IBM Creates MRI With 100M Times the Resolution

An anonymous reader writes "IBM Research scientists, in collaboration with the Center for Probing the Nanoscale at Stanford University, have demonstrated magnetic resonance imaging with volume resolution 100 million times finer than conventional MRI. This result, published today in the Proceedings of the National Academy of Sciences, signals a significant step forward in tools for molecular biology and nanotechnology by offering the ability to study complex 3D structures at the nanoscale."

High levels of radiation

[Light+and+Truth]

This is a concerning development for those who have been following the advancement of science (MRI Technology). One of the undocumented effects (intentional) of MRI is "direct particle insertion" where the resonance of strong magnetism can be used to transport matter particles as energy through short distances and reassembled within confines of enclosed cavity (skull or chest). This is DOCUMENTED FACT as established by Dr. Paul C. Lauterbur in 1971 through research papers (suppressed as unpublished). With current levels of technology there is too much diffusion by radio waves to take advantage of timing effects due to low resolution. Experiments are performed DAILY to eliminate high levels of interference (government frequencies) but none could prove beyond a doubt a way to perfect a technique for changing neurons due to the small size (can be seen with the strongest microscope only). Having mapped a human brain (genomics) with fine resolution permits modification of magnetic waves to CREATE AND DESTROY thought. This tech was five years to deployment but has been accelerated for widespread acceptance (planned by bureaucracy).

Re:High levels of radiation

[Evanisincontrol]

Please inform us if you are serious or joking so you can be modded appropriately. I hope it's the latter.

Re:High levels of radiation

[im_thatoneguy]

My understanding of this specific MRI technology is that its applications are similar to that of an electron microscope.

Unless you plan on crawling into a pitri dish your precious little thoughts should be safe. You don't even need tinfoil!

Re:High levels of radiation

[HTH+NE1]

The Doctor: Um, that big, erm, machine thing - is it supposed to be making that noise?
Florence Finnegan: You wouldn't understand.
The Doctor: But isn't that a magnetic resonance imaging thing? Like a ginormous sort of a magnet? I did Magnetics GCSE. Well, I failed, but all the same...
Florence Finnegan: A magnet with its setting now increased to 50,000 tesla.
The Doctor: Ooh, that's a bit strong. Isn't it?
Florence Finnegan: It'll send out a magnetic pulse that'll fry the brain stems of every living thing within 250,000 miles. Except for me. Safe in this room.
The Doctor: But hold on, hold on. I did Geography GCSE. I passed that one. Doesn't that distance include the Earth?
Florence Finnegan: Only the side facing the moon. The other half will survive. Call it my gift.

Re:High levels of radiation

[sams67]

The big letters mean it MUST be TRUE.

Re:High levels of radiation

[SigmaTao]

Your brain has to be prepared - Diced.... But don't worry we will give you a replacement - a simple one should suffice :-)

Re:High levels of radiation

[philspear]

This is DOCUMENTED FACT as established by Dr. Paul C. Lauterbur in 1971 through research papers (suppressed as unpublished)

Aha, an undocumented documented fact. Well, I'm convinced.

Re:High levels of radiation

[Dunbal]

You forgot the bit about the Time Cube!

Re:High levels of radiation

[GeckoAddict]

With a user ID of 1444615 and that being the only post... I seriously doubt they're joking, which is a sad fact in itself.

Re:High levels of radiation

[Ethanol-fueled]

Or maybe it's their professional trolling debut!

Re:High levels of radiation

[HTH+NE1]

The only thing wrong with that was that it stole a basic Star Trek trope, the "reversal of polarity".

I was about to object, but then checked the dates and Star Trek (original series) does predate the Third Doctor's "reverse the polarity of the neutron flow" (1966-1969 vs. 1970-1974).

Instead I say, well played sir!

Re:High levels of radiation

[HTH+NE1]

You forgot the bit about the Time Cube!

And being invented by Shampoo!

(A gift of peace in all good faith.)

Re:High levels of radiation

[The+Great+Pretender]

I also HEARD that another SIDE EFFECT was the unbridled NEED to write in CAPS to try and DRIVE home a POINT. NEXT comes the DESIRE to add a lot of EXCLAIMATION marks to EVERYTHING!!!!!!!!!!!!!!

This is great to see

[Zouden]

Now if only HP and AT&T would bring back their R&D departments we might see more companies doing basic research like this.

Re:This is great to see

Don't worry Sam Palmisano is doing his best to destroy IBM. Under his so called leadership morale has dropped to lows never seen. Everything is being cut even R&D. Latest rumors are 16,000 most US based to be laid off on Jan 23.

uploading

[hedley]

Now we are getting closer. Once you can extract the raw brain data, you can simulate the data. You can 'live' forever if they can get the raw data out.

Adapting inputs to the simulation and that simulation can interact with you...

H.

Re:uploading

[jellomizer]

But would you want to live forever in a Windows Vista Box. You are thinking naughty things, cancel or allow.

Re:uploading

[jellomizer]

Yea but it would be pronounced so loud, that everyone would know.

Interesting!

[girlintraining]

I wonder if it can resolve individual dendrite connections in the brain. If so, we've just developed our first brain scanner capable of mapping a living brain's circuitry. Which means, in principle, we now possess all the technology required to model a human brain, or for that matter (but at extreme cost), create a synthetic one. Though, at present, we have no way of truly providing it with the interface necessary for communication or interaction with the physical world.

Re:Interesting!

This device won't work on large samples (think brain) because the detection mechanism is a microcantilever. It will work for small particles, since the resonant frequency of the cantilever can remain high with only a small mass on the end. Large objects will simply make the detector extremely slow and insensitive. While a whole brain won't work, I'd expect a few cells or small tissue sample might be possible to image, giving impressive detail on the chemical pathways in the cell and between cells.

Re:Interesting!

[zalas]

You need temporal resolution on the order of one second or less in addition to spatial resolution for most brain imaging. Standard MRI scans essentially scan frequency space of the specimen, which takes some time. The article doesn't say what time resolution their new technique has.

Re:Interesting!

[popeye44]

Great, All I need is a machine which ignores me.. then 5 minutes later wants something but isn't happy with whatever I give it. randomly scratches the shit out of me and takes off running like it's ass is on fire. No Thanks.

Re:Interesting!

[Sponge+Bath]

...simulating a cat brain

No problem:

for (;;) {
        for (i=1000 ; i ; i--)
                printf("meow\n");
        cough_up_hairball();
}

Re:Interesting!

[ViennaSt]

Unfortunately, this 3D MRI can not be applied to imaging the human brain yet.

One problem is that though this machine has great spatial resolution (precision in space)....it may not have great temporal resolution (precision in time).

In regards to your curiosity about imaging dendritic connections: It may image where/how the connections are made, which is a great leap for Neuroanatomists. But it cannot measure or record the hundreds of thousands of mechanisms and live actions that the dendrites/axons/cell bodies and their connections make during every one action potential that takes place...Even if this machine could measure outside the nanoscale.

Here's why: Neurons may fire a number of action potentials in millisecond time and increase/decrease in volume as the influx of sodium brings in water into the cell causing it to expand. As enough sodium (positively charged particals) are in the cell causing a depolarization, the voltage-gated ion channels shut off and K+ outflux/Na+ influx ceases. The cell hyperpolarizes, shrinks in volume and it's morphology is changed drastically once again. To capture all this change with such fine resolution is a feat, that sadly, cannot be accoplished by this 3D Machine--since everything it measures must be fixed and perfectly still. What neuroscientist use now for "partial real time brain imaging" is a function MRI or fMRI which measure changes in metabolism (glucose metabolism to be exact) but compromises the great spatial resolution this 3D machine has for the temporal resolution.

Re:Interesting!

[Dice]

I think you need a call to rand(), a switch statement, and some additional function calls like sleep_in_sun(), eat(), shit(), scratch_aimlessly_at_litter(), tear_through_the_house_for_no_apparent_reason(), etc.

Re:Interesting!

[Directrix1]

Are you talking about a cat or a wife?

Re:Interesting!

[Z34107]

I think you need a call to rand(), a switch statement, and some additional function calls like sleep_in_sun(), eat(), shit(), scratch_aimlessly_at_litter(), tear_through_the_house_for_no_apparent_reason(), etc.

It's C. The cough_up_hairball() function has undocumented side effects, including all of he aforementioned.

Additionally, after 0, the i register underflows when compiled with a particular gcc switch, setting the carry flag and incrementing a pointer in another register. This modifies the LSB of a pointer to an entry in a 256-entry lookup-table that is randomly populated with function pointers which also call those functions. After UNSIGNED_INT_MAX NOPs, the loop starts again.

Now, in C++, he could have just overloaded the "<<" operator to do all of that.

Re:Interesting!

[jstockdale]

It's C. The cough_up_hairball() function has undocumented side effects, including all of he aforementioned.

Now, in C++, he could have just overloaded the "<<" operator to do all of that.

Well, at least it's better than cat implemented in Java:

AnimalInstance ourCat = new Cat
ourCat.meow()
ourCat.sleep_in_sun()
ourCat.eat()
ourCat.tear_through_house_for_no_apparent_reason()
java.lang.OutOfMemoryError: Java heap space
at
org.slashdot.animal.Cat.tear_through_house_for_no_apparent_reason() ...

*sigh* Oh Java.

Re:pr0n!

[sanosuke001]

we can SEE the herpes virus enter the skin during penetration now! I don't need 1080p, I need HSVp!

Storage Monster

[bananaquackmoo]

Good lord I don't want to see the required storage space for each file on that thing...

High resolution but small volume

[kebes]

The actual scientific paper is:
C. L. Degen, M. Poggio, H. J. Mamin, C. T. Rettner, D. Rugar Nanoscale magnetic resonance imaging PNAS 2009, doi: 10.1073/pnas.0812068106.

The abstract:

We have combined ultrasensitive magnetic resonance force microscopy (MRFM) with 3D image reconstruction to achieve magnetic resonance imaging (MRI) with resolution <10 nm. The image reconstruction converts measured magnetic force data into a 3D map of nuclear spin density, taking advantage of the unique characteristics of the 'resonant slice' that is projected outward from a nanoscale magnetic tip. The basic principles are demonstrated by imaging the 1H spin density within individual tobacco mosaic virus particles sitting on a nanometer-thick layer of adsorbed hydrocarbons. This result, which represents a 100 million-fold improvement in volume resolution over conventional MRI, demonstrates the potential of MRFM as a tool for 3D, elementally selective imaging on the nanometer scale.

I think it's important to emphasize that this is a nanoscale magnetic imaging technique. The summary implies that they created a conventional MRI that has nanoscale resolution, as if they can now image a person's brain and pick out individual cells and molecules. That is not the case! And that is likely to never be possible (given the frequencies of radiation that MRI uses and the diffraction limit that applies to far-field imaging.

That having been said, this is still a very cool and noteworthy piece of science. Scientists use a variety of nanoscale imaging tools (atomic force microscopes, electron microscopes, etc.), but having the ability to do nanoscale magnetic imaging is amazing. In the article they do a 3D reconstruction of a tobacco mosaic virus. One of the great things about MRI is that is has some amount of chemical selectivity: there are different magnetic imaging modes that can differentiate based on makeup. This nanoscale analog can use similar tricks: instead of just getting images of surface topography or electron density, it could actually determine the chemical makeup within nanostructures. I expect this will become a very powerful technique for nano-imaging over the next decade.

Re:High resolution but small volume

[jd]

Just out of curiosity... if you can image specific viruses in a sample of, say, blood, then would it be possible to do extremely reliable blood screening of any and all known viruses by matching the reconstituted image of each object (or a suitably long cryptographic hash thereof) against a database of known viruses? One of the problems with identifying specific viral strains seems to be that it takes an extremely long time, often relies on the detection of the antibodies rather than the viruses themselves (which doesn't seem reliable, and has produced many stories purporting specific people are immune to viruses those people subsequently die from), and just seems to be all-round a really bad idea if you can avoid it.

If this MRI scanner can image a virus in 3D in such a way that modeling software (possibly with human aid) can isolate the virus and perform a direct match-up, it would seem that you should be able to screen for the virus (a) long before the immune system has detected anything, and therefore before an immune response has occurred, and (b) much more reliably (it should be hard to fool an MRI at this resolution, whereas bacteria and viruses fool the immune system all the time).

However, this line of reasoning is highly dependent on the assumption that the imaging can produce some images that are detailed enough that you can classify things automatically or semi-automatically, but not so detailed that "noise" (irrelevant variations) prevent identification. It is also highly dependent on the assumption that by "3D imaging", they mean images where the component objects can be separated in 3D space, rather than being a 3D "soup" that a trained expert can (eventually) pick objects out from. There are probably other assumptions in there that seem so obvious I'm missing that they're even there.

Even if this is possible (which is a big if), there are any number of factors (price, portability, energy costs, robustness, ease of maintenance, etc) which might preclude it from being used in practice in this way, except perhaps in the case of something particularly dangerous and new. I imagine SARS might have taken less time to classify, had this been available at the time of the initial breakout, assuming I'm correct about how good it is. HIV took even longer to identify, and the cause of CJDnv is only thought to be prions, there is no direct evidence of this - evidence this scanner could possibly provide. (Along, maybe, with an explanation for the other new CJD strain that is affecting Americans.)

Link to the PNAS abstract

[FilipeMaia]

http://www.pnas.org/content/early/2009/01/12/0812068106.abstract

Transporter?

[RetroGeek]

I wonder if this is fine enough to be able to distinguish the type and state of a molecule. If so, then you should be able to scan an entire person and store the result.

Then at a later date (when the technology becomes available) you should be able to re-create that person.

The beginnings of a transporter.

Re:Transporter?

[zippthorne]

Indeed. A transporter that works like the visible man.

Step 1: die. (not strictly necessary, but makes the remaining steps more pleasant.)
Step 2: freeze body in great big ice cube. agitate and freeze rapidly to avoid bubbles and crystals.
step 3: put ice block on giant deli slicer. Use "1 cell thick" setting.
step 4: further divide ice slice into pieces small enough to use with the MRI device. Carefully label the position of each piece.
step 5: painstakingly scan each piece and store in appropriate database.
step 6: repeat steps 3 through 5 over the next several months until no slices remain.
step 7: ?
step 8: arrive at destination, nearly perfectly reconstructed and only a little bit dead (just your brains. and organs)

Re:Transporter?

[Eudial]

I wonder if this is fine enough to be able to distinguish the type and state of a molecule. If so, then you should be able to scan an entire person and store the result.

Then at a later date (when the technology becomes available) you should be able to re-create that person.

The beginnings of a transporter.

Unfortunately, Heisenberg's uncertainty principle dictates that in scanning the position of the particles, you also change their state. You can in short never know everything you need to know about a system to identically replicate it elsewhere.

Re:Transporter?

[jackchance]

It isn't clear whether the quantum uncertainty of the particles is relevant for reconstructing a biological organism.

It's true that the precise location of individual ions would be slightly misplaced. However, as long as the wiring of neurons was accurately recreated it might work.

So while the 'recreated' organism would not be 'exactly' the same as the scanned organism, it might be good enough.

Re:Transporter?

[sdpuppy]

So while the 'recreated' organism would not be 'exactly' the same as the scanned organism, it might be good enough.

Hey - that's what my wife tells me all the time!

Re:Isn't this just....

[reverseengineer]

What it amounts to is an atomic force microscope combined with a magnetic needle that allows it to perform proton NMR. An AFM is a pretty general and adaptable technique- the key element is the cantilever system that allows you to detect a tiny amount of force exerted on atoms in a sample; how you supply that force, via magnetic resonance, van der Waals forces, the Casimir effect, etc., makes it versatile. The significant drawback of this instrument is that it is a supermicroscope, not a macroscale scanner like a medical MRI machine. Samples are usually limited to a surface area of a few hundred square microns. The resolution achieved here is impressive, but is best understood as an advancement in microscopy. Just as with a light microscope or an electron microscope, this is a technique for scanning cells, not bodies.

But the real question is:

[Mr_eX9]

Has this IBM invention patented itself yet?

Re:But the real question is:

No, the real question is: Does go BING?

not a valid comparison

[Viking+Coder]

kebes already pretty much said it, and as I said (under a different name) on Digg,

Saying "100 million times stronger than MRI" is a deceptive way to describe this. The normal usage of MRI that the public is familiar with is to scan your body, or parts of your body. This new technology would work on a "sample," for instance a biopsy. If the new technology operated at the same scale - your whole body - and was at 100 million times finer resolution - then that would be astounding.

But this is a competitor for other microscopes - not MRI.

And I'm making myself...

...not a tinfoil hat, but rather, a hat made from Mu-metal.

Re:Similar to MEG?

[reverseengineer]

No, this technique isn't anything like magnetoencephalography. The only way it could scan your brain is if you allowed them to cut out a cell at a time. Medical scale MRI works by aligning the spins of certain nuclei (usually hydrogen atoms, which are mostly bound in water molecules in your body) using a powerful magnetic field, then using a radiofrequency field to flip those spins, and then measuring the magnetic fields produced by the nuclei as they relax to their equilibrium state. Functional MRI, or fMRI, the type often used in brain activity monitoring, measures the differing magnetic properties of hemoglobin has when oxygen is bound versus free. Therefore, the technique monitors areas of increased oxygen usage by regions of the brain, which generally correlate to increase activity.

The technique the article discusses, however, is not to measure the magnetic properties of a bunch of atoms, but to make a picture of a sample by scanning atom by atom. A very precisely constructed magnetic needle scans over a surface, in this case, the surface of a virus. Whenever the needle hovers over a hydrogen nucleus, the nucleus flips, generating a tiny force that pushes down on the stage the virus is mounted on. By recording each of these events, a map is generated of all of the hydrogen nuclei the needle passed over. It's a great way to look at protein structure, but an awfully slow way to look at a brain.

Re:Not really.

[geckipede]

So you need a way for the external machine to influence parts of your brain. If you can make a computer override the output of any particular neuron then you can burn out and take over the running of one neuron at a time. It's the ship of theseus problem made to work for you. Your identity is not embedded in any particular cell, so you could remain conscious though the duration of the transfer process. I imagine it taking quite a long time, I wouldn't be comfortable with it unless the transfer took a good fraction of a year, but the principle is sound even if you do it more quickly.

20 years ago when I was at Stanford.

[John+Sokol]

20 years ago when I was at Stanford they were experimenting with MRI Microscopy.
They were able to image 1/10 mm resolution of the inside of a common snail. Just using miniature coils.

My group was using the same machine to map blood flow volume and direction using MRI.

The article doesn't explain what they are doing in much detail. Even the little video is vague.

This advancement was enabled by a technique called magnetic resonance force microscopy (MRFM), which relies on detecting ultrasmall magnetic forces.

A cat is fine too.

[soupforare]

..."or"?

Maybe another way to do it?

[JoeSilva]

I totally agree with kebes's comments and this reminds me, back when I was working with a team developing DNA Sequencers (I was doing the software, though hardware and Physics have always been an interest), I got to alternative ways to sequence DNA and one of them was nano-scale MRI. At the time there was some research on micron scale MRI of live samples and looking at some papers the equation for spatial resolution was dependent on temperature so it seemed to suggest one could maybe get to nano scale by greatly cooling the apparatus in addition to shrinking the sample/coils/probe.

Has anyone else looked into this? Is it really feasible?

Re:Twitter?

[digitalunity]

Fuck twitter.

No seriously, I hope they relocate to the Mediterranean and get their cables cut every week.