Full Body Scanner (from newscientist.com)

What are full body scanners?

Remember the X-ray specs of science fiction comics that would let people see through walls and clothing? Full body scanners are a bit like them. The scanners take advantage of the fact that at certain wavelengths, electromagnetic waves can pass through clothes but not through the skin, metal or substances such as drugs and explosives.

If your eyes were sensitive to these wavelengths like the scanners, every person you meet would appear naked, with pens, coins, belt buckles and the like magically festooned about their person. You would also be able to see if they were carrying a knife, gun or explosives.

What are the health concerns surrounding them?

There are two main types of full body scanner. One uses X-rays while the other uses lower energy milimetre wavelengths. X-rays are hazardous because their photons have enough energy to ionise atoms and break chemical bonds. That can cause damage to DNA that subsequently leads to cancer. The machines are deemed safe because the total dose that someone receives during a scan is tiny.

However, earlier this year, a group of scientists at the University of California, San Francisco, raised a number of concerns over X-ray scanners. They said the X-rays they use are low energy to ensure they bounce only off skin rather than passing through the body, to produce an image focused on objects concealed beneath clothes. This means that the entire dose that the person being scanned receives is concentrated on the skin rather than spread throughout their body. That could mean the skin receives a dose that is one or two orders of magnitude more than expected.

To many observers, the response of the US Food and Drug Administration failed to properly address these concerns.

Are there health concerns surrounding millimetre-wave scanners?

In theory, these ought to be safer than X-rays because millimetre photons do not have enough energy to break chemical bonds. Last year, however, researchers at Los Alamos National Laboratory in New Mexico suggested that these low energy photons could damage DNA in an entirely novel way. They say that while these photons cannot break DNA, they can shake it. This shaking may be so strong that it unzips the two strands in DNA, interfering with the genetic machinery that keeps cells working and healthy.

The team at Los Alamos did their calculations for submilimetre or terahertz waves, whose photons are slightly more energetic than those of millimetre waves. Their results are probabilistic rather than deterministic, they say. This explains why some experiments show that terahertz waves can damage DNA while other, practically identical studies show nothing.

While terahertz full body scanners are not yet widely used, the work does show that the effects of electromagnetic waves on DNA are not fully understood.