At-home DNA tests predict how you'll respond to drugs — but how well do they work?

Pharmacogenomic, or PGx, tests predict how your genes might affect your response to medications. But they have their limitations.

man in a button down shirt prepares to swab his cheek with a long cotton swab at home
At-home DNA tests that predict how you'll respond to drug typically collect DNA from either a saliva sample or cheek swab that is then sent to the laboratory.
(Image credit: BSIP via Getty Images)

Have you ever wondered why certain medications don't seem to work as well for you as they do for others? This variability in drug response is what pharmacogenomic testing hopes to explain by looking at the genes within your DNA.

Pharmacogenomics, or PGx, is the study of how genes affect your response to medications. Genes are segments of DNA that serve as an instruction manual for cells to make proteins. Some of these proteins break down or transport certain medications through the body. Others are proteins that medications target to generate a desired effect.

Philip Empey
Associate Professor, Pharmacy and Therapeutics; Director, Pharmacogenomics Center of Excellence, University of Pittsburgh

Dr. Philip Empey is the Associate Director for Pharmacogenomics of the Pitt/UPMC Institute for Precision Medicine and leads the PreCISE-Rx and Test2Learn teams to implement pharmacogenomics clinical, research, and educational initiatives. He also directs the University of Pittsburgh - Thermo Fisher Scientific Pharamcogenomics Center of Excellence which is deploying population scale preemptive pharmagenomics testing (to >150,000 patients) in western Pennsylvania. As a clinician-scientist in the Department of Pharmacy and Therapeutics, Dr. Empey conducts NIH-funded clinical and translational research aimed at understanding the mechanisms of the variability in drug response to improve medication-related outcomes in critically-ill patients. He received his PharmD from the University of Rhode Island and completed PGY1 and PGY2 residencies in Pharmacy Practice and Critical Care at the University of Kentucky. He earned a PhD in Clinical Pharmaceutical Sciences at the University of Kentucky before completing postdoctoral research training at the University of Pittsburgh.