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Archive for the ‘bioengineering’ category: Page 93

Apr 21, 2021

Approaching a Singularity, When The Number of Humans Alive Will Equal The Number Who Have Ever Died

Posted by in categories: bioengineering, biological, genetics, life extension, nuclear energy, singularity, sustainability

There are several key technologies converging on an inevitable effect, namely a dramatic, explosive increase in human population. Currently around 40% of Earth’s total land area is dedicated to agricultural production to feed seven billion people, but, interestingly, while the human population will increase, the land area required to sustain this population will decrease, approaching zero land area to sustain a trillion human lives. In this era, bulk elements such as gold will have no value, since they will be so easy to produce by fusion separation of elements from bulk rock. Instead, value will be attached to biological material and, most importantly, new technologies themselves.

The several key emerging technologies that make this state of affairs unstoppable are listed along with aspects of their impact:

1) Most important is fusion energy, an unlimited, scalable energy, with no special fuel required to sustain it. This will allow nearly all agriculture to be contained in underground “vertical farm” buildings, extending thousands of feet downwards. Cheap artificially-lighted, climate-controlled environments will allow the maximum efficiency for all food crops. Thus, agriculture will take up close to zero surface area, largely produced underground on Earth or the Moon.

Continue reading “Approaching a Singularity, When The Number of Humans Alive Will Equal The Number Who Have Ever Died” »

Apr 20, 2021

CRISPR-on, CRISPR-off Next Level Gene Editing… — YouTube

Posted by in categories: bioengineering, biotech/medical

Clip from Lew Later (This iPhone is 1 in 100 Million…) — https://youtu.be/OczdkxrD2uQ.

Apr 18, 2021

NASA MOXIE device will create oxygen on Mars

Posted by in categories: bioengineering, energy, space

Circa 2020 o.o


The NASA Perseverance Rover has a device aboard called MOXIE that will convert the air available on Mars into oxygen. The device is a test, and if the technology was used on a larger scale could produce oxygen for humans to breathe on the Red Planet and could be used for rocket fuel. NASA knows that one of the most challenging parts of putting people on Mars will be getting them off the planet and back to Earth.

Continue reading “NASA MOXIE device will create oxygen on Mars” »

Apr 15, 2021

Part-human, part-monkey embryos grown in lab dishes

Posted by in categories: bioengineering, biotech/medical, life extension

Scientists injected dozens of human stem cells into developing monkey embryos, and the resulting hybrids survived for up to 20 days in lab dishes.

These human-monkey embryos could someday serve as helpful models for human disease, embryonic development and aging, the study authors noted in a new report, published April 15 in the journal Cell. By zooming in on the interaction of human and animal cells in the embryos, scientists could also learn how to help human cells survive amongst animal cells, potentially advancing the effort to grow human organs in living animal models.

Apr 10, 2021

Genetic Engineering 2.0: An On-Off Switch for Gene Editing

Posted by in categories: bioengineering, biotech/medical, genetics

New, reversible CRISPR method can control gene expression while leaving underlying DNA sequence unchanged.

Over the past decade, the CRISPR-Cas9 gene editing system has revolutionized genetic engineering, allowing scientists to make targeted changes to organisms’ DNA. While the system could potentially be useful in treating a variety of diseases, CRISPR-Cas9 editing involves cutting DNA strands, leading to permanent changes to the cell’s genetic material.

Now, in a paper published online in Cell on April 9, researchers describe a new gene editing technology called CRISPRoff that allows researchers to control gene expression with high specificity while leaving the sequence of the DNA unchanged. Designed by Whitehead Institute Member Jonathan Weissman, University of California San Francisco assistant professor Luke Gilbert, Weissman lab postdoc James Nuñez and collaborators, the method is stable enough to be inherited through hundreds of cell divisions, and is also fully reversible.

Apr 9, 2021

MIT and UCSF researchers create CRISPR ‘on-off switch’ that controls gene expression without changing DNA

Posted by in categories: bioengineering, biotech/medical, genetics, neuroscience

The gene editing system CRISPR-Cas9 makes breaks in DNA strands that are repaired by cells—a process that can be hard to control, resulting in unwanted genetic changes. Researchers at the Massachusetts Institute of Technology and the University of California, San Francisco (UCSF) designed an alternative technology that changes gene expression without damaging DNA, and they believe it could be useful for both research and drug development.

The researchers used their system, dubbed CRISPRoff and CRISPRon, to induce pluripotent stem cells to transform into neurons. They also used it to silence the gene that makes the protein Tau, which has been implicated in Alzheimer’s disease. They described their research in the journal Cell.

The MIT and UCSF researchers started by creating a machine made of a protein and small RNAs that guided it to specific spots on strands of DNA. The machine adds “methyl groups” to genes to silence their expression. The technology can also reverse the process, turning the genes back on by removing the methyl groups.

Apr 7, 2021

These mobile, self-healing living robots were born from frog stem cells

Posted by in categories: bioengineering, biotech/medical, robotics/AI

Like something straight out of a pulpy sci-fi horror flick, researchers at Tufts University and the University of Vermont (UVM) have engineered a new generation of living robots they call Xenobots, which demonstrate cooperative swarm activity while collecting piles of micro particles.

Last year, this same team of scientists and biologists created tiny self-healing bio-machines that exhibited movement, payload pushing abilities, and a sort of hive mentality. The blueprints for creating these biological bots, which technically aren’t a typical robot or a catalogued animal species, but instead are more akin to a distinct class of unique artifact that acts as a living, programmable organism.

Apr 7, 2021

Bioengineers Learn the Secrets to Precisely Turning on and off Genes in Living Cells

Posted by in categories: bioengineering, biotech/medical, chemistry

In a recent study led by the University of Bristol, scientists have shown how to simultaneously harness multiple forms of regulation in living cells to strictly control gene expression and open new avenues for improved biotechnologies.

Engineered microbes are increasingly being used to enable the sustainable and clean production of chemicals, medicines and much more. To make this possible, bioengineers must control when specific sets of genes are turned on and off to allow for careful regulation of the biochemical processes involved.

Their findings are reported in the journal Nature Communications.

Apr 7, 2021

Dr. Lee Chae — Co-Founder / CTO, Brightseed — Re-Connect People and Plants, For Health & Wellness

Posted by in categories: bioengineering, biotech/medical, food, health, robotics/AI

Using Artificial Intelligence And Plant Biology, To Re-Connect People and Plants, For Health & Wellness — Dr. Lee Chae, Ph.D., Co-Founder & CTO, Brightseed.


Dr. Lee Chae, Ph.D., is a Co-Founder and Chief Technology Officer at Brightseed, a novel life sciences company, merging the tools of plant biology and artificial intelligence, with a goal of enabling a healthier future by re-illuminating and re-activating the connections between people and plants.

Continue reading “Dr. Lee Chae — Co-Founder / CTO, Brightseed — Re-Connect People and Plants, For Health & Wellness” »

Apr 6, 2021

Research team discovers use of elasticity to position microplates on curved 2D fluids

Posted by in categories: bioengineering, biological

A team of polymer science and engineering researchers at the University of Massachusetts Amherst has demonstrated for the first time that the positions of tiny, flat, solid objects integrated in nanometrically thin membranes—resembling those of biological cells—can be controlled by mechanically varying the elastic forces in the membrane itself. This research milestone is a significant step toward the goal of creating ultrathin flexible materials that self-organize and respond immediately to mechanical force.

The team has discovered that rigid solid plates in biomimetic fluid membranes experience interactions that are qualitatively different from those of biological components in cell membranes. In cell membranes, fluid domains or adherent viruses experience either attractions or repulsions, but not both, says Weiyue Xin, lead author of the paper detailing the research, which recently appeared in Science Advances. But in order to precisely position solid objects in a membrane, both attractive and repulsive forces must be available, adds Maria Santore, a professor of polymer science and engineering at UMass. In the Santore Lab at UMass, Xin used giant unilamellar vesicles, or GUVs, which are cell-like membrane sacks, to probe the interactions between solid objects in a thin, sheet-like material. Like biological cells, GUVs have fluid membranes and form a nearly spherical shape. Xin modified the GUVs so that the membranes included tiny, solid, stiff plate-like masses.

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