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Archive for the ‘bioengineering’ category: Page 186

Feb 8, 2017

Engineering Nature: How Improved Photosynthesis Could Feed the World

Posted by in categories: bioengineering, food, genetics

https://youtube.com/watch?v=d6xpQYaxiRc

In Brief

  • Researchers were able to increase the weight of tobacco plants by around 14 to 20 percent compared to unmodified plants by adding in genes to improve the process of photosynthesis.
  • If successful with other plants, the method could improve the yields of food crops such as cowpeas, rice, and cassava and decrease world hunger.

In terms of plants, the concept of genetically modified organisms (GMOs) often refers to the insertion of genetic information from one species of plant to another so that the recipient plant gains a desirable trait. This process has been used extensively to improve crop yields. For example, one type of rice has been made waterproof so that yields aren’t affected by heavy floods from typhoons.

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Feb 8, 2017

Better 3D-printed scaffolds help scientists study cancer

Posted by in categories: 3D printing, bioengineering, biotech/medical

Nice.


Testing treatments for bone cancer tumors may get easier with new enhancements to sophisticated support structures that mimic their biological environment, according to Rice University scientists.

A team led by Rice bioengineer Antonios Mikos has enhanced its three-dimensional printed scaffold to see how Ewing’s sarcoma (bone cancer) cells respond to stimuli, especially shear stress, the force experienced by tumors as viscous fluid such as blood flows through bone. The researchers determined the structure of a scaffold, natural or not, has a very real effect on how cells express signaling proteins that help cancer grow.

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Feb 8, 2017

Intestine, Liver, Kidney Proximal Tubule, Blood-Brain Barrier and Skeletal Muscle

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

This is definitely a share that is interesting to many studying synthetic organs and their acceptance into the human body as well as the work occurring on Quantum biology as well.


The goal of in vitro and in vivo toxicity testing is to identify compounds that would predict adverse reactions in humans. Olson et al. found that only 70% of human toxicity was predicted from animal testing. Currently we rely on traditional toxicity testing in animals, a 1930’s methodology that is now challenged due to questionable relevance to human risk, high cost, ethical concerns, and throughput that is too limited for the nearly 80,000 industrial chemicals not yet tested for safety. Additionally, testing usually extrapolates acute, high dose animal results to chronic, low dose human exposures, thereby risking rejection or limiting the use of drugs, industrial chemicals or consumer products. Moreover, the ability of lab animal target organ toxicity to predict dose-limiting toxicity in the corresponding human organ varies widely, from a low of 30% for human cutaneous toxicity, to 50–60% for human hepatotoxicity, to a high of 90% for hematological drug toxicity. Animal drug efficacy models are also notoriously discordant. In an analysis of six drugs to treat head injury, hemorrhage, acute ischemic stroke, neonatal respiratory distress syndrome, and osteoporosis, it was found that efficacy was similar in animals and humans for three drugs but was dissimilar for another three. In oncology drug development, animal models often over-predict anti-tumor efficacy in humans3,4. Examples such as these highlight the need to continue research into methods that reduce the dependence on laboratory animals for toxicity testing of environmental chemicals, determine efficacy and toxicity in drug development, serve as a mimic of human diseases, and provide patient-specific guidance in the emerging field of precision medicine.

Recent advances in bioengineered materials, microfluidic technology, and the availability of human primary, immortalized, and induced pluripotent stem cell (iPSC)-derived cells are enabling development of human microphysiological systems (MPS), sometimes called “organs-on-a-chip” or “human-on-a-chip,” that use multiple organ-specific human cells to recapitulate many functional and structural properties of a human organ. It is now generally accepted and supported by data that cellular responses to drugs in most human organs are more accurately approximated in 3D cell cultures than in traditional static 2D cell cultures5,6. Microfluidic perfusion further improves model performance by providing a flow of nutrients and oxygen and the removal of waste products from the cell cultures. Physiologically relevant flow increases oxygen consumption, Krebs cycle activity and secretion of synthesized proteins, and decreases expression of the hypoxia HIF1 gene. Flow also improves the absorption and metabolism of compounds like benzo[a]pyrene6,8,9. The large number of recent publications reviewing organ MPS models indicates a high degree of interest by industrial and academic researchers, granting agencies and other stakeholders10,11,12,13. In addition to the stand-alone MPS, investigators are linking MPS to study organ-organ functional interactions, efficacy, PK and toxicology14,15,16,17,18.

Continue reading “Intestine, Liver, Kidney Proximal Tubule, Blood-Brain Barrier and Skeletal Muscle” »

Feb 7, 2017

Search for Synthetic-Essential Genes Uncovers Prostate Cancer Treatment Target

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

Synbio research at work and discovery.


Study of synthetic essential genes identifies a novel pathway in prostate cancer and suggests a framework for the discovery of targets in cancers harboring tumor-suppressor deficiencies.

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Feb 7, 2017

India to frame policy on synthetic biology

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

Rules placed on Synbio in India; wonder who is next?


The technology could help produce drugs, vaccines, fuel components and other chemicals.

: India is taking its first steps to evolve a policy on synthetic biology, an emerging science through which new life forms can potentially be made in labs and existing life forms, such as bacteria and other microbes, tweaked to produce specific proteins or chemically useful products.

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Feb 7, 2017

Injection could permanently lower cholesterol

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

Some people have mutations that greatly lower their cholesterol. Tests in mice suggest gene editing could give the rest of us the same protection.

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Feb 6, 2017

Quantum principles and human bio system to enhance its abilities

Posted by in categories: bioengineering, biological, biotech/medical, complex systems, disruptive technology, DNA, quantum physics, singularity, Singularity University, telepathy, theory, thought controlled, transhumanism

Recent evidence suggests that a variety of organisms may harness some of the unique features of quantum mechanics to gain a biological advantage. These features go beyond trivial quantum effects and may include harnessing quantum coherence on physiologically important timescales.

Quantum Biology — Quantum Mind Theory

Feb 5, 2017

Synbio and Biosecurity

Posted by in categories: bioengineering, genetics, quantum physics

Wait until you see how Quantum bio is applied in Biosecurity.


By guest author Devang Mehta

The world in 1918 was emerging from under the pall of a World War that had claimed 38 million lives, and yet in the span of only one year, just as many lives would be lost to the Spanish Flu an influenza pandemic that is still regarded the single deadliest epidemic in recorded history. The disease reached all corners of the world, from the Antipodes to Europe and Asia, eventually claiming 20–50 million lives. The 1918 virus caused unusually strong symptoms, described by one physician at the time as “a blood-tinged froth that sometimes gushed from (the) nose and mouth”. The disease also had an incredibly high mortality rate of 10–20%, which combined with a high rate of infection meant that up to 6% of the world’s population died due to the virus.

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Feb 2, 2017

Gene editing has saved the lives of two children with leukaemia

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

A year on and we catch up with two kids who were genetically engineered to treat their cancer. This is the future of medicine.


By Michael Le Page.

Two children treated with gene-edited cells to kill their cancers are both doing well more than a year later. The baby girls were both given the experimental treatment only as a last resort, but clinical trials of the therapy are now getting underway in children and adults in the UK.

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Feb 1, 2017

Coordinates of more than 23,000 atoms in technologically important material mapped

Posted by in categories: bioengineering, nanotechnology, particle physics, quantum physics

Nice read.


The results demonstrate that the positions of tens of thousands of atoms can be precisely identified and then fed into quantum mechanics calculations to correlate imperfections and defects with material properties at the single-atom level. This research will be published Feb 2. in the journal Nature.

Jianwei (John) Miao, a UCLA professor of physics and astronomy and a member of UCLA’s California NanoSystems Institute, led the international team in mapping the atomic-level details of the bimetallic nanoparticle, more than a trillion of which could fit within a grain of sand.

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