Doctor with a syringe on the background of DNA.
Steve, a 60-year-old resident of the DC area who works in manufacturing, was always physically fit. In college, he played lacrosse in Division I, the highest level of intercollegiate athletics in the United States. Later, he stayed active by swimming, biking, and running--up until something strange happened around two years ago.
"It was hard for me to even get upstairs. I wasted away."
Steve, who requested that his last name be withheld to protect his privacy, started to notice weakness first in his toes, then his knees. On a trip to the zoo, he had trouble keeping up. Then some months later, the same thing happened on a family hike. What was supposed to be a four-mile trek up to see a waterfall ended for him at the quarter-mile mark. He turned around and struggled back to the start just as everyone else was returning from the excursion.
Alarmed, he sought out one doctor after the next, but none could diagnose him. The disabling weakness continued to creep up his legs, and by the time he got in to see a top neurologist at Johns Hopkins University last January, he was desperate for help.
"It was hard for me to even get upstairs," he recalls. "I wasted away and had lost about forty-five pounds."
The neurologist, Dr. Michael Polydefkis, finally made the correct diagnosis based on Steve's rapid progression of symptoms, a skin and nerve biopsy, and a genetic test. It turned out that Steve had a rare inherited disease called hereditary transthyretin amyloidosis. Transthyretin is a common blood protein whose normal function is to transport vitamins and hormones in the body. When patients possess certain genetic mutations in the transthyretin gene, the resulting protein can misfold, clump and produce amyloid, an aggregate of proteins, which then interferes with normal function. Many organs are affected in this disease, but most affected are the nervous system, the GI tract, and the heart.
Dr. Michael Polydefkis, Steve's neurologist at Johns Hopkins Bayview Medical Center in Baltimore, MD.
(Courtesy of Dr. Polydefkis)
For the 50,000 patients like Steve around the world, the only treatment historically has been a liver transplant—a major, risky operation. The liver makes most of the transthyretin in a person's body. So if a person who carries a genetic mutation for a disease-causing form of transthyretin has their liver transplanted, the new liver will stop making the mutant protein. A few drugs can slow, but do not stop the disease.
Since it is a genetic condition, a regular "drug" can't tackle the problem.
"For almost all of medicine from the 18th century to today, drugs have been small molecules, typically natural, some invented by humans, that bind to proteins and block their functions," explains Dr. Phillip Zamore, chair of the department of Biomedical Sciences at the University of Massachusetts Medical School. "But with most proteins (including this one), you can't imagine how that would ever happen. Because even if it stuck, there's no reason to think it would change anything. So people threw up their hands and said, 'Unless we can find a protein that is "druggable" in disease X, we can't treat it.'"
To draw a car analogy, treating a disease like Steve's with a small molecule would be like trying to shut down the entire car industry when all you can do is cut the power cord to one machine in one local factory. With few options, patients like Steve have been at a loss, facing continual deterioration and disability.
"It's more obvious how to be specific because we use the genetic code itself to design the drug."
A Radical New Approach
Luckily, Dr. Polydefkis knew of an experimental drug made by a biotech company that Dr. Zamore co-founded called Alnylam Pharmaceuticals. They were doing something completely different: silencing the chemical blueprint for protein, called RNA, rather than targeting the protein itself. In other words, shutting down all the bad factories across the whole car industry at once – without touching the good ones.
"It's more obvious how to be specific," says Dr. Zamore, "because we use the genetic code itself to design the drug."
For Steve's doctor, the new drug, called patisiran, is a game changer.
"It's the dawn of molecular medicine," says Dr. Polydefkis. "It's really a miraculous development. The ability to selectively knock down or reduce the amount of a specific protein is remarkable. I tell patients this is science fiction that is now becoming reality."
A (Very) Short History
The strategy of silencing RNA as a method of guiding drug development began in 1998. Basic research took six years before clinical testing in humans began in 2004. Just a few months ago, in November, the results of the first double-blind, placebo-controlled phase III trials were announced, testing patisiran in patients--and they surpassed expectations.
"The results were remarkably positive," says Dr. Polydefkis. "Every primary and secondary outcome measure target was met. It's the most positive trial I have ever been associated with and that I can remember in recent memory."
FDA approval is expected to come by summer, which will mark the first official sanction of a drug based on RNA inhibition (RNAi). Experts are confident that similar drugs will eventually follow for other diseases, like familial hypercholesterol, lipid disorders, and breathing disorders. Right now, these drugs must get into the liver to work, but otherwise the future treatment possibilities are wide open, according to Dr. Zamore.
"It doesn't have to be a genetic disease," he says. "In theory, it doesn't have to be just one gene, although I don't think anyone knows how many you could target at once. There is no precedent for targeting two."
Dr. Phillip Zamore, chair of the RNA Therapeutics Institute at the University of Massachusetts Medical School.
(Courtesy of Dr. Zamore)
Alnylam, the leading company in RNAi therapeutics, plans to strategically design other new drugs based on what they have learned from this first trial – "so with each successive experience, with designing and testing, you get better at making more drugs. In a way, that's never happened before...This is a lot more efficient of a way to make drugs in the future."
And unlike gene therapy, in which a patient's own genetic code is permanently altered, this approach does not cause permanent genetic changes. Patients can stop taking it like any other drug, and its effects will vanish.
How Is Steve?
Last February, Steve started on the drug. He was granted early access since it is not yet FDA-approved and is still considered experimental. Every 21 days, he has received an IV infusion that causes some minor side effects, like headaches and facial flushing.
"The good news is, since I started on the drug, I don't see any more deterioration other than my speech."
So far, it seems to be effective. He's gained back 20 pounds, and though his enunciation is still a bit slurred, he says that his neuropathy has stopped. He plans to continue the treatment for the rest of his life.
"The good news is, since I started on the drug, I don't see any more deterioration other than my speech," he says. "I think the drug is working, but would I have continued to deteriorate without the drug? I'm not really sure."
Dr. Polydefkis jumps in with a more confident response: "If you ask me, I would say 100 percent he would have kept progressing at a fairly rapid pace without the drug. When Steve says the neuropathy has stopped, that's music to my ears."
Paul Alexander spent more than 70 years confined to an iron lung after a polio infection left him paralyzed at age 6. Here, Alexander uses a mirror attached to the top of his iron lung to view his surroundings.
Paul Alexander was one of several thousand who were infected and paralyzed by polio in 1952. That year, a polio epidemic swept the United States, forcing businesses to close and polio wards in hospitals all over the country to fill up with sick children. When Paul caught polio in the summer of 1952, doctors urged his parents to let him rest and recover at home, since the hospital in his home suburb of Dallas, Texas was already overrun with polio patients.
Paul rested in bed for a few days with aching limbs and a fever. But his condition quickly got worse. Within a week, Paul could no longer speak or swallow, and his parents rushed him to the local hospital where the doctors performed an emergency procedure to help him breathe. Paul woke from the surgery three days later, and found himself unable to move and lying inside an iron lung in the polio ward, surrounded by rows of other paralyzed children.
Hospitals were commonly filled with polio patients who had been paralyzed by the virus before a vaccine became widely available in 1955. Associated Press
But against all odds, Paul lived. And with help from a physical therapist, Paul was able to thrive—sometimes for small periods outside the iron lung.
The way Paul did this was to practice glossopharyngeal breathing (or as Paul called it, “frog breathing”), where he would trap air in his mouth and force it down his throat and into his lungs by flattening his tongue. This breathing technique, taught to him by his physical therapist, would allow Paul to leave the iron lung for increasing periods of time.
With help from his iron lung (and for small periods of time without it), Paul managed to live a full, happy, and sometimes record-breaking life. At 21, Paul became the first person in Dallas, Texas to graduate high school without attending class in person, owing his success to memorization rather than taking notes. After high school, Paul received a scholarship to Southern Methodist University and pursued his dream of becoming a trial lawyer and successfully represented clients in court.
Paul Alexander, pictured here in his early 20s, mastered a type of breathing technique that allowed him to spend short amounts of time outside his iron lung. Paul Alexander
Throughout his long life, Paul was also able to fly on a plane, visit the beach, adopt a dog, fall in love, and write a memoir using a plastic stick to tap out a draft on a keyboard. In recent years, Paul joined TikTok and became a viral sensation with more than 330,000 followers. In one of his first videos, Paul advocated for vaccination and warned against another polio epidemic.
Paul was reportedly hospitalized with COVID-19 at the end of February and died on March 11th, 2024. He currently holds the Guiness World Record for longest survival inside an iron lung—71 years.
Polio thankfully no longer circulates in the United States, or in most of the world, thanks to vaccines. But Paul continues to serve as a reminder of the importance of vaccination—and the power of the human spirit.
““I’ve got some big dreams. I’m not going to accept from anybody their limitations,” he said in a 2022 interview with CNN. “My life is incredible.”
