Calling it a necroprinter is equal parts ominous and spectacular.
And then you find that the inks they've tried it with are solutions of cancer cells.
The necroprinter prints cancer.
Reminds me of something from Warhammer 40k universe. Next someone is going to put ChatGPT helper inside a human skull, probably :V
In the future, when humans die, their neurons will be sold and repurposed in local AI's.
“Oh, look, he’s dead. Let’s sell his neurons.” The neuron harvester says as he wipes the blood from his knife.
It is silly. By that standard, your leather shoes should be called necrofootwear.
hopefully the name will stick, as it realy is ,,ominous and spectacular ,,and will get people thinking about what might come next
didn't elon say that hands and fingers are the hardest part of making robots?
peasants under technofeudalism don't really need those parts anyway, since we'll be evolving into vat people with brain chips soon in the new necropia
> didn't elon say that hands and fingers are the hardest part of making robots?
Not a problem for a dancer in a robot suit though.
"Hi, i'd like some dead nozzles for my necroprinter please. What do you mean i can only pay with SoulCoin?"
They say the mosquito proboscis has a 20 μm inner diameter, "100% finer" than commercial alternatives (presumably meaning half the diameter). Not having read the paper, I'm guessing it can't handle 210° molten PLA.
From the paper:
> The ink used for the proof of extrusion demonstration is a ready-to-use, polyethylene oxide–based training bioink purchased and used directly from the vendor (Cellink Start, Cellink)
> The ink used for the honeycomb demonstration and the maple leaf demonstration is a sacrificial, temperature-sensitive, 40% (w/v) Pluronic F-127 in deionized water bioink purchased and used directly from the vendor (Pluronic F-127, Allevi).
> The ink used for the first cell-laden grid demonstration is Pluronic F-127 bioink with B16 cancer cells suspended in solution.
> The ink used for the second cell-laden grid demonstration is Pluronic F-127 bioink embedded with RBCs.
> The ink used for the cell viability experiments is Pluronic F-127 bioink with B16 cancer cells suspended in solution.
Aha, thanks! That makes a lot of sense.
From TFA, they're using it to print bioinks. Think scaffolding for cell cultures.
At these kinds of physical scales, biology is almost certainly a much larger market than mechanical applications. A 20 um line width (slightly less than one thou for US folks) is certainly a tolerance you might encounter on a drawing for subtractive manufacturing, but for addative, feature sizes that small will be strength limited.
Mechanical applications at that scale are not well developed, but that doesn't mean their potential is small.
Member sizes below the critical diameter for flaw-sensitivity are crucial to the hardness and durability of, for example, human teeth and limpet teeth, as well as the resilience of bone and jade. Nearly all metals, glasses, and ceramics are limited to a tiny percentage of their theoretical mechanical performance by flaw-sensitivity.
Laparoscopes that require smaller incisions are better laparoscopes. Ideally you could thread in a biopsy-needle instrument through a large vein to almost anywhere in the body.
Visible-light optical metamaterials such as negative-index lenses require submicron feature sizes.
I know a research group that is gluing battery-powered RFID transponders to honeybees.
Electrophoretic e-paper displays are orders of magnitude more power-hungry than hypothetical MEMS flip-dot displays. We just don't have an economical way to make those.
And of course MEMS gyroscopes, accelerometers, and DLP chips are already mass-market products.
There's still a lot of room at the bottom, even if EUV takes thetakes purely computational opportunities off the table.
I can’t wait for MEMS flip-dot displays.
"They mounted the mosquito proboscis on a standard dispensing tip and used it to deposit specialized bioinks.", "They then successfully printed bioscaffolds used to support cell growth and high-resolution microstructures".
Tissue-printing type stuff, not plastic
I wonder if at scale this will lead to mosquito farms or to mosquito extinction in nature.
Of course I suspect it will be the former but the latter is way funnier.
We've been stuck with these insects for a while. It would be so funny that the solution to get rid of them was in fact the same that wiped out many species before: over exploitation of natural resources.
I mean, ideally it would lead to both. We can wipe out the farmed mosquitos when we find something else that produces similar tubes.
Our most successful efforts at wiping out wild mosquitos, though, don't produce useful corpses. So I don't think it's particularly realistic for high industrial demand to lead to mosquito extinction anyway.
This is cool and great and all, but isn't it a bit ... stretched to motivate this by the fact that the nozzle is biodegradable?
I mean for a printing nozzle with an inner diameter of 20 µm, how much material would be wasted if it was made out of plastic or metal? I get that no such nozzle is available and/or easily made, but shouldn't that be the point of the invention, rather than "yay, it's biodegradable so we save a microgram of plastic/metal"?
Yes, it's silly. They surely use orders of magnitude more consumables (latex gloves, plastic bottle tops for chemicals...) in preparing a batch of mosquito proboscides than the hypothetical nozzle would take up.
The university's marketing department has been instructed to emphasize sustainability in its press releases, and the website reporting it has, like most news organisations that have survived, made the choice not to hire journalists with critical thinking skills but to have them rephrase press releases.
I'm so disappointed they didn't print a tiny benchy in their videos.