Cooling MRI magnets without a continuous supply of scarce helium

A company called Cryogenic has developed a new way to cool magnets for MRI machines to near absolute zero without the need for a continuous supply of liquid helium. MRI (magnetic resonant imaging) machines work by generating a very large…

A company called Cryogenic has developed a
new way to cool magnets for MRI machines to near absolute zero
without the need for a continuous supply of liquid helium. MRI (magnetic resonant imaging) machines work by generating a
very large magnetic field using a super conducting magnet and many
coils of wires through which a current is passed. Maintaining a
large magnetic field needs a lot of energy, and this is
accomplished using superconductivity, which involves trying to
reduce the resistance in the wires to almost zero. This is done by
bathing the wires in a continuous supply of liquid helium at
-269.1C. A typical MRI scanner uses 1,700 litres of liquid helium,
which needs to be topped up periodically.The problem is that helium is running out,
as explained by chemist Peter Wothers in the Royal Institution’s
2012 Christmas Lectures. Despite being the second most
abundant material in the universe, helium is scarce on Earth as its
lightness means it is not gravitationally bound to the atmosphere
and is therefore constantly being lost to space. The majority of
the world’s helium supply is created through natural radioactive
decay and cannot be artificially synthesised, meaning the gas is a
non-renewable resource. Cryogenic has developed a technique to cool magnets to close to
absolute zero without needing liquid helium, only a small fixed
amount of helium (equivalent of maybe half a liquid litre). The
company is offering its magnets for use in a variety of imaging
techniques including MRI, Nuclear Magnetic Resonance spectroscopy
and Electron Spin Resonance spectroscopy. The magnets can be cooled to low temperatures using mechanical
refrigerators which run using electrical power and cooling water.
The coolers rely on the compression and expansion of a fixed volume
of helium gas supplied under pressure in a closed, self-contained
circuit — much like how an airconditioning unit would work. The
helium gas remains cold and doesn’t condense into a liquid.Cryogenic’s “dry” system eliminates the need for skilled
manpower to transfer and handle the liquid helium. Director
Jeremy Good explains to Wired.co.uk: ”It’s much like if you
were trying to cool some drinks. Do you get a sack of ice cubes or
a refrigerator?” Cryogenic says that its system avoids a problem that sometimes
occurs with MRI machines, called “quenching”. This is when the wire
in the electromagnet stops being superconducting and starts to
generate a lot of heat. At this point, any liquid helium around the
magnet rapidly boils off and escapes from the vessel housing the
magnet. For this reason places using liquid helium need special
ventilation facilities. The managing director of Cyrogenic Jeremy Good, said in a
statement: “In recent years major research laboratories have had to
temporarily shut down multimillion-pound facilities because of
these [helium] shortages and the problem will only get worse.
Providing an alternative which doesn’t rely on a regular supply of
helium is essential to addressing this problem.”

Cryogenic mainly focuses on MRI and other instruments based in
research facilities, and doesn’t currently make a cooling system
for the full-body MRI machines that exist in hospitals. Good says
that there are no fundamental reasons why Cryogenic’s technology
could not be used in this context and that he is in conversations
with major manufacturers of those systems.