Researchers identify how neural cells build up resistance to opioid pain drugs within hours

Researchers at the University of Montreal's Sainte-Justine Hospital have identified how neural cells are able to build up resistance to opioid pain drugs within hours. "A better understanding of these mechanisms will enable us to design drugs that avoid body resistance to these drugs and produce longer therapeutic responses, including prolonged opioid analgesia", lead author Dr. Graciela Pineyro said.

Humans have known about the usefulness of opioids, which are often harvested from poppy plants, for centuries, but we have very little insight into how they lose their effectiveness in the hours, days and weeks following the first dose. "Our study revealed cellular and molecular mechanisms within our bodies that enable us to develop resistance to this medication, or what scientists call drug tolerance," she added.

The research team looked at how drug molecules would interact with molecules called "receptors" that exist in every cell in our body. Receptors, as the name would suggest, receive "signals" from the chemicals that they come into contact with, and the signals then cause the various cells to react in different ways. They sit on the cell wall, and wait for corresponding chemicals known as receptor ligands to interact with them. Ligands can be produced by our bodies or introduced, for example, as medication. "Until now, scientists have believed that ligands acted as 'on-off' switches for these receptors, all of them producing the same kind of effect with variations in the magnitude of the response they elicit," Pineyro explained. "We now know that drugs that activate the same receptor do not always produce the same kind of effects in the body, as receptors do not always recognize drugs in the same way. Receptors will configure different drugs into specific signals that will have different effects on the body."

Once activated by a drug, receptors move from the surface of the cell to its interior, and once they have completed this 'journey', they can either be destroyed or return to the surface and used again through a process known as "receptor recycling." By comparing two types of opioids - DPDPE and SNC-80 - the researchers found that the ligands (chemicals that enable interaction with the cell) that encouraged recycling produced less analgesic tolerance than those that didn't. "We propose that the development of opioid ligands that favour recycling could be away of producing longer-acting opioid analgesics," Pineyro said.

Pineyro is attempting to tease the "painkilling" function of opioids from the part that triggers mechanisms that enable tolerance build up. "My laboratory and my work are mostly structured around rational drug design, and trying to define how drugs produce their desired and non-desired effects, so as to avoid the second, Pineyro said. "If we can understand the chemical mechanisms by which drugs produce therapeutic and undesired side effects, we will be able to design better therapeutic agents."