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Researchers hope to deploy the device to the International Space Station to study the effects of space travel on humans

While mankind has been sending men and women into space for the past five decades, the effects of spaceflight on the human body are still only partially understood.  One key obstacle is that many forms of high-resolution medical scanning equipment is too bulky and heavy to transport into space for use in orbiting space stations.

I. Bringing an MRI up to the ISS?

A key example is the magnetic resonance imaging (MRI) machines.  On Earth they provide the capability to image tissues at a fidelity not possible with other types of scans.  A typical MRI machine costs around $1M USD and weighs about 11 tons due to its bulky liquid-helium cooled superconducting magnets.  Also a traditional MRI could endanger space state residents -- its gradient coils consume massive amounts of power in short bursts and the magnets can create stray magnetic fields that could disrupt life support and other mission-critical systems.

The chairman of the Canadian University of Saskatchewan's Biomedical engineering department hopes to change that, though.  Chairman Gordon Sarty heads a team that has developed a miniature version of the scanner that weighs less than a ton and costs as little as $200,000.

Micro MRI
A full-size mockup of Professor Sarty's reimagined MRI
[Image Source: Gordon Sarty / University of Saskatchewan]

An initial deployment to the International Space Station (ISS) may involve a 1/20th of a ton device, only capable of scanning limbs, to study bone mass and vasculature.  However, Professor Sarty would like to build a full size scanner for the station eventually.  He comments in an NBC News interview, "I would like to build a facility-class, whole-body-sized MRI.  Such a project would require an agreement between the ISS space agencies."

II. Initial Findings Look Promising

At the American Institute of Aeronautics and Astronautics' Sept. 13 AIAA Space 2012 conference Professor Sarty and his team presented their findings.

Their instrument employs a couple of key advances.  First, it utilizes a permanent Halbach magnet -- the primary source of the large weight reduction.  Halbach magnets are a construct of permanent magnets arranged in an array such that they increase each other’s magnet fields within one region and nullify it within another.  In a cylindrical configuration -- a configuration being explored for both motor applications and imaging equipment like Professor Sarty's micro-MRI -- in the ideal case there is an intense field within the cylinder and virtually no field outside of it.

Halbach magnet
A Halbach magnet [Image Source: PERDaix]

Thus the Halbach magnet cylinder also solves a couple of the other issues as it draws no power and produces minimal magnetization outside the cylinder.  To further reduce power, the coil system is modified to only need the radiofrequency coil -- a design called the Transmit Array Spatial Encoding (TRASE).

While the result may be tailor-fit for space applications, Professor Sarty says its qualities like reduced weight and low power consumption could make it well suited for terrestrial applications, as well, such as battlefield deployments (the device could be loaded aboard a truck and run off of batteries).

ISS wide
The final target deployment is the ISS. [Image Source: NASA]

While conference attendees reportedly urged Professor Sarty to set his eyes on these earthbound applications first, he has his sights firmly set on space and is lobbying the Canadian Space Agency to deploy a prototype to the ISS.  He comments, "Eventually someone will break a bone in space.  We have no idea if that bone will heal."

Source: NBC News



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This article is over a month old, voting and posting comments is disabled

By dgingerich on 9/24/2012 8:12:01 AM , Rating: 2
There are times when the higher resolution is needed, and times when it is not. Obviously, the numbers aren't mentioned in the article, but there is a likelihood this new design could come close to the high end machines produced today and improve from there, but I can't say for certain. Even if it doesn't, a lot of good medicine was practiced with the older units that didn't have very good resolution. That high end resolution isn't always needed.

I can certainly see a couple nice uses in this magnet design, though. I've never heard of it before, but I can imagine an electric generator design that would be incredibly efficient and useful.


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