Lifeboat Foundation

Bioprinting has been all over the news in the past several years with headline-worthy breakthroughs like printed human skin, synthetic bones, and even a fully functional mouse thyroid gland.

3D printing paved the way for bioprinting thanks to the printers’ unique ability to recreate human tissue structures; their software can be written to ‘stack’ cells in precise patterns as directed by a digital model, and they can produce tissue in just hours and make numerous identical samples.

Despite the progress in bioprinting, however, more complex human organs continue to elude scientists, and resting near the top of the ‘more complex’ list are the kidneys.

Continue reading “Bioprinting Is One Step Closer to Making a Human Kidney” »

After 3D-printing a mouse thyroid gland and successfully transplanting it last year, Russia’s 3D Bioprinting Solutions is aiming to make a human kidney by 2030, the company’s scientists told Sputnik.

© Sputnik/ Sergey Guneev

Continue reading “Stamping Out Disease: Russian Scientists Aim to Bioprint Human Kidneys By 2030” »

Lenses with a surface accuracy in the nanometer range are behind ever more accurate laser and optical systems. Manufacturers depend on ultra-precise optical and mechanical ablation processes, innovative coating processes and extremely accurate measuring technology to venture into these nano-worlds. The latest trends in optical manufacturing will be showcased by the world’s leading trade fair LASER World of PHOTONICS, from June 26–29, 2017 in Munich.

Nanoscribe GmbH’s 3D printing process creates three-dimensional micro and nano lenses from photosensitive coatings. The structures are built up a pulse at a time by highly focused femtosecond lasers employing two-photon polymerization. Source: Nanoscribe GmbH

The diversity of lenses, their shapes, sizes and materials is growing all the time. Applications in non-visible wavelengths from x-rays and ultraviolet to the far infrared also require special optics, such as material processing using short pulse and ultrashort pulse lasers or imaging techniques in the medical and research fields and industrial quality control.

Continue reading “Ultra-precision in optical manufacturing” »

A collaboration between Russia’s Foundation for Advanced Research Projects and the Central Scientific – Research Institute for Precision Machine Engineering known as TSNIITOCHMASH has produced 3D printed bullets.

The Foundation formed in 2012 serves as an advanced research facility for military projects, an equivalent of the American DARPA. The project, conducted by the Foundation’s Laboratory of Additive Technologies and Design materials used selective laser melting technology to create an experimental batch of bullets. This same batch of bullets was then successfully fired.

According to the head of the laboratory, Doctor of Physical and Mathematical Sciences, Professor Vladimir Chuvildeeva, the current development team was formed more than ten years ago at the University of Nizhni Novgorod. The team has become specialized in developing laser alloying technology to develop complex physical models. Their end goal is being to develop equipment much more sophisticated for military purposes.

Continue reading “Russian Researchers Learn How to 3D Print Bullets” »

Excellent! Now, imagine how this technology can be used to improve synthetic diamond quality for things such as 3D printing of syn. diamonds used by QC, Quantum light networks, etc.

Machines can take over from gemologists in grading 2 of the gems’ famous 4 C’s, says Sarine Technologies.

Continue reading “Israeli tech lets diamonds’ true colors, and clarity, shine through” »

A woman living on a dialysis machine is grown a new kidney using her own cells. A father struggling with age-related vision loss has his eyesight restored. A soldier suffers extensive burns and has his skin regenerated.

This is a glimpse of the holy grail of regenerative medicine. The ultimate goal of the field is to develop therapies that restore normal function to diseased tissues and organs. Advances in 3D bioprinting, the process of fabricating functional human tissue outside the body in a layer-by-layer fashion, have pushed the envelope on what is considered possible in the field.

Continue reading “Printable Organs Will Put an End to Transplant Lists” »

I see many uses of this material already in security, defense & intelligence, devices and energy related products, etc. Contracts as it heats up.

Qiming Wang’s team designed a unique manufacturing technique using 3D printing.

In Brief:

• New artificial blood vessels were able to grow with the recipient in recent animal testing
• Researchers saw a 56% increase in diameter made of patients’ own cells.

We have sufficiently advanced medicine to the point that artificial body parts are no longer science fiction. In fact, we may even start 3D printing organs, or have them grown in a lab. However, their artificial nature often means they won’t grow with a patient. For example, children need to undergo repeated surgeries until adulthood to replace implants they have outgrown.

Bioprinting is becoming more sophisticated daily. Students from Munich, Germany, hacked an Ultimaker 2+ to 3D print biomaterials even more efficient. Without a doubt, the yearly iGEM challenge is one of the yearly highlights for students in the field of biology, biochemistry, and biotechnology.