Rethink Strep Throat Remedies
Ben Brumfield,Georgia Institute of
Technology
Got
a sore throat? The doctor may write a quick prescription for penicillin or amoxicillin,
and with the stroke of a pen, help diminish public health and your own future
health by helping bacteria evolve resistance to antibiotics.
It’s
time to develop alternatives to antibiotics for small infections, according to
a new thought paper by scientists at the Georgia Institute of Technology, and to do so quickly. It
has been widely reported that bacteria will evolve to
render antibiotics mostly ineffective by mid-century, and current strategies
to make up for the projected shortfalls haven’t worked.
One
possible problem is that drug development strategies have focused on replacing
antibiotics in extreme infections, such as sepsis, where every minute without
an effective drug increases the risk of death.
But
the evolutionary process that brings forth antibiotic resistance doesn’t happen
nearly as often in those big infections as it does in the multitude of small
ones like sinusitis, tonsillitis, bronchitis, and bladder infections, the
Georgia Tech researchers said.
“Antibiotic prescriptions against those smaller ailments account for about 90 percent of antibiotic use, and so are likely to be the major driver of resistance evolution,” said Sam Brown, an associate professor in Georgia Tech’s School of Biological Sciences.
Bacteria that survive these many small battles against antibiotics grow in strength and numbers to become formidable armies in big infections, like those that strike after surgery.
“It
might make more sense to give antibiotics less often and preserve their effectiveness
for when they’re really needed. And develop alternate treatments for the small
infections,” Brown said.
Brown,
who specializes in the evolution of microbes and in bacterial virulence, and first author Kristofer Wollein
Waldetoft, a medical doctor and postdoctoral research assistant in Brown’s lab,
published an essay detailing their suggestion for refocusing the development of
bacteria-fighting drugs on December 28, 2017, in the journal PLOS Biology.
Duplicitous antibiotics
The
evolution of antibiotic resistance can be downright two-faced.
“If
you or your kid go to the doctor with an upper respiratory infection, you often
get amoxicillin, which is a relatively broad-spectrum antibiotic,” Brown said.
“So, it kills not only strep but also a lot of other bacteria, including in
places like the digestive tract, and that has quite broad impacts.”
E.
coli is
widespread in the human gut, and some strains secrete enzymes that thwart
antibiotics, while other strains don’t. A broad-spectrum antibiotic can kill
off more of the vulnerable, less dangerous bacteria, leaving the more dangerous
and robust bacteria to propagate.
“You
take an antibiotic to go after that thing in your throat, and you end up with
gut bacteria that are super-resistant,” Brown said. “Then later, if you have to
have surgery, you have a problem. Or you give that resistant E. coli to
an elderly relative.”
Much
too often, superbugs have made their way into hospitals in someone’s
intestines, where they had evolved high resistance through years of occasional
treatment with antibiotics for small infections. Then those bacteria have
infected patients with weak immune systems.
Furious
infections have ensued, essentially invulnerable to antibiotics, followed by
sepsis and death.
Alternatives get an “F”
Drug
developers facing dwindling antibiotic effectiveness against evolved bacteria
have looked for multiple alternate treatments. The focus has often been to find
some new class of drug that works as well as or better than antibiotics, but so
far, nothing has, Brown said.
Wollein
Waldetoft came across a research paper in the medical journal Lancet Infectious Diseases that examined study after
study on such alternate treatments against big, deadly infections.
“It
was a kind of scorecard, and it was almost uniformly negative,” Brown said.
“These alternate therapies, such as phage or anti-virulence drugs or, bacteriocins -- you name it -- just
didn’t rise to the same bar of efficacy that existing antibiotics did.”
“It
was a type of doom and gloom paper that said once the antibiotics are gone,
we’re in trouble,” Brown said. “Drug companies still are investing in alternate
drug research, because it has gotten very, very hard to develop new effective
antibiotics. We don’t have a lot of other options.”
But
the focus on new treatments for extreme infections has bothered the
researchers because the main arena where the vast portion of resistance
evolution occurs is in small infections. “We felt like there was a disconnect
going on here,” Brown said.
Don’t kill strep, beat it
The
researchers proposed a different approach: “Take the easier tasks, like sore
throats, off of antibiotics and reserve antibiotics for these really serious
conditions.”
Developing
non-antibiotic therapies for strep throat, bladder infections, and bronchitis
could prove easier, thus encouraging pharmaceutical investment and research.
For
example, one particular kind of strep bacteria, group A streptococci,
is responsible for the vast majority of bacterial upper respiratory infections.
People often carry it without it breaking out.
Strep
bacteria secrete compounds that promote inflammation and bacterial spread. If
an anti-virulence drug could fight the secretions, the drug could knock back
the strep into being present but not sickening.
Brown
cautioned that strep infection can lead to rheumatic heart disease, a deadly
condition that is very rare in the industrialized world, but it still takes a
toll in other parts of the world. “A less powerful drug can be good enough if
you don’t have serious strep throat issues in your medical history,” he said.
Sometimes,
all it takes is some push-back against virulent bacteria until the body’s immune system can
take care of it. Developing a spray-on treatment with bacteriophages, viruses
that attack bacteria, might possibly do the trick.
If
doctors had enough alternatives to antibiotics for the multitude of small
infections they treat, they could help preserve antibiotic effectiveness longer
for the far less common but much more deadly infections, for which they’re most
needed.
Research
was funded by the Simons Foundation (grant 396001), the Centers for Disease
Control and Prevention (grant OADS-2016-N-17812), the Wenner-Gren Foundation,
and the Physiographic Society of Lund. Any opinions, findings, and conclusions
or recommendations expressed in this material are those of the authors and do
not necessarily reflect the views of the sponsors.
