools to thoroughly appreciate cellular protein expression in the whole, connected systems in which it occurs.

“Conventionally, investigating the molecules within cells requires dissociating tissue into single cells or slicing it into thin sections, as light and chemicals required for analysis cannot penetrate deep into tissues. Our lab developed technologies such as CLARITY and SHIELD, which enable investigation of whole organs by rendering them transparent, but we now needed a way to chemically label whole organs to gain useful scientific insights,” says study senior author Kwanghun Chung, associate professor in The Picower Institute for Learning and Memory, the departments of Chemical Engineering and Brain and Cognitive Sciences, and the Institute for Medical Engineering and Science at MIT. “If cells within a tissue are not uniformly processed, they cannot be quantitatively compared. In conventional protein labeling, it can take weeks for these molecules to diffuse into intact organs, making uniform chemical processing of organ-scale tissues virtually impossible and extremely slow.”

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Scientists have translated nanoscale experimental and computational data into precise 3D representations of bacteria, yeast and human epithelial, breast and breast cancer cells in Minecraft, a video game that allows players to explore, build and manipulate structures in three dimensions.

The innovation will allow researchers and students of all ages to navigate biological cells, puncturing through the membranes of organelles to view their interiors or wandering across the cytoplasm to see how the various structures are distributed within the cell.

“CraftCells: A Window into Biological Cells” is the first broadly accessible tool allowing users to get an accurate picture of whole cells in 3D, said Zaida (Zan) Luthey-Schulten, a professor of chemistry and of physics at the University of Illinois Urbana-Champaign who led the work with Illinois bioengineering professors Stephen Boppart and Rohit Bhargava, graduate student Kevin Tan, postdoctoral researchers Zane Thornburg and Seth Kenkel, and study lead author Tianyu Wu, a biophysics graduate student at the U. of I.

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