3D-printed monograms combine two initials in one pendant

Two initials are merged so each be read from different angles in this 3D-printed metal jewellery (+slideshow).

3D printed monogram by Mymo

Design agency Ultravirgo‘s Mymo service creates 3D monograms by digitally combining any two letters or numbers. “From the front, you see one character,” said the designers. “From the side, you see the other.” The monograms can be 3D-printed as small charms by New York company Shapeways.

3D printed monogram by Mymo

Traditionally embroidered on clothing, a monogram is a 2D graphic combining two or more letters to form a logo. Mymo transforms these motifs into a 3D form, to be printed in stainless steel, silver or ceramic.

3D printed monogram by Mymo

The steel and ceramic pieces are printed by gluing layers of the powdered materials on top of each other, while the silver designs are cast in a 3D-printed wax mould.

3D printed monogram by Mymo

The pendants can be worn as a necklace, linked to a keychain or displayed as an ornament. The Mymo typeface was designed by Ultravirgo founder Patrick Durgin-Bruce.

Here is some more information from the designer:


Mymo reinvents the monogram with 3D-printed typography

Introducing Mymo. A modern, clever monogram that combines any two letters or numbers into a custom typographic sculpture for necklaces, keychains, and ornaments (to start). From the front, you see one character. From the side, you see the other.

3D printed monogram by Mymo

Monograms used to be a badge of honor, embroidered on work shirts, towels, and stationery. But with their florid Victorian style and the move to mass production, they were left behind as an ephemeral fashion trend. But we love the concept of letters that carry personal meaning, so we’ve re-invented them.

3D printed monogram by Mymo

Twitter may allow 140 characters, but a Mymo makes a statement with just two. We challenge people to decide what two letters or numbers best represent them. Initials? Kids’ initials? The dogs’? Age? Football jersey number? Birthday date? They make the perfect gift for weddings, graduations, housewarmings, holidays, wedding attendant gifts, new babies, mothers, fathers, and just because – allowing anyone to give a gift with personal meaning without needing to know too much about the recipient.

3D printed monogram by Mymo

Mymo uses Shapeways to 3D print each item individually on-demand. The finished Mymos are made of sterling silver, stainless steel, or food-grade ceramic. Mymo makes 3D-printed objects more accessible to the public, combining great design with personalisation – without customers needing to learn how to use 3D software.

3D printed monogram by Mymo

The Mymo type was designed by Patrick Durgin-Bruce of Ultravirgo, an award-winning graphic design agency in New York City with a penchant for typography. He has also created custom type for the United Nations and the University of Pennsylvania. New typefaces by other designers are in the works for 2014.

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3D-printed tiny selfies can be ordered from your living room

News: Microsoft Kinect users can now scan themselves with the motion capture device and order a 3D-printed miniature model of themselves without leaving the house.

Developed by 3D scanning company Artec Group, Shapify.me offers a printing and delivery service for “3D Mini Me” figurines.

Tiny 3D selfies created using Kinect

To create the tiny model, users can download an app to their computer and pair the machine with their Kinect device.

Tiny 3D selfies created using Kinect

The Kinect must be positioned at chest height on the edge of a surface. The subject stands in front of the device, just over a metre away.

Tiny 3D selfies created using Kinect

After striking the desired pose, the individual scans themselves and then turns 45 degrees before scanning again. This is repeated until a full rotation has been made and the same pose has to be held throughout.

The scan is calculated and appears on the screen so it can be viewed from various angles to check if it’s okay.

Tiny 3D selfies created using Kinect

By pressing the 3D print button, the model one twentieth of the real height is ordered and delivered in the post in a matter of days. Figures can be ordered with or without a white stand.

The system is currently compatible with Microsoft Kinect for either Xbox 360 or Windows.

Tiny 3D selfies created using Kinect

The service takes the self-scanning and printing process on a stage from British supermarket chain Asda’s in-store 3D scanning and 3D printing service.

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3D-printed perfume tools by Unfold and Barnabé Fillion

Belgian design studio Unfold has created a set of 3D-printed ceramic tools for diluting and diffusing the scents of French perfumer Barnabé Fillion (+ slideshow).

The Peddler by The Peddler by Unfold and Barnabé FillionUnfold and Barnabé Fillion
Photography by Marie Taillefer

Using a ceramic 3D-printing technique the studio originally developed in 2009, Unfold produced a series of objects to dilute the perfume plus a diffuser that absorbs the liquid and dissipates the scent.

The Peddler by Unfold and Barnabé Fillion
Photography by Marie Taillefer

“The whole setup is an olfactory installation that explores the extraordinary way in which ceramics absorb, store and release a perfume’s head, heart and base notes over a prolonged time,” Dries Verbruggen of Unfold told Dezeen.

The Peddler by Unfold and Barnabé Fillion
Photography by Marie Taillefer

The printed tools include a carafe that holds distilled water, a smaller receptacle for alcohol and a high-necked flask, pipette and funnel used to dilute and mix the perfume.

The Peddler by Unfold and Barnabé Fillion
Photography by Unfold

Diluted perfume is then poured into the central core of an unglazed diffuser and gradually spreads through the multiple compartments, which create a greater surface area to absorb the liquid.

The Peddler by Unfold and Barnabé Fillion
Photography by Marie Taillefer

“The inspiration here was taken from fruit cut-throughs,” said Verbruggen. “When you cut through a lemon for example, you release its essence in the atmosphere but you also expose the intricate inner structure of the fruit.”

The Peddler by Unfold and Barnabé Fillion
Photography by Marie Taillefer

Although the diffuser will naturally release the perfume’s scent over time, the designers created an apparatus that spreads it around, “to give it an extra punch and to add a conscious gesture.”

The Peddler by Unfold and Barnabé Fillion
Photography by Unfold

Any of three different diffusers can be attached to an oak and aluminium contraption and are counterbalanced by a weight. Turning a handle causes the diffuser to rotate, releasing the scent as it spins.

The Peddler by Unfold and Barnabé Fillion
Photography by Unfold

The items are printed from fine layers of ceramic that produce a stratified surface. “The technique is very suited for intricate and complex ceramic shapes like the diffusers,” Verbruggen explained. The vessels have a layer thickness of one millimetre that results in a rough surface, while the more precise diffusers are formed from 0.5 millimetre-thick layers.

The Peddler by Unfold and Barnabé Fillion
Photography by Unfold

Unfold created the installation for the launch of Barnabé Fillion‘s perfume brand, which is called The Peddler and focuses on the experience of scent through temporary events and exhibitions. Their machine was one of several collaborations Fillion undertook with artists and designers, and he presented the results at Maison & Objet in September.

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World’s first 3D-printed metal gun successfully fired

Worlds first 3D-printed metal gun 1911 successfully fired Solid Concepts

News: an American company has built and successfully fired the world’s first metal 3D-printed gun.

Worlds first 3D-printed metal gun 1911 successfully fired Solid Concepts

American additive manufacturing firm Solid Concepts successfully fired 50 rounds using the handgun, which looks a lot closer to traditional firearms than the plastic Liberator 3D-printed gun that was first fired in May this year.

The design was based on a classic design from 1911 and manufactured using laser-sintered powdered metals. The firm says the gun “functions beautifully and has already handled 50 rounds of successful firing.”

It’s made from over 30 components printed in stainless steel and an alloy called Inconel 625, and has a selective laser sintered (SLS) carbon-fibre and nylon hand grip.

Worlds first 3D-printed metal gun 1911 successfully fired Solid Concepts

“We’re proving this is possible,” said Kent Firestone, vice president of additive manufacturing at Solid Concepts. “The technology is at a place now where we can manufacture a gun with 3D Metal Printing.”

Firestone said the point of the project was to prove to quality and suitability of 3D-printed parts for real-world applications, and even its superiority over traditional techniques: the printed parts are less porous than cast parts and could be made more made complex than machined parts.

“The whole concept of using a laser sintering process to 3D-print a metal gun revolves around proving the reliability, accuracy and usability of metal 3D printing as functional prototypes and end use products,” said Firestone. “It’s a common misconception that 3D Printing isn’t accurate or strong enough, and we’re working to change people’s perspective.”

Worlds first 3D-printed metal gun 1911 successfully fired Solid Concepts
Image courtesy of Solid Concepts Inc.

The firm chose to build the 1911 45ACP firearm because the design is in the public domain and says it is licensed to produce firearms parts.

“We’re doing this legally,” said Firestone. “In fact, as far as we know, we’re the only 3D Printing Service Provider with a Federal Firearms License (FFL). Now, if a qualifying customer needs a unique gun part in five days, we can deliver.”

Here’s some more information from Solid Concepts:


Solid Concepts, a world leader in 3D Printing services, manufactures the world’s first 3D Printed Metal Gun.

Solid Concepts, one of the world leaders in 3D Printing services, has manufactured the world’s first 3D Printed Metal Gun using a laser sintering process and powdered metals. The gun, a 1911 classic design, functions beautifully and has already handled 50 rounds of successful firing. It is composed of 33 17-4 Stainless Steel and Inconel 625 components, and decked with a Selective Laser Sintered (SLS) carbon-fiber filled nylon hand grip. The successful production and functionality of the 1911 3D Printed metal gun proves the viability of 3D Printing for commercial applications.

The metal laser sintering process Solid Concepts used to manufacture the 30+ gun components is one of the most accurate additive manufacturing processes available, and more than accurate enough to build the interchangeable and interfacing parts within the 1911 series gun. The gun proves the tight tolerances laser sintering can meet. Plus, 3D Printed Metal has less porosity issues than an investment cast part and better complexities than a machined part. The 3D Printed gun barrel sees chamber pressures above 20,000 psi every time it is fired. Solid Concepts chose to build the 1911 because the design is public domain.

The 3D Printed metal gun proves that 3D Printing isn’t just making trinkets and Yoda heads. The gun manufactured by Solid Concepts debunks the idea that 3D Printing isn’t a viable solution or isn’t ready for mainstream manufacturing. With the right materials and a company that knows how to best program and maintain their machines, 3D printing is accurate, powerful and here to stay.

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3D-printed noses for accident victims “within a year”

3D-printed prostheses by Fripp Design and Research

News: 3D-printed nose and ear replacements for accident victims and people with facial disfigurements could be just a year away, according to a design firm working on a new generation of prosthetics (+ interview).

Patients could get a customised nose or ear printed within 48 hours, rather than the ten weeks it takes to make a hand-made prosthesis, Fripp Design & Research believes.

“It’s time saving and cost saving,” the company’s founder Tom Fripp told Dezeen. “Particularly, the time-saving is great for the patient. Traditionally to have one made you’re waiting for about ten weeks for a hand-made prosthesis. From start to finish we would scan, design and print within 48 hours.”

Fripp said that the technology could be ready this time next year, although getting the health services to embrace it was the biggest challenge. “I think to actually get anywhere from now to [having an] available service you’re talking about a year,” he said. “It requires some sort of acceptance into the health services. That’s the biggest barrier to it.”

The project is being exhibited as part of the 3D Printshow Hospital at the 3D Printshow in London. The exhibition, which explores how 3D printing is transforming healthcare, also features a bio-printer that could print human cells that could eliminate the need for animal testing of new drugs.

Fripp is also working on 3D-printed eyes, which could be produced for less than £100, compared to the current price of up to £4,000 for existing ocular prosthetics.

UK-based Fripp uses colour 3D printing to create soft-tissue prostheses that can be used by patients who are missing sections of their face. Each custom prosthesis printed with bio-compatible starch and silicone will match the wearer’s skin colour, and take less than two days to produce.

“We reproduce the colour, which is an exact match for the skin tone,” Fripp told Dezeen. “Following that, we have to colour code it for the printer because if you send any colour to any standard printer, you get a totally different colour.”

The current process is lengthy and costly and involves taking an impression of the area to create a mould for the prosthesis, which then has to be hand painted and modified during fitting.

To speed this up, Fripp Design & Research are collaborating with researchers at the University of Sheffield to map the shape of the patient’s trauma area and capture skin colour data in an instant using a setup of multiple digital cameras.

The prosthetics are then designed using previous scans of the patients, if available, by mapping features from the patients’ relatives or simply taking stock files of parts like noses or ears.

“[We use] a graphic clay that we can carve away and morph to the trauma area,” said Fripp, “so we make sure we have a dead accurate fit.”

The shape is then printed with the precise colour profile using a Z Corp Z510 colour 3D printer. This will cost around the same as a handmade prosthetic, but once created the file can be used to generate multiple copies for replacements at a significantly lower cost.

3D-printed prostheses by Fripp Design and Research

Fripp admits his products are less realistic than the current models: “They’re not as high quality as a hand-made one which really are beautiful, but a patient can have this as an interim until their handmade one is actually produced.”

He says they have tested and fitted a prosthetic for a patient but that the project is awaiting medical accreditation. He believes that the people who are going to benefit the most from this process will be “individuals currently in the developing world who go without because they don’t have the money to pay for a skilled technician to build one.”

Fripp’s company is also working with Manchester Metropolitan University to produce stock batches of prosthetic eyes that patients could buy for just £30, which they also hope to be selling in a year’s time.

He also claims that his company has developed the first machine to 3D-print entirely in silicon, which will help remove the white lines that form around the edge of the protheses due to the silicon reacting with the starch.

For our one-off 3D-printing magazine Print Shift, we reported that the technology is making strides towards medical applications such as printing organs. Scientists have also printed a bionic ear that can hear radio frequencies beyond a human’s normal range.

Here’s the full interview we conducted with Tom Fripp:


Dan Howarth: How you go about printing a nose or an ear?

Tom Fripp: It starts off with a data capture, half of it, because we deal with patients who are sometimes very nervous, sometimes very agitated, we have to use a structured light system, its an instant capture. People who are nervous tend to move around and fidget, lasers take too long to produce them because they don’t stay still. So we use a colour photogrammetry system. It’s an array of cameras mounted in pads that are calibrated to know where each pod is sat. They all take a picture at the same time then they can work out the physical geometry and at the same time capture the colour.

That gives us a mesh of the area of the trauma. What that doesn’t include obviously is what you’ve got to produce to replace any trauma area which might be due to surgery or through disease. The next thing to do is to create that geometry, we can use either stock prosthetics that we have as CAD files or we can image a friend or family member and we will adjust it all to fit in 3D CAD. Or we could use CCRMI data if thats available.

There’s quite a lot of ways that we could reproduce, lets say for example a nose to make sure that it fits. We use a voxel modelling system for modelling so it’s pixels rather than surfaces or solid modelling, it uses a graphic clay that we can carve away and morph to the trauma area. So we make sure we have a dead accurate fit. Then we have to make sure we get the colour right and we do this by taking a special photometer reading from the patient, all captured at the same time. Then we reproduce the colour which is an exact match for the skin tone. Following that, we have to colour code it for the printer because if you send any colour to any standard printer, you get a totally different colour. Then the final stage is that we produce it, we actually 3D print the full colour part in starch because it’s a stable, lightweight and porous material. The processing involves forcing medical grade silicon into the starch, that brings out its final qualities and then the prothesis is ready to go to the fitter to be adjusted and fitted to the patient.

Dan Howarth: What are the benefits compared to the current methods of creating protheses?

Tom Fripp: It’s time saving and cost saving. Particularly, the time saving is great for the patient. Traditionally to have one made you’re waiting for about ten weeks for a hand made prosthesis. From start to finish we would scan, design and print within 48 hours. They’re not as high quality as a hand-made one which really are beautiful, but a patient can have this as an interim until their handmade one is actually produced.

The other benefit is that it is much more cost effective. Although the first one would cost about the same amount which is between £1500 and £3000 depending on where you are in the country. Our first one would cost about the same because of the design side. For a repeat handmade one you’re talking up to a thousand pounds. For our one it comes down to about £130 because we’ve just got a CAD file, we just press print again.

Dan Howarth: Has this been tested and used on patients yet?

Tom Fripp: No, we have fitted it to a patient to see what their response is to it but its not actually been provided out there as prosthesis yet. The main reason is that it’s difficult for products to get into the medical profession. We are an industrial design company, we’re finding an awful lot of resistance to it because traditionally, things come from surgeons and clinicians having an idea and developing it rather than an external design company doing the same.

Dan Howarth: How long do you think it will be until it’s taken up?

Tom Fripp: I think to actually get anywhere from now to available service, you’re talking about a year. It requires some sort of acceptance into the health services. That’s the biggest barrier to it.

Dan Howarth: What sort of printers do you use to print out the files?

Tom Fripp: We use Z Corp Z510s deliberately because its a much more of an open system and we can play about with the materials before, the more recent ones are more cartridge based.

Dan Howarth: How does the prothesis then attach to the face?

Tom Fripp: There’s a variety of ways. A lot of patients will already have an implant placed on the good tissue. So any bone underneath the trauma area that can be used, they all have a steel implant drilled into the bone then we can capture the orientation and location in our scanning process. Then we would produce the prosthesis with magnets actually inside the prosthesis which would just clip onto the implants. But the prosthesis is also made with a fine fitted edge which means that you can place a medical grade adhesive around this edge that reactivates when you clean it. So you can actually take the prosthesis off overnight and allow air to get to any scar tissue, clean it and then clip it back onto the implant with the medical adhesive, with a little bit of make-up round the edge, it hides it.

Dan Howarth: Who is going to benefit the most from this?

Tom Fripp: The people who are going to benefit the most from this are the individuals currently in the developing world who go without because they don’t have the money to pay for a skilled technician to build one. There are areas where technicians aren’t actually available and they would have to wait for up to a year or so to visit a more developed country where you get academics going over and starting up small clinics. It happens very regularly but you still have to wait a long time, and in most cases some still can’t afford it.

Dan Howarth: Whats next after it gains medical accreditation, could you then develop it to create other body parts?

Tom Fripp: Yes, we are currently constrained on the physical parts that we can produce so for example limbs are a bit troublesome because of their physical size. The starch material is very delicate when it comes out of the printer so a large limb might collapse when you actually try to process it. We have looked at other parts, things like replacing breasts, they are particularly difficult to produce because of the physical size of the moulds required to make them, make them incredibly heavy to process. The process is straightforward but there’s quite a lot of work to do on the material side before we can produce something that large.

Dan Howarth:: Have you got anything else in the pipeline?

Tom Fripp: For the last year and a half to two years, we’ve also been developing ocular prosthetics, replacing eyes for people. You have a similar situation with the handmade prosthetics, we’ve developed a way of full colour 3D printing them without them costing about £3000-4000, we can produce them for less than £100.

Dan Howarth: That works in the same way as the noses?

Tom Fripp: Kind of. With the ocular prosthetics, we’re actually producing them as stock parts so they’re a standardised set of 3D printed parts. At the moment, all of the ocular prosthetics are handmade and very expensive to produce whereas ours are far quicker and far cheaper. So ours will be about £30 and we can make approximately 150 in three hours on our system.

Dan Howarth: Is this project in the same stage as the noses?

Tom Fripp: The product is more refined actually and the process is pretty much complete. The materials are standard, there’s no issue with the materials. We’re currently working with Manchester Metropolitan University on that project. We starting to scale up the process for production. There’s an awful lot of interest in the product particularly from India.

Dan Howarth: How long do you think until that might be put into mass production?

Tom Fripp: I would imagine within 12 months, we should be producing this product and its should be going out to India.

I should mention, one of the problems with the soft tissue prosthetics is that starch and silicon don’t get on too well. So when you over-stress the prosthesis, you get a small white grazing line on it, which isn’t too much of a problem if you’ve got a temporary prosthesis. The only way to get around that is to eliminate the starch from the process, so for the last six months or so, Fripp Design as a company has developed its own new type of 3D printer which actually prints directly in silicone, which is a complete game changer because nobody is actually able to print in silicone and we’ve discovered a way. We have a test rig up and running at the moment and we’re producing samples and filed the patent about two weeks ago.

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3D-printed human cells could “replace animal testing”

Animal testing

News: 3D-printed human cells could replace the need for animal testing of new drugs within five years, according to a pioneering bio-printing expert at the 3D Printshow in London, which opens today.

“It lends itself strongly to replace animal testing,” said Bioengineering PhD student Alan Faulkner-Jones of Heriot Watt University in Edinburgh. “If it gets to be as accurate as it should be, there would be no need to test on animals.”

Alan-Faulkner-Jones

Faulkner-Jones spoke to Dezeen while demonstrating the technology at the 3D Printshow in London this week as part of the 3D Printshow Hospital, a feature designed to showcase medical uses of 3D printing.

Using a bio-printer made from a hacked MakerBot printer, Faulkner-Jones is demonstrating how human stem cells can be successfully printed to create micro-tissues and micro-organs that can be used to test drugs.

bioprinter-hacked-from-makerbot

The technology could be ready to replace animal testing within five years, he believes. “The micro-tissues I think would be in the order of five years away hopefully, if we carry on at the pace we are now,” he said. “You could even test personalised drugs. So you’d be able to use cells of the person that is ill and create specific micro-tissues that would replicate their response, rather than the response of a generic human.

Image of animal testing courtesy of Shutterstock.

Here’s an edited transcript of the interview with Faulkner-Jones:


Marcus Fairs: Tell us who you are and what this project is all about.

Alan Faulkner-Jones: I’m Alan Faulkner Jones from Heriot Watt University in Edinburgh and we’re working on this bio-printer to produce small human micro-tissues for drug testing and drug production to replace animal testing.

Marcus Fairs: There’s been a lot of talk about 3D printing of human tissue. How much further forward does this project take the story?

Alan Faulkner-Jones: This is a major breakthrough in the fact that we did more testing than has ever been done before on the exact physiological response of the stem cells to the printing process. A lot of people have tried to do it before and have just checked whether or not they’re still alive at the end of the process, but we checked several markers to make sure that they were still physiologically the same cells at the end as they were when they went in. So we checked the potency markers to check the stem cells were still stem cells – because if they’re not stem cells then the technology isn’t worth anything, because you’ve changed them by printing. We want it to be as non invasive as possible. So on top of the fact that we’ve been able to prove that it’s over 90% viable, the cells are physiologically identical when they come out of the printing process.

Marcus Fairs: How much does this have in common with a standard 3D printer such as a MakerBot?

Alan Faulkner-Jones: All the iterations of our technology started out as something else. The first generation model was a CNC machine, which was too big. We couldn’t do anything with it. So we made a series of these – this is the third one – and you might notice that some of the plastic bits are from a MakerBot.

Marcus Fairs: It’s hacked?

Alan Faulkner-Jones: Yeah. We rebuilt it. It has a completely new control system and everything but the plastic bits and the rails came off a Replicator 1. But the major difference of course is the print head, which is a completely different design. It’s a pressurised cartridge system which is fed into a solenoid valve with a nozzle on it. By opening and closing the valve, we can produce different volumes of fluid. And by changing the pressure and the opening time we can control the different size of droplet we produce.

Marcus Fairs: So it’s a pneumatic process rather than an extrusion process?

Alan Faulkner-Jones: Yes. The fluid is under pressure.

Marcus Fairs: Is this specifically aimed at the drug testing market?

Alan Faulkner-Jones: I’m aiming it at testing. My supervisor and some of the researchers aren’t exactly geared towards it but it lends itself strongly to replace animal testing.

Marcus Fairs: Tell us how that would work, and how soon it could be ready.

Alan Faulkner-Jones: At the moment unfortunately a lot of drugs have to be tested on animals for regulations. You have to prove that it works, which unfortunately leads to the drugs being tailored to the specific animals they’re tested on, which won’t give you an accurate response for a human. Which is why a lot of money is spent on drugs that don’t make it to market.

Marcus Fairs: They work for rabbits but they don’t work for people?

Alan Faulkner-Jones: Exactly. So they fail at the last hurdle basically. You’ve spent so long testing them on animals that they don’t work on humans. Or if they do they produce adverse side effects. So the idea is that we would produce micro-tissues of specific organs in the body and then they would have the same reaction to the physiological environment – drugs, everything – as the entire organ would do, but on a much smaller scale.

So you can apply the drug to the micro-tissue and it would give off the same result. So if it killed it or inflamed it, you’d get that response. And you could then connect a series of these micro-organs together into a system that is becoming known as “human on a chip” – so you can find the entire body’s reaction to a new drug or chemical.

Marcus Fairs: Tell us more about the human on a chip. Is that a digital chip or a biological one?

Alan Faulkner-Jones: With human on a chip you have areas on this micro-fluidic chip with a synthetic blood supply and nutrients, and introduce the drug inside each chamber, where you have micro organs that represent human organs. So you have one for the liver, the kidney, the lungs, the heart, brain tissue.

Marcus Fairs: So it’s like a chip of living tissue?

Alan Faulkner-Jones: Yes. It wold emulate the whole body’s response.

Marcus Fairs: And this could eliminate the need for animal testing?

Alan Faulkner-Jones: I hope so yes. If it gets to be as accurate as it should be, there would be no need to test on animals. You could even test personalised drugs. So you’d be able to use cells of the person that is ill and create specific micro-tissues that would replicate their response, rather than the response of a generic human.

Marcus Fairs: How far away is that?

Alan Faulkner-Jones: The micro-tissues I think would be in the order of five years away hopefully, if we carry on at the pace we are now. It’s just a matter of sorting out cell ratios at this point. We can produce cells, we just need to make sure we can get the physiological response. There are certain structures in the organs that are quite difficult to reproduce at a small level.

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Software developed to disguise 3D printing files shared online

London designer Matthew Plummer-Fernandez has developed a piece of software that allows users to visually corrupt 3D-print files so they can’t be recognised on file-sharing sites.

Disarming Corruptor for disguising 3D print files by Matthew Plummer Fernandez

Matthew Plummer-Fernandez‘s Disarming Corruptor algorithm can be used to transform and disguise STL (STereoLithography) files – which record the outer shape of an object to be printed – in a way that can be only reversed by trusted recipients with the relevant key.

Disarming Corruptor for disguising 3D print files by Matthew Plummer Fernandez

“Thingiverse lets you share 3D files – these get rendered, tagged, and exposed to the whole internet, and you don’t know who might be looking at them in the near future,” Plummer-Fernandez told Dezeen. “Patent trolls frighten me, and so do mysterious law enforcement agencies and their web-crawling technologies.”

“In a time of prolific online espionage, crackdowns on file-sharing, and a growing concern for the 3D-printing of illegal items and copyright-protected artefacts, Disarming Corruptor is a free software application that helps people to circumvent these issues,” he said, adding that the project was inspired by devices such as the Enigma Machine used to encrypt and decode messages during the Second World War.

“People could alternatively just email each other encrypted files if necessary, but I wanted to devise a system where people could utilise the benefits of a sharing site and maintain a level of privacy and personal control.”

Disarming Corruptor for disguising 3D print files by Matthew Plummer Fernandez

After downloading Disarming Corruptor, users open the file they want to distort then use slide bars to set seven values that are displayed as an encryption key at the top of the screen.

Pressing Corrupt transforms the shape according to these settings and saves the new file plus an image of the encryption key in the same location as the original. The disguised object can then be uploaded to a public file-sharing site like Thingiverse and the decoding key distributed to a few trusted people.

The last slider controls how much the form is corrupted, so the result can retain some recognisable elements. “This could be useful for instances where you might want simply make functional object inoperative until keys are shared,” the designer suggests.

Disarming Corruptor for disguising 3D print files by Matthew Plummer Fernandez

To restore the file to its original form, the recipient needs both the application and the unique seven-digit settings used by the sender. They simply open the corrupted version in the Disarming Corruptor program, move the sliders to generate the correct key in the top bar and click Repair. Entering the incorrect settings to decode the file would just damage it further.

Disarming Corruptor for disguising 3D print files by Matthew Plummer Fernandez

“I know there are a lot of harmless copyright infringements already on Thingiverse,” Plummer-Fernandez continued. “Think of all the Yoda Heads out there. These are exposed to all the patent and copyright trolls to dive in and pick out victims, and I’m sure the small print on these sharing services leaves their communities hanging out to dry when they come for them.”

“When patent trolls and law enforcement agencies find these files on sharing sites they will only see abstract contortions, but within the trusting community these files will still represent the objects they are looking for, purposely in need of repair,” he said.

Disarming Corruptor for disguising 3D print files by Matthew Plummer Fernandez

The software is free and available for Mac OSX, and Plummer-Fernandez is working on exports for Linux and Windows.

Plummer-Fernandez was born in Colombia and now lives in London, where he graduated from the Royal College of Art‘s Design Products MA in 2009, and creates his own 3D-editing tools for design projects like the 3D-printed vessels made by scanning and manipulating everyday objects that he presented this time last year.

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Doubts emerge over police “first ever 3D gun” claims

Makerbot Replicator 2 extruder alternative compared to 3D printed part found by Greater Manchester Police

News: Greater Manchester Police have issued a new statement following earlier claims that they had seized “component parts for what could be the UK’s first ever 3D gun” after the 3D-printing community pointed out they may be harmless printer upgrade parts.

“We cannot categorically say we have recovered the component parts for a 3D gun,” said the police, after Dezeen readers and technology websites raised doubts over the claims.

“I have worked with 3D-printers for several years, and I actually have that exact same printer, that’s why I recognised the parts,” said Dezeen reader Thor Henrik Bruun.

3D-printed part found by Greater Manchester Police compared to Makerbot Thingiverse filament spool holder
3D-printed “gun clip” found by Greater Manchester Police (top) compared to a Makerbot Thingiverse filament spool holder

Bruun, who lives in Norway, posted a comment on our earlier story about the police claims, saying: “These are not gun-parts. The “trigger” is a part from an Replicator 2 extruder-upgrade and the other looks like a filament spool-holder.”

Bruun posted links to the components – an extruder part listed on MakerBot’s website and a filament holder listed on Thingiverse – which he says strongly resemble items in photographs released by Greater Manchester Police this morning.

Bruun added: “I don’t have proof that these parts aren’t for nefarious uses, but using existing upgrade-parts for making a gun instead of making or printing bespoke parts seems to defeat the purpose of using a 3D-printer.”

3D printed "trigger" found by Greater Manchester Police compared to a Makerbot Replicator 2 extruder alternative
3D printed “trigger” found by Greater Manchester Police compared to a Makerbot Replicator 2 extruder alternative

On Twitter @RARA_London tweeted Dezeen commenting: “It’s a spool holder and a drive block, (modified parts of the machine itself) for anyone interested”.

An article on Buzzfeed claimed that “Greater Manchester Police haven’t seized the UK’s first 3D printed gun” while The Verge also reported Bruun’s claims.

Bruun said other members of the 3D printing community were making a similar point on Facebook. “I had a look on the GMP Facebook page also, and the top comment is (was) someone else linking to similar parts,” said Bruun.

Greater Manchester Police issued a statement earlier today titled “Component parts for UK’s first 3D gun seized,” describing how they had seized a MakerBot Replicator 2 3D printer and printed components they suspected of being gun parts.

In a new statement issued this afternoon, assistant chief constable Steve Heywood said: “We need to be absolutely clear that at that this stage, we cannot categorically say we have recovered the component parts for a 3D gun.

“What we have seized are items that need further forensic testing by national ballistics experts to establish whether they can be used in the construction of a genuine, viable firearm.

“We will also be conducting a thorough analysis of computers we have recovered to establish any evidence of a blueprint on how to construct such a weapon.

“Clearly the fact we have seized a 3D printer and have intelligence about the possible production of a weapon using this technology is of concern. It prudent we establish exactly what these parts can be used for and whether they pose any threat.

“What this has also done is open up a wider debate about the emerging threat these next generation of weapons might pose.

“The worrying thing is for me is that these printers can be used to make certain components of guns, while others can be legitimately ordered over the Internet without arousing suspicion. When put together, this could allow a person to construct a firearm in their own home.

“Thanks to Challenger, which is the biggest ever multi-agency response to organised crime in Greater Manchester’s history, we now have even greater resources to combat any emerging threats posed by organised criminal gangs, which may include the production of these weapons.Under Challenger we will a multi-agency action plan for every single organised crime group in Manchester and we will target these networks from every possible angle, hitting them where it hurts.”

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“first ever 3D gun” claims
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“3D-printed gun parts” seized by police in Manchester

3D-printed gun trigger found by Greater Manchester police

News: police have seized parts of a suspected 3D-printed gun during a raid on a property in Greater Manchester, England.

In what is thought to be the first such discovery, Greater Manchester Police officers found a plastic trigger (top image) and clip capable of holding bullets, which they believe had been 3D-printed using a MakerBot Replicator 2 that was also discovered at the property.

3D-printed gun magazine found by Greater Manchester police
Suspected 3D-printed gun clip found by Greater Manchester police. Top: 3D-printed trigger

If verified, the discovery “demonstrates that organised crime groups are acquiring technology that can be bought on the high street to produce the next generation of weapons,” said detective inspector Chris Mossop of the city’s organised crime unit.

Update: Greater Manchester Police issued a new statement following these claims after the 3D-printing community pointed out they may be harmless printer upgrade parts.

“This is a really significant discovery for Greater Manchester Police,” said Mossop. “In theory, the technology essentially allows offenders to produce their own guns in the privacy of their own home, which they can then supply to the criminal gangs who are causing such misery in our communities. Because they are also plastic and can avoid X-ray detection, it makes them easy to conceal and smuggle.”

Forensic experts are analysing whether the parts found could be used to make a working weapon, but Greater Manchester Police already believe this is the first discovery of 3D-printed gun parts in the UK.

Cody Wilson firing the first 3D-printed gun.
Cody Wilson firing the first 3D-printed gun.

The world’s first 3D printed gun was successfully fired in May this year by US anarchist Cody Wilson, triggering a global debate about the social and ethical impact of 3D-printing. Wilson’s gun was acquired by the V&A museum in London last month.

The V&A Museum in London bought Cody Wilson's 3D-printed gun
The V&A Museum in London bought Cody Wilson’s 3D-printed gun.

“There’s been a lot of technocratic optimism around 3D printing, particularly in the design world,” senior V&A curator Kieran Long told Dezeen in an interview about the acquisition. “I don’t believe everyone should be carrying guns and that’s not what we’re advocating here. What we are saying is this is possible and we might have to do something about it if we don’t want these things to happen.”

“These could be the next generation of firearms and a lot more work needs to be done to understand the technology and the scale of the problem,” said Mossop. “If what we have seized today can, as we suspect, be used to make a genuine firearm then today will be an important milestone in the fight against this next generation of homemade weapons.”

A MakerBot Replicator 3D-printer was found at the crime scene.
A MakerBot Replicator 3D-printer was found at the crime scene.

MakerBot’s Replicator 2 printer went on sale earlier this summer. Open-source designer Ronen Kadushin warned last year that 3D printers could allow people to “print ammunition for an army”.

Read our feature on how 3D-printed weapons are transforming warfare.

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Mycelium Chair by Eric Klarenbeek is 3D-printed with living fungus

Dutch Design Week 2013: designer Eric Klarenbeek has 3D-printed a chair using living fungus, which then grows inside the structure to give it strength (+ slideshow)

Mycelium Chair by Eric Klarenbeek

The chair is the result of a collaboration between Klarenbeek and scientists at the University of Aachen to develop a new way of printing with living organisms. “Our main purpose  was to bring together the machine and nature to create a new material that could be used to make any product,” Klarenbeek told Dezeen.

Samples for Mycelium Chair by Eric Klarenbeek
Research samples

The result is a new material that, Klarenbeek believes, could be used to make almost anything in future. “It could be a table, a whole interior or even a house,” he said. “We could build a house with it.”

Segment of 3D-printed Mycelium Chair by Eric Klarenbeek
3D-printed segment of bioplastic shell

Presented at Dutch Design Week in Eindhoven this weekend, the Mycelium Chair was printed using a mixture of water, powdered straw and mycelium, which is the thread-like part of a fungus that lives underground.

Segment of 3D-printed Mycelium Chair by Eric Klarenbeek
3D-printed segment of straw core

The mycelium grew within the structure, replacing the water and creating a solid but extremely lightweight material. Mushrooms began sprouting on the surface, at which point Klarenbeek dried out the structure to prevent further growth.

Scale model of 3D-printed Mycelium Chair by Eric Klarenbeek
Scale model

“When you dry it out you have the straw kind of glued together by the mushroom,” Klarenbeek said. “You have this strong, solid material that is really lightweight and durable.”

A thin layer of printed bioplastic covers the structure of the chair to contain the growing fungus. Straw was used as a substrate since the fungus used in the project – the yellow oyster mushroom – likes to grow on straw.

Scale model of 3D-printed Mycelium Chair by Eric Klarenbeek
Scale model

“The mushrooms are only a decorative element,” said Klarenbeek. That’s why we shot the photograph with the mushrooms popping out. Our main purpose was to bring together the machine and nature to create a new material that could be used to make any product.

3D-printing straw substrate for Mycelium Chair by Eric Klarenbeek
3D-printing straw substrate

“This chair is really a metaphor for what could be made with this technique of 3D printing a living organism and then have it grow further. It could be a table, a whole interior or even a house. We could build a house with it.”

Here’s some text from Klarenbeek:


Studio Eric Klarenbeek most recent project is the Mycelium Chair, a chair in which 3D printing and growing material are combined. 

Designer Eric Klarenbeek interest is combining materials in unexpected ways. Klarenbeek is exploring ways of making 3D prints of living organisms, such as mycelium, the threadlike network in fungi.

3D-printing straw for Mycelium Chair by Eric Klarenbeek
3D-printing straw

He uses experimental raw materials for printing material: organic substrate for mushroom growing and bioplastics. Working with scientists, Klarenbeek has printed a chair from straw, with a thin coating of bioplastic.

Once it is mature it should be strong enough to support a person. The chair is a metaphor for what can be achieved with materials and production methods.

Thanks to: CNC Exotic Mushrooms, Wageningen UR ⋅ Plant Breeding ⋅ Mushroom Research Group, Beelden op de Berg

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is 3D-printed with living fungus
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