08 Nov The Science Behind Drug Tests
For many employees, taking a drug test seems simple. However, the science behind most drug test involves complex processes and chemical reactions that most people do not even consider.
Places of employment often require varied drug testing, depending on the type of drug tested and the type of sample collected. Samples such as bodily fluids and hair screen for many drugs, including marijuana, cocaine and amphetamines.
Credible drug screening programs involve a two-step process: the initial (immunoassay) and confirmatory (gas chromatography-mass spectrometry) –– a GC-MS test. These methods, the most commonly utilized for drug testing, allow a high level of sensitivity and specificity. If companies give both tests, the likelihood of false positives or false negatives lowers dramatically.
Lab workers take the immunoassay test first and often use it as a screening method. If the immunoassay tests negative, lab workers take no further action and the results are reported as negative. If the sample tests positive, lab workers will administer an additional confirmatory GC-MS analysis on a separate portion of the biological sample.
Drug Testing Using Urine
The urine sample test, the most common, checks for biochemicals called immunoassays. Immunoassays bond to specific macromolecules that give off an indicator reaction.
If the results indicate drug use, they send another sample to undergo the GC-MS method. This method, using helium gas, pushes the sample through a tubular column. Particular drugs pass through the column at certain known speeds. Once the sample gets to the end of the column, it fragments with ionization. The lab workers then sort the fragments by mass. Certain drugs have specific and known fragmentation patterns, allowing the lab to discover recent drug use.
Drug Testing Using Hair
Let’s use Marijuana as an example. Marijuana enters the bloodstream, like oxygen would, and travels down to the lungs. There, a gas exchange called diffusion happens and takes the drug molecules throughout the whole body’s bloodstream. In contrast, a direct injection of a drug enters the bloodstream and moves throughout the body immediately.
Once through the bloodstream, the drug enters the hair through diffusion across the cell membrane, entering an internal pathway –– either the sweat glands or the bloodstream entryway.
Hair analysis provides long-term information, from months to years, concerning both the severity and pattern of drug use. In contrast, urinalysis simply indicates only drug use from the last two to three days. Field studies demonstrate that hair analysis identifies drug users much more effectively.