Skip to main content

You can now buy BioBots’ human tissue 3D printer for a mere $10K

biobots launches biobot 1 3d human tissue printer biobots1
BioBots
Despite the growing number of organ donors in the United States, wait times for organ transplants tend to be absolute nightmares. Expected wait times for, say, a liver transplant typically hover around five years, with some states’ lists pushing transplant waits to nearly a decade. Understanding this for the massive problem it is, a Philadelphia-based startup named BioBots burst on the scene last spring armed with one incredibly revolutionary idea: develop and manufacture a 3D printer capable of printing real human tissue.

Not merely a pipe dream of a concept, BioBots physically demonstrated its plan at TechCrunch Display in New York last May by 3D printing a nearly exact replica of Vincent Van Gogh’s famous severed ear. After stunning the crowd in attendance that day, BioBots has since partnered with roughly 50 research facilities around the globe, according to an interview CEO Danny Cabrera gave Quartz. Not only has this partnership allowed for an incredible amount of research and development of the tech, but it’s allowed BioBots to officially launch its first, commercially available bioprinter, the BioBot 1. Basically, anyone who ponies up $10,000 in cash has the ability to buy their very own human tissue 3D printer. Where do we sign?

Though BioBots isn’t nearly the first company to attempt to create a 3D printer capable of producing human tissue, the key difference in its approach lies with the kind of bio-ink it utilizes. Essentially, this ink contains what’s called photoinitiator powder, which solidifies after its hit with a certain wavelength of blue light. This process allows the machine to print biomaterial without the need for UV light or pressure, which many biofabrication devices currently require. During the company’s recent research phase, Cabrera and his team made this unique bio-ink open-source, giving researchers in the field unfettered access to improve or develop new tech.

What makes the BioBot 1 particularly fascinating to the world of organ transplants is the fact BioBots outfitted the machine with two extruders. These extruders allow the machine to build complex structures (e.g., organ tissue, blood vessels, etc.) of which Cabrera believes could even be utilized for testing new drugs in the future. In addition to hoping the BioBot 1 shows up in labs across the world, he also thinks it could one day completely wipe out the organ transplant waiting list.

No matter how revolutionary BioBots’ human-tissue printer is, the U.S. Food and Drug Administration has yet to provide much information regarding its approval. Back in February, however, the FDA did tell Quartz it was currently considering the tech with a “significant scientific interest,” though an estimation on when it would issue an approval is still unknown. Though, regardless of the FDA’s approval or not, there’s no denying just how incredibly useful 3D-printing human tissue will inevitably prove to be.

Making BioBots’ innovative 3D printer available for public consumption is a massive step in the right direction toward seeing this tech begin to make a real difference. It’s literally just a matter of time before organ transplant candidates will not only receive relief sooner, but will have the ability to see their organs printed right before their very eyes.

Rick Stella
Former Digital Trends Contributor
Rick became enamored with technology the moment his parents got him an original NES for Christmas in 1991. And as they say…
Wild new 3D printer makes parts by sending titanium particles supersonic
3D printing metal technique

Regular layer-by-layer 3D printing is old news compared to a new additive manufacturing technique developed by an international team of engineers. They recently demonstrated an innovative method for printing 3D metal objects by firing a powder that’s composed of tiny titanium particles, at supersonic speed, so that they fuse together in any interesting way.

This “cold spray” approach takes place below the melting temperature of the metal. When the particles hit the substrate at high enough velocity, they deform and adhere to it. The efficiency of this adhesion increases as the particle velocity increases. Without the high-speed impact, metal powders would simply not adhere well.

Read more
GPS-tracking, 3D-printed decoy eggs can help root out illegal poachers
Decoy turtle eggs

Poachers pose a major threat to sea turtle nests by stealing eggs to sell in what has become a rampant black market trade in certain parts of the world. Conservation efforts to stop this have, to date, included patrolling beaches for would-be poachers, as well as removing the eggs and placing them in a secure hatchery so that they can be incubated in safety.

Conservationists at the nonprofit organization Paso Pacifico in Nicaragua and researchers from the U.K.’s University of Kent have another idea, however -- and it involves 3D-printed decoy eggs, boasting built-in GPS trackers.

Read more
Printable wood biopaste could be the sustainable future of 3D printing
Biopaste 3D printing

Researchers at Germany’s University of Freiburg may have found a way to make 3D printing a bit more environmentally friendly -- by printing with a new material best described as a wood-based biopaste. After all, who needs boring, unsustainable plastics when you’ve got an alternative that works impressively well, made out of wood biopolymers cellulose and lignin?

Marie-Pierre Laborie, the lead researcher on the project, told Digital Trends that creating the printable material is straightforward. “We put each component, a cellulose-based derivative and lignin, into [a] solution and blend the two … to form a sort of paste of high-solid content,” Laborie said. “At [a] particular solid content and composition, we retain the lyotropic liquid crystalline behavior of the cellulose derivative. This facilitates the processing of the paste. The paste then solidifies thanks to the stabilizing effect of the lignin upon 3D printing.”

Read more