Bug ZappersThe best futuristic ideas for killing drug-resistant bacteria.
Posted Thursday, July 12, 2007, at 1:06 PM ET
In May, runaway groom Andrew Speaker gave the public a crash course in drug-resistant tuberculosis. It turned out that Speaker wasn't infected with the worst form of TB after all. But he's done us a favor by making us think about antibiotic resistance to infection. This is one of those problems, like global warming, that is creepily creeping up on us. Around the world, drug-resistant strains of tuberculosis are proliferating. The superbug MRSA (or methicillin-resistant Staphylococcus aureus) is now found in 34 of every 1,000 hospital patients. And vancomycin-resistant enterococci—also bad bacteria—is responsible for roughly a third of infections in hospital intensive-care units.
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StumbleUponThese warning signs, highlighted by a recent spate of editorials (subscription required), articles, and blogs, may make us wish for a gorillacillin—a superdrug—that could destroy any bug under the sun. But as the National Academy of Sciences pointed out last year, such a remedy is unlikely to emerge. And if one did, it would probably be used so widely that resistant strains would quickly evolve. Instead, the future seems to lie with treatments that target specific bacteria by taking cues from how they behave in nature, modulating the human immune system, or intervening boldly in bacterial genetics. Some of these approaches may substitute for antibiotics; others could extend the usefulness of the drugs we have. Here are some of the best big ideas ranked on a scale of 1 to 10, based on their potential promise and sheer intellectual chutzpah.
1. Mimicking Nature
Promise: 9
Chutzpah: 3
In nature, bacteria often use highly targeted proteins called bacteriocins to kill their close relatives (typically when times are tough and resources scarce). Bacteriocins are widespread, so it's relatively easy and cheap to find the one that could kill, say, the causative agent of anthrax or plague, says Peg Riley of the University of Massachusetts, Amherst.
Riley's group is running animal trials on bacteriocins to fight urinary tract infections, and in vitro trials to treat ear infections and conjunctivitis. In the future, she envisions a pharma shelf that contains "narrow spectrum bacteriocins for every major human infectious disease." Because bacteriocins target specific bacteria, resistant strains would take longer to evolve and spread, Riley argues. On the other hand, more targeted therapies mean that doctors would need to know exactly what they're shooting at. So this strategy may be widely practical only if and when faster diagnostic tools—like chip-based technologies—come on line.
2. Eating Bugs
Promise: 8
Chutzpah: 4
Bacteriophages are viruses that can infect and kill specific types of bacteria (the word phage is derived from the Greek "to eat"). Like bacteriocins, phages are widespread in nature, meaning that drug candidates would probably be relatively easy to find. Phages are already used in the food industry: The Canadian company Biophage Pharma Inc. sells a product called Listex, which can be added to cold cuts and cheeses to kill listeria. The company is also working on a product that hospitals could spray on surfaces to kill MRSA—or perhaps spray into the nasal passages of people who carry this superbug. Phage treatment for infection is currently available in Soviet Georgia. But many Western experts worry about the quality and safety of the viruses used there. Experts also view phages as something of a wild card, since they can promote the reshuffling of DNA. Phages won't gain ground in Western hospitals and clinics until their effect on specific bacteria is studied a lot more thoroughly.
3. Controlling Crowds
Promise: 7
Chutzpah: 6
Bacteria compete with one another—and sometimes we can reap the benefits. Under normal circumstances, good bacteria on our skin and in our mouths and guts help to keep out pathogenic invaders. The Wisconsin-based company ConjuGon is working on a treatment for chronic urinary tract infections that harnesses a similar principle. Its method builds on research that suggests introducing benign bacteria into the bladder—which is normally bacteria-free—may help to crowd out bad bugs and prevent urinary tract infections. Such a treatment would be especially good for patients with permanent catheters, who often get several UTIs a year, the company says. Swedish researchers have also explored whether bacterial crowding might be used to prevent ear infections. In general, toying with bacterial populations can be tricky business, just as messing with ecosystems is. And companies will need to worry about preventing unintended side effects like inflammation.
4. Blaming the Victim
Promise: 7
Chutzpah: 8
Our immune systems overreact to many bacterial invaders, and in the process cause as much or more harm than the bugs themselves. Such is the case with tuberculosis, meningitis, rheumatic fever, pneumonia, and septicemic plague, say Elisa Margolis and Bruce Levin of Emory University. They argue for manipulating the body's immune response. In 2001, Eli Lilly received FDA approval for a drug called Xigris, which is designed to counter the body's over-response to sepsis (or systemic inflammation due to infection). But Xigris has remained controversial. And so far, other attempts to develop immune-modulating drugs for bacterial infections seem to have come up short. Partly, this is because the immune system is so complex—it is hard to know precisely which cells and molecules it's mobilizing at any given time. Real-time, computer-assisted monitoring of a patient's immune system may be required for this approach to gain traction, Margolis and Levin recognize. At least at first, their strategy thus would probably be relevant to only the sickest patients.
5. Stopping Evolution:
Promise: 5
Chutzpah: 10
What if we could intervene genetically and stop bacteria from becoming antibiotic-resistant? The traditional view is that drug-resistant bacteria are created by random mutation. Recently, however, Floyd Romesberg of the Scripps Research Institute has found that antibiotics can cause new mutations in some bacteria by sending them into SOS orbit, in which they turn on a mutation-inducing gene. By inhibiting this gene in vitro, Romesberg has managed to prevent bacteria from becoming resistant to the antibiotics ciprofloxacin and rifampicin. If an inhibitor drug for humans could be developed, he says, it could be given in conjunction with antibiotics and might help to extend their usefulness.
Romesberg's strategy is tantamount to sticking a finger in the eye of evolution—and in theory it holds great appeal. In practice, however, a drug that inhibits a mutation-causing mechanism would probably be hard to develop. Such a drug would also help only people who started out with nonresistant bugs—like those for whom antibiotics initially worked and then stopped—rather than those initially infected with a resistant strain.
Meanwhile, meddling with evolution is also a low-tech game. The rest of us can do our part by avoiding broad-spectrum antibiotics and antibacterial soaps and wipes (unless we happen to work in an operating room) and by buying antibiotic-free meat. While we're waiting on the big ideas, the small measures are all we've got.
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Remarks from the Fray:
I probably picked up MRSA in the hospital during a protracted stay following alarming, but successful surgery. At first, it was just weird, but I was able to punch it down with some fairly heavy duty meds Rx'd by my doc.
Then my son came down with a nasty infection that hit him fast and hard. He wound up in the hospital on IV antibiotics.
But when my wife got a nasty infection on her leg, someone finally thought to send a sample off for evaluation. The strain of MRSA was id'd and the state board of health's infectious disease guy had a long chat with my GP. At the end of the day, everyone in my family went on oral meds, and had to take a shower twice a day with an antibacterial Rx soap and put ucky goo in our noses. I think this went on for two weeks. And it worked. The meds set us back $600, and the only lasting damage is a silver dollar sized scar on my wife's leg.
Unfortunately, MRSA is seeping into the populace at large, and many cases occur in people who haven't been in or near a hospital, so it doesn't spring to mind as readily as it would post-hospitalization. This means it gets treated later, and is thus harder to treat, and has more opportunity to spread.
We came out ok, but no mistake, this is nasty stuff, and some people fair much worse than we did.
--ihatethenewlogin
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As an ICU physician, I see a lot of cases of infection with drug-resistant bacteria. The excellent piece in Slate neglects two important points. One is the old saw of using anitbiotics only when indicated, that is not for "colds" and what we call "upper respiratory infections" such as bronchitis, which usually don't get better with antibiotics.
The other, more difficult, task is to use indicated antibiotics for less time. How long should a patient with an infection receive antibiotics? With a few exceptions, we just don't know. We choose an arbitrary length of treatment (say, 10 days, 14 days), but only rarely are these decisions driven by empiric data. The less time a patient receives antibiotics, the lower the probability of a bacteria developing resistance.
In the medical community, we need to do more research to help us make decisions about when it is safe to stop a course of antibiotics, and also better data on when antibiotics are really indicated.
--dak12
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The chief problem with bacteriocins is that they are produced by strains relatively closely related to the target. Classical antibiotics are produced by molds or actinomycetes and can target common molecules among large groups of bacteria. However, if you are closely related to your target, you have to be much more selective - and that makes mutation away from sensitivity easier. Resistance and immunity already generally exist in nature, and humans mass producing these bacteriocins will be just the sort of pressure needed to push these factors into the populations.
Phage have a related problem. Resistance to phage is already common, and phage can't be given in controlled dosages. This means that everybody near a person under phage therapy is also getting doses of the phage. This expands the population under selection for resistance, making resistance more readily available next time around.
Probiotics are also hard to modulate and control, and because they must be closely related to the pathogens, to hold a related niche, they can take up pathogen genes and become pathogens themselves. Further, they may cause some of the same problems as the pathogen, if they are put in an unwelcome place that should normally be sterile, like the bladder.
One interesting idea is to combine probiotics and bacteriocins. Use the bacteriocins to upset the applecart of the rock-paper-scissors game going on in the world (Kerr et al, Nature 2004/Kirkup and Riley, Nature 2004) and then add resistant probiotic bugs to quickly fill in the gap left behind.
There is lots to discuss about all the ways of dealing with antibiotic resistance. I hope people start thinking about this...
--BenK
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There are some great technologies that unfortunately are cheap and not patentable, and they work great, so they are never advertised. They aren't cool or attention-grabbing. They just work. For instance: Iodine.
Yeah, good ol' iodine. It went out of favor when it was discovered that the alcohol-base prevented healing. But not it's available in a povidone base. And you know what? It actually sinks into the skin and kills bacteria BELOW the skin. It prevents deep tissue infections in spinal surgery. Add a couple of drops to brine, and it cures nasal infections. It might be what makes "sea air" so healthful. Bacteria haven't developed a resistance to it, even after a few million years.
--HeidiS13
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