Researchers advance drugs that treat pain without addiction
New therapies are using creative approaches that target the body’s sensory neurons, which send pain signals to the brain.
Opioids are one of the most common ways to treat pain. They can be effective but are also highly addictive, an issue that has fueled the ongoing opioid crisis. In 2020, an estimated 2.3 million Americans were dependent on prescription opioids.
Opioids bind to receptors at the end of nerve cells in the brain and body to prevent pain signals. In the process, they trigger endorphins, so the brain constantly craves more. There is a huge risk of addiction in patients using opioids for chronic long-term pain. Even patients using the drugs for acute short-term pain can become dependent on them.
Scientists have been looking for non-addictive drugs to target pain for over 30 years, but their attempts have been largely ineffective. “We desperately need alternatives for pain management,” says Stephen E. Nadeau, a professor of neurology at the University of Florida.
A “dimmer switch” for pain
Paul Blum is a professor of biological sciences at the University of Nebraska. He and his team at Neurocarrus have created a drug called N-001 for acute short-term pain. N-001 is made up of specially engineered bacterial proteins that target the body’s sensory neurons, which send pain signals to the brain. The proteins in N-001 turn down pain signals, but they’re too large to cross the blood-brain barrier, so they don’t trigger the release of endorphins. There is no chance of addiction.
When sensory neurons detect pain, they become overactive and send pain signals to the brain. “We wanted a way to tone down sensory neurons but not turn them off completely,” Blum reveals. The proteins in N-001 act “like a dimmer switch, and that's key because pain is sensation overstimulated.”
Blum spent six years developing the drug. He finally managed to identify two proteins that form what’s called a C2C complex that changes the structure of a subunit of axons, the parts of neurons that transmit electrical signals of pain. Changing the structure reduces pain signaling.
“It will be a long path to get to a successful clinical trial in humans," says Stephen E. Nadeau, professor of neurology at the University of Florida. "But it presents a very novel approach to pain reduction.”
Blum is currently focusing on pain after knee and ankle surgery. Typically, patients are treated with anesthetics for a short time after surgery. But anesthetics usually only last for 4 to 6 hours, and long-term use is toxic. For some, the pain subsides. Others continue to suffer after the anesthetics have worn off and start taking opioids.
N-001 numbs sensation. It lasts for up to 7 days, much longer than any anesthetic. “Our goal is to prolong the time before patients have to start opioids,” Blum says. “The hope is that they can switch from an anesthetic to our drug and thereby decrease the likelihood they're going to take the opioid in the first place.”
Their latest animal trial showed promising results. In mice, N-001 reduced pain-like behaviour by 90 percent compared to the control group. One dose became effective in two hours and lasted a week. A high dose had pain-relieving effects similar to an opioid.
Professor Stephen P. Cohen, director of pain operations at John Hopkins, believes the Neurocarrus approach has potential but highlights the need to go beyond animal testing. “While I think it's promising, it's an uphill battle,” he says. “They have shown some efficacy comparable to opioids, but animal studies don't translate well to people.”
Nadeau, the University of Florida neurologist, agrees. “It will be a long path to get to a successful clinical trial in humans. But it presents a very novel approach to pain reduction.”
Blum is now awaiting approval for phase I clinical trials for acute pain. He also hopes to start testing the drug's effect on chronic pain.
Learning from people who feel no pain
Like Blum, a pharmaceutical company called Vertex is focusing on treating acute pain after surgery. But they’re doing this in a different way, by targeting a sodium channel that plays a critical role in transmitting pain signals.
In 2004, Stephen Waxman, a neurology professor at Yale, led a search for genetic pain anomalies and found that biologically related people who felt no pain despite fractures, burns and even childbirth had mutations in the Nav1.7 sodium channel. Further studies in other families who experienced no pain showed similar mutations in the Nav1.8 sodium channel.
Scientists set out to modify these channels. Many unsuccessful efforts followed, but Vertex has now developed VX-548, a medicine to inhibit Nav1.8. Typically, sodium ions flow through sodium channels to generate rapid changes in voltage which create electrical pulses. When pain is detected, these pulses in the Nav1.8 channel transmit pain signals. VX-548 uses small molecules to inhibit the channel from opening. This blocks the flow of sodium ions and the pain signal. Because Nav1.8 operates only in peripheral nerves, located outside the brain, VX-548 can relieve pain without any risk of addiction.
"Frankly we need drugs for chronic pain more than acute pain," says Waxman.
The team just finished phase II clinical trials for patients following abdominoplasty surgery and bunionectomy surgery.
After abdominoplasty surgery, 76 patients were treated with a high dose of VX-548. Researchers then measured its effectiveness in reducing pain over 48 hours, using the SPID48 scale, in which higher scores are desirable. The score for Vertex’s drug was 110.5 compared to 72.7 in the placebo group, whereas the score for patients taking an opioid was 85.2. The study involving bunionectomy surgery showed positive results as well.
Waxman, who has been at the forefront of studies into Nav1.7 and Nav1.8, believes that Vertex's results are promising, though he highlights the need for further clinical trials.
“Blocking Nav1.8 is an attractive target,” he says. “[Vertex is] studying pain that is relatively simple and uniform, and that's key to having a drug trial that is informative. But the study needs to be replicated and frankly we need drugs for chronic pain more than acute pain. If this is borne out by additional studies, it's one important step in a journey.”
Vertex will be launching phase III trials later this year.
Finding just the right amount of Nerve Growth Factor
Whereas Neurocarrus and Vertex are targeting short-term pain, a company called Levicept is concentrating on relieving chronic osteoarthritis pain. Around 32.5 million Americans suffer from osteoarthritis. Patients commonly take NSAIDs, or non-steroidal anti-inflammatory drugs, but they cannot be taken long-term. Some take opioids but they aren't very effective.
Levicept’s drug, Levi-04, is designed to modify a signaling pathway associated with pain. Nerve Growth Factor (NGF) is a neurotrophin: it’s involved in nerve growth and function. NGF signals by attaching to receptors. In pain there are excess neurotrophins attaching to receptors and activating pain signals.
“What Levi-04 does is it returns the natural equilibrium of neurotrophins,” says Simon Westbrook, the CEO and founder of Levicept. It stabilizes excess neurotrophins so that the NGF pathway does not signal pain. Levi-04 isn't addictive since it works within joints and in nerves outside the brain.
Westbrook was initially involved in creating an anti-NGF molecule for Pfizer called Tanezumab. At first, Tanezumab seemed effective in clinical trials and other companies even started developing their own versions. However, a problem emerged. Tanezumab caused rapidly progressive osteoarthritis, or RPOA, in some patients because it completely removed NGF from the system. NGF is not just involved in pain signalling, it’s also involved in bone growth and maintenance.
Levicept has found a way to modify the NGF pathway without completely removing NGF. They have now finished a small-scale phase I trial mainly designed to test safety rather than efficacy. “We demonstrated that Levi-04 is safe and that it bound to its target, NGF,” says Westbrook. It has not caused RPOA.
Professor Philip Conaghan, director of the Leeds Institute of Rheumatic and Musculoskeletal Medicine, believes that Levi-04 has potential but urges the need for caution. “At this early stage of development, their molecule looks promising for osteoarthritis pain,” he says. “They will have to watch out for RPOA which is a potential problem.”
Westbrook starts phase II trials with 500 patients this summer to check for potential side effects and test the drug’s efficacy.
There is a real push to find an effective alternative to opioids. “We have a lot of work to do,” says Professor Waxman. “But I am confident that we will be able to develop new, much more effective pain therapies.”
Scientists Attempt to Make Human Cells Resistant to Coronaviruses and Ebola
Scientists are experimenting with turning certain genes on and off to make cells better fight viral infection.
Under the electronic microscope, the Ebola particles looked like tiny round bubbles floating inside human cells. Except these Ebola particles couldn't get free from their confinement.
They were trapped inside their bubbles, unable to release their RNA into the human cells to start replicating. These cells stopped the Ebola infection. And they did it on their own, without any medications, albeit in a petri dish of immunologist Adam Lacy-Hulbert. He studies how cells fight infections at the Benaroya Research Institute in Seattle, Washington.
These weren't just any ordinary human cells. They had a specific gene turned on—namely CD74, which typically wouldn't be on. Lacy-Hulbert's team was experimenting with turning various genes on and off to see what made cells fight viral infections better. One particular form of the CD74 gene did the trick. Normally, the Ebola particles would use the cells' own proteases—enzymes that are often called "molecular scissors" because they slice proteins—to cut the bubbles open. But CD74 produced a protein that blocked the scissors from cutting the bubbles, leaving Ebola trapped.
"When that gene turns on, it makes the protein that interferes with Ebola replication," Lacy-Hulbert says. "The protein binds to those molecular scissors and stops them from working." Even better, the protein interfered with coronaviruses too, including SARS-CoV-2, as the team published in the journal Science.
This begs the question: If one can turn on cells' viral resistance in a lab, can this be done in a human body so we that we can better fight Ebola, coronaviruses and other viral scourges?
Recent research indeed shows that our ability to fight viral infections is written in our genes. Genetic variability is at least one reason why some coronavirus-infected people don't develop symptoms while others stay on ventilators for weeks—often due to the aberrant response of their immune system, which went on overdrive to kill the pathogen. But if cells activate certain genes early in the infection, they might successfully stop viruses from replicating before the immune system spirals out of control.
"If my father who is 70 years old tests positive, I would recommend he takes interferon as early as possible."
When we talk about fighting infections, we tend to think in terms of highly specialized immune system cells—B-cells that release antibodies and T-cells that stimulate inflammatory responses, says Lacy-Hulbert. But all other cells in the body have the ability to fight infections too via different means. When cells detect the presence of a pathogen, they release interferons—small protein molecules named so because they set off a genetic chain reaction that interferes with viral replication. These molecules work as alarm signals to other cells around them. The neighboring cells transduce these signals inside themselves and turn on genes responsible for cellular defenses.
"There are at least 300 to 400 genes that are stimulated by type I interferons," says professor Jean-Laurent Casanova at Rockefeller University.
Scientists don't yet know exactly what all of these genes do, but they change the molecular behavior of the cells. "The cells go into a dramatic change and start producing hundreds of proteins that interfere with viral replication on the inside," explains Qian Zhang, a researcher at Casanova's lab. "Some block the proteins the virus needs and some physically tether the virus."
Some cells produce only small amount of interferon, enough to alert their neighbors. Others, such microphages and monocytes, whose jobs are to detect foreign invaders, produce a lot, injecting interferons into the blood to sound the alarm throughout the body. "They are professional cells so their jobs [are] to detect a viral or bacterial infection," Zhang explains.
People with impaired interferon responses are more vulnerable to infections, including influenza and coronaviruses. In two recent studies published in the journal Science, Casanova, Zhang and their colleagues found that patients who lacked a certain type of interferon had more severe Covid-19 symptoms and some died from it. The team ran a genetic comparison of blood samples from patients hospitalized with severe coronavirus cases against those with the asymptomatic infections.
They found that people with severe disease had rare variants in the 13 genes responsible for interferon production. More than three percent of them had a genetic mutation resulting in non-functioning genes. And over ten percent had an autoimmune condition, in which misguided antibodies neutralized their interferons, dampening their bodies' defenses—and these patients were predominantly men. These discoveries help explain why some young and seemingly healthy individuals require life support, while others have mild symptoms or none. The findings also offer ways of stimulating cellular resistance.
A New Frontier in the Making
The idea of making human cells genetically resistant to infections—and possibly other stressors like cancer or aging—has been considered before. It is the concept behind the Genome Project-write or GP-write project, which aims to create "ultra-safe" versions of human cells that resist a variety of pathogens by way of "recoding" or rewriting the cells' genes.
To build proteins, cells use combinations of three DNA bases called codons to represent amino acids—the proteins' building blocks. But biologists find that many of the codons are redundant so if they were removed from all genes, the human cells would still make all their proteins. However, the viruses, whose genes would still include these eliminated redundant codons, would no longer successfully be able to replicate inside human cells.
In 2016, the GP-Write team successfully reduced the number of Escherichia coli's codons from 64 to 57. Recoding genes in all human cells would be harder, but some recoded cells may be transplanted into the body, says Harvard Medical School geneticist George Church, the GP-Write core founding member.
"You can recode a subset of the body, such as all of your blood," he says. "You can also grow an organ inside a recoded pig and transplant it."
Church adds that these methods are still in stages that are too early to help us with this pandemic.
LeapsMag exclusively interviewed Church in 2019 about his latest progress with DNA recoding:
The Push for Clinical Trials
In the meantime, interferons may prove an easier medicine. Lacy-Hulbert thinks that interferon gamma might play a role in activating the CD74 gene, which gums up the molecular scissors. There also may be other ways to activate that gene. "So we are now thinking, can we develop a drug that mimics that actual activity?" he says.
Some interferons are already manufactured and used for treating certain diseases, including multiple sclerosis. Theoretically, nothing prevents doctors from prescribing interferons to Covid patients, but it must be done in the early stages of infection—to stimulate genes that trigger cellular defenses before the virus invades too many cells and before the immune systems mobilizes its big guns.
"If my father who is 70 years old tests positive, I would recommend he takes interferon as early as possible," says Zhang. But to make it a mainstream practice, doctors need clear prescription guidelines. "What would really help doctors make these decisions is clinical trials," says Casanova, so that such guidelines can be established. "We are now starting to push for clinical trials," he adds.
Lina Zeldovich has written about science, medicine and technology for Popular Science, Smithsonian, National Geographic, Scientific American, Reader’s Digest, the New York Times and other major national and international publications. A Columbia J-School alumna, she has won several awards for her stories, including the ASJA Crisis Coverage Award for Covid reporting, and has been a contributing editor at Nautilus Magazine. In 2021, Zeldovich released her first book, The Other Dark Matter, published by the University of Chicago Press, about the science and business of turning waste into wealth and health. You can find her on http://linazeldovich.com/ and @linazeldovich.
Thousands of Vaccine Volunteers Got a Dummy Shot. Should They Get the Real Deal Now?
If a treatment or prevention is known to work, it is considered unethical to withhold it from volunteers in order to prolong a research trial, experts say.
The highly anticipated rollout of a COVID-19 vaccine poses ethical considerations: When will trial volunteers who got a placebo be vaccinated? And how will this affect the data in those trials?
It's an issue that vaccine manufacturers and study investigators are wrestling with as the Food and Drug Administration is expected to grant emergency use authorization this weekend to a vaccine developed by Pfizer and the German company BioNTech. Another vaccine, produced by Moderna, is nearing approval in the United States.
The most vulnerable—health care workers and nursing home residents—are deemed eligible to receive the initial limited supply in accordance with priority recommendations from the Centers for Disease Control and Prevention (CDC).
With health care workers constituting an estimated 20 percent of trial participants, this question also comes to the fore: "Is it now ethically imperative that we offer them the vaccine, those who have had placebo?" says William Schaffner, an infectious diseases physician at Vanderbilt University and an adviser to the CDC's immunization practices committee.
When a "gold-standard" measure becomes available, participants in the placebo group "would ordinarily be notified" of the strong public health recommendation to opt for immunization, says Johan Bester, interim assistant dean for biomedical science education and director of bioethics at the University of Nevada, Las Vegas School of Medicine.
"If a treatment or prevention exists that we know works, it is unethical to withhold it from people who would benefit from it just to answer a research question." This moral principle poses a quandary for ethicists and physicians alike, as they ponder possible paths to proceed with vaccination amid ongoing trials. Rigorous trials are double-blinded—neither the participants nor the investigators know who received the actual vaccine and who got a dummy injection.
"The intent of these trials is to follow these folks for up to two years," says Marci Drees, infection prevention officer and hospital epidemiologist for ChristianaCare in Wilmington, Delaware. At a minimum, she adds, researchers would prefer to monitor participants for six months.
"You can still follow safety over a long-term period of time without actually continuing to have a placebo group for comparison."
But in the midst of a pandemic, that may not be feasible. Prolonged exposure to the highly contagious and lethal virus could have dire consequences.
To avoid compromising the integrity of the blinded data, "there are some potentially creative solutions," Drees says. For instance, trial participants could receive the opposite of what they initially got, whether it was the vaccine or the placebo.
One factor in this decision-making process depends on when a particular trial is slated to conclude. If that time is approaching, the risk of waiting would be lower than if the trial is only halfway in progress, says Eric Lofgren, an epidemiologist at Washington State University who has studied the impact of COVID-19 in jails and at in-person sporting events.
Sometimes a study concludes earlier than the projected completion date. "All clinical trials have a data and safety monitoring board that reviews the interim results," Lofgren says. The board may halt a trial after finding evidence of harm, or when a treatment or vaccine has proven to be "sufficiently good," rendering it unethical to deprive the placebo group of its benefits.
The initial months of a trial are most crucial for assessing a vaccine's safety. Differences between the trial groups would be illuminating if fewer individuals who got the active vaccine contracted the virus and developed symptoms when compared to the placebo recipients. After that point, in vaccine-administered participants, "you can still follow safety over a long-term period of time without actually continuing to have a placebo group for comparison," says Dial Hewlett Jr., medical director for disease control at the Westchester County Department of Health in New York.
Even outside of a trial, safety is paramount and any severe side effects that occur will be closely monitored and investigated through national reporting networks. For example, regulators in the U.K. are investigating several rare but serious allergic reactions to the Pfizer vaccine given on Tuesday. The FDA has asked Pfizer to track allergic reactions in its safety monitoring plan, and some experts are proposing that Pfizer conduct a separate study of the vaccine on people with a history of severe allergies.
As the FDA eventually grants authorization to multiple vaccines, more participants are likely to leave trials and opt to be vaccinated. It is important that enough participants choose to stay in ongoing trials, says Nicole Hassoun, professor of philosophy at the State University of New York at Binghamton, where she directs the Global Health Impact program to extend medical access to the poor.
She's hopeful that younger participants and individuals without underlying medical conditions will make that determination. But the departure of too many participants at high risk for the virus would make it more difficult to evaluate the vaccine's safety and efficacy in those populations, Hassoun says, while acknowledging, "We can't have the best of both worlds."
Once a safe and effective vaccine is approved in the United States, "it would not be ethically appropriate to do placebo trials to test new vaccines."
One solution would entail allowing health care workers to exit a trial after a vaccine is approved, even though this would result in "a conundrum when the next group of people are brought forward to get the vaccine—whether they're people age 65 and older or they're essential workers, or whoever they are," says Vanderbilt physician Schaffner, who is a former board member of the Infectious Diseases Society of America. "All of a sudden, you'll have an erosion of the volunteers who are in the trial."
For now, one way or another, experts agree that current and subsequent trials should proceed. There is a compelling reason to identify additional vaccines with potentially greater effectiveness but with fewer side effects or less complex delivery methods that don't require storage at extremely low temperatures.
"Continuing with existing vaccine trials and starting others remains important," says Nir Eyal, professor and director of Rutgers University's Center for Population-Level Bioethics in New Brunswick, New Jersey. "We still need to tell how much proven vaccines block infections and how long their duration lasts. And populations around the world need vaccines that are easier to store and deliver, or simply cheaper."
But once a safe and effective vaccine is approved in the United States, "it would not be ethically appropriate to do placebo trials to test new vaccines," says bioethicist Bester at the University of Nevada, Las Vegas School of Medicine. "One possibility if a new vaccine emerges, is to test it against existing vaccines."
In a letter sent to trial volunteers in November, Pfizer and BioNTech committed to establishing "a process that would allow interested participants in the placebo group who meet the eligibility criteria for early access in their country to 'cross-over' to the vaccine group." The trial plans to continue monitoring all subjects regardless of whether people in the placebo group cross over, Pfizer said in a presentation to the FDA today. After Pfizer has collected six months of safety data, in April 2021, it plans to ask the FDA for full approval of the vaccine.
In the meantime, the company pledged to update volunteers as they obtain more input from regulatory authorities. "Thank you again for making a difference by being a part of this study," they wrote. "It is only through the efforts of volunteers like you that reaching this important milestone and developing a potential vaccine against COVID-19 is possible."
CORRECTION: An earlier version of this article mistakenly stated that the FDA would be granting emergency "approval" to the Pfizer/BioNTech vaccine, rather than "emergency use authorization." We regret the error.