Summary: Researchers developed an antibody with significant potential to reverse the lethal effects of a carfentanil overdose, according to preclinical tests.
Carfentanil, a potent variant of the synthetic opioid fentanyl, is often mixed with illicit drugs, leading to a high number of overdoses. This newly engineered antibody binds powerfully to carfentanil, fentanyl, and other variants, effectively reverses carfentanil-induced respiratory depression in rodents.
The discovery holds promise for a more robust, long-lasting treatment for synthetic opioid overdoses compared to current methods.
Key Facts:
- The new antibody has been shown to counteract respiratory depression—a common fatal outcome in opioid overdoses—caused by carfentanil, the deadliest fentanyl variant.
- The treatment, administered by simple intramuscular injection, could offer long-term protection due to its high affinity to fentanyl and its derivatives, and its ability to persist in the body.
- FDA-approved clinical trials for an IgG version of this antibody, CSX-1004, are set to commence this month to assess its effectiveness in preventing fentanyl overdoses.
Source: Scripps Research Institute
An antibody in single-chain fragment variable (scFv) format that binds to the powerful opioid carfentanil was shown to reverse signs of carfentanil overdose in preclinical tests conducted by scientists at Scripps Research.
Carfentanil is a variant of the synthetic opioid fentanyl, and about 100 times as potent as its chemical cousin. Along with fentanyl and other fentanyl variants, it is commonly mixed with illegal drugs such as heroin and cocaine to enhance their euphoric effects, resulting in many fatal overdoses.
In the study, published in ACS Chemical Neuroscience on August 3, 2023, the researchers developed a human antibody that binds very tightly to carfentanil, fentanyl and other fentanyl variants.
In rodents, they showed that administering a solution of the antibody shortly after an overdose reverses the potentially deadly respiratory depression caused by carfentanil, the most dangerous of the variants.
The results suggest that the antibody could be a more powerful, longer-lasting treatment for synthetic opioid overdose, compared to existing options.
“We expect this antibody to be a valuable new weapon for fighting the opioid crisis,” says study senior author Kim D. Janda, PhD, the Ely R. Callaway, Jr. Professor of Chemistry at Scripps Research.
The study’s first author was Lisa Eubanks, PhD, a senior staff scientist in the Janda laboratory.
Opioid drugs, whether synthetic or derived from the opium poppy, bind and activate neuronal receptors called mu-opioid receptors.
These receptors are present on different types of neurons across the human nervous system, which is why opioid drugs have multiple effects like pain-relief and euphoria, but also respiratory depression—slower and shallower breathing.
Respiratory depression is the immediate cause of death in the tens of thousands of fatal opioid-related overdoses that occur each year in the U.S.
Carfentanil, after fentanyl, is the next-most common synthetic opioid found in illicit drugs in the U.S. Once available legally as a tranquilizer for large animals, it was pulled from the market by the FDA in 2018 because of its potential for misuse—and its potential lethality at doses measured in micrograms.
Carfentanil is so potent that the U.S. government regards it as a possible chemical warfare agent; the Janda lab’s early work on the new antibody was funded in part by a National Institutes of Health program aimed at finding antidotes to such weapons.
Fentanyl and carfentanil overdoses currently are treated with the mu-opioid receptor-blocking drugs naloxone and naltrexone, but these treatments are sometimes ineffective against synthetic opioids even at large doses.
Moreover, the benefits of these treatments typically last for less than an hour after dosing—potentially allowing respiratory depression from fentanyl or carfentanil (which persist much longer in the body) to resume.
Janda and his team set out to develop an anti-fentanyl antibody that would have three basic features: firstly, it should bind with very high affinity to fentanyl and its derivatives, pulling them out of the bloodstream and thereby causing them to diffuse out of the brain as well; secondly, it should persist in the body so as to provide reasonably long-term protection; and thirdly, it should be able to get quickly into the bloodstream and be delivered by a simple intramuscular injection, which requires no special training.
To obtain antibodies, Janda and his team vaccinated rodents with a molecule they designed that would elicit antibodies against carfentanil, fentanyl and variants.
The rodents were engineered to produce human antibodies (rather than rodent antibodies, which would trigger an unwanted immune response if administered to humans).
Among the resulting antibodies, the researchers were able to identify several that bind to carfentanil with super-high affinity—and bind very strongly to fentanyl and several other fentanyl derivatives.
They then selected the most potent of these antibodies, modified it to be more lightweight (so that it would get quickly into the bloodstream), and further altered it so it would persist in the blood for days.
Tests in rodents showed that the optimized scFv, dubbed C10‐S66K, did indeed have a powerful effect at reducing carfentanil’s actions on the brain—reversing carfentanil-driven respiratory depression when injected 15 minutes after a heavy carfentanil exposure.
The effect after about 40 minutes was stronger than naloxone’s and was still increasing after two hours, whereas naloxone’s peaked at 30 minutes and swiftly declined.
As part of the study, the collaborating laboratory of Ian Wilson, PhD, Hansen Professor of Structural Biology at Scripps Research, used X-ray crystallography to determine the near-atomic resolution structures of carfentanil- and fentanyl-bound C10‐S66K.
These structural data suggest that the antibody should indeed bind well to multiple fentanyl derivatives but should not interfere with the activity of other beneficial opioid molecules such as naloxone and naltrexone.
Janda and Scripps Research have licensed the rights to further develop and market C10-S66K to the pharma company Cessation Therapeutics, the sponsor of the clinical trial planned for this month. The U.S. Food and Drug Administration (FDA) has approved a full length IgG version of this antibody termed CSX-1004 for clinical trials, slated to begin this month for the prevention of fentanyl overdose.
About this opioid addiction and neuropharmacology research news
Author: Scripps Research Communications Office
Source: Scripps Research Institute
Contact: Scripps Research Communications Office – Scripps Research Institute
Image: The image is credited to Neuroscience News
Original Research: Open access.
“An Engineered Human-Antibody Fragment with Fentanyl Pan-Specificity That Reverses Carfentanil-Induced Respiratory Depression” by Kim D. Janda et al. ACS Chemical Neuroscience
Abstract
An Engineered Human-Antibody Fragment with Fentanyl Pan-Specificity That Reverses Carfentanil-Induced Respiratory Depression
The opioid overdose crisis primarily driven by potent synthetic opioids resulted in more than 500,000 deaths in the US over the last 20 years.
Though naloxone, a short-acting medication, remains the primary treatment option for temporarily reversing opioid overdose effects, alternative countermeasures are needed.
Monoclonal antibodies present a versatile therapeutic opportunity that can be tailored to synthetic opioids and help prevent post-treatment renarcotization.
The ultrapotent analog carfentanil is especially concerning due to its unique pharmacological properties. With this in mind, we generated a fully human antibody through a drug-specific B cell sorting strategy with a combination of carfentanil and fentanyl probes.
The resulting pan-specific antibody was further optimized through scFv phage display, producing C10-S66K. This monoclonal antibody displays high affinity to carfentanil, fentanyl, and other analogs and reversed carfentanil-induced respiratory depression.
Additionally, X-ray crystal structures with carfentanil and fentanyl bound provided structural insight into key drug:antibody interactions.