Medical

Molecular drills tear into superbugs' antibiotic defenses

Molecular drills tear into superbugs' antibiotic defenses
A Klebsiella pneumoniae bacteria after being attacked by the molecular drills. The yellow arrows indicate cell wall holes, and the purple shows where material is leaking from inside
A Klebsiella pneumoniae bacteria after being attacked by the molecular drills. The yellow arrows indicate cell wall holes, and the purple shows where material is leaking from inside
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A Klebsiella pneumoniae bacteria after being attacked by the molecular drills. The yellow arrows indicate cell wall holes, and the purple shows where material is leaking from inside
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A Klebsiella pneumoniae bacteria after being attacked by the molecular drills. The yellow arrows indicate cell wall holes, and the purple shows where material is leaking from inside
A microscope image of Klebsiella pneumoniae after being targeted by molecular drills. The insides of the bacteria are leaking out at the red arrow
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A microscope image of Klebsiella pneumoniae after being targeted by molecular drills. The insides of the bacteria are leaking out at the red arrow
A diagram showing how the molecular drills work to kill bacteria
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A diagram showing how the molecular drills work to kill bacteria
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Bacteria are quickly evolving resistance to our best drugs, threatening to make the most mundane infections lethal once again. Now, researchers at Rice University have developed a new method to kill these emerging superbugs, using molecular “drills” to pierce their cell walls. The same technique has also been shown to work on cancer cells.

Chemicals such as drugs may be effective for a while, but eventually individual bacteria will randomly mutate a way to defend themselves. These lucky few will be the only ones to survive an antibiotic attack, meaning they’ll reproduce and spread the beneficial mutation to future generations. Some of these defense mechanisms include building stronger cell walls that the drugs can’t get through, or “pumps” that let the bugs spit out antibiotics before they can do any harm.

But while they may outsmart chemical attacks, bacteria are helpless to defend themselves against physical assaults. It’s similar to how the human immune system can fight off an otherwise-lethal flu infection, but won’t be able to stop a bullet. And this is the idea behind the latest research from the James Tour Lab at Rice University.

The team has developed motorized molecules shaped a little like paddles, that seek out target cells and attach themselves to the surface. Once activated with light, they spin up to three million times a second, drilling into the cell wall. If that doesn’t kill the bacteria outright, then it provides a way for antibiotics to get in and do their job – even those the bug is already resistant to.

The researchers demonstrated the effectiveness of the technique on Klebsiella pneumoniae, a nasty little bug that causes pneumonia or urinary tract infections. Adding a small amount of the molecular drills to colonies, the team was able to kill up to 17 percent of bacteria on their own. When the drills were administered alongside the antibiotic meropenem, 65 percent were killed. With some more tweaking, this number was eventually raised to an astounding 94 percent.

Interestingly, these bacteria had already developed resistance to meropenem alone, indicating that the technique could help supercharge existing antibiotics that are no longer effective.

“Now we can get (the drug) through the cell wall,” says James Tour, lead researcher on the study. “This can breathe new life into ineffective antibiotics by using them in combination with the molecular drills.”

A microscope image of Klebsiella pneumoniae after being targeted by molecular drills. The insides of the bacteria are leaking out at the red arrow
A microscope image of Klebsiella pneumoniae after being targeted by molecular drills. The insides of the bacteria are leaking out at the red arrow

Since the technique is reliant on light as a trigger, the researchers say that in its current form it would be most useful for treating infections on the skin, in wounds, around implants, or in easily accessible internal areas.

“On the skin, in the lungs or in the GI tract, wherever we can introduce a light source, we can attack these bacteria,” says Tour. “Or one could have the blood flow through a light-containing external box and then back into the body to kill blood-borne bacteria.”

The technology doesn’t just apply to bacteria though – as the team demonstrated back in 2017, these molecular drills can be trained on cancer cells as well. In a separate new study, the Rice researchers tested it out on pancreatic cancer cells, with promising results. Where the earlier study activated them with UV light, the new one used visible light, which should be less damaging to healthy cells.

Using mechanical means to kill bacteria could be the most promising method to prevent the rise of superbugs. Other techniques based on the same idea include hydrogels, materials, and black silicon, which all tear into the bacterial cell walls. Let’s see them evolve their way out of this one.

The bacteria study was published in the journal ACS Nano, while the cancer paper appeared in ACS Applied Materials Interfaces.

Source: Rice University

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4 comments
4 comments
Expanded Viewpoint
What about Rife technology based treatments? That stuff is STILL being buried and suppressed today! I guess that if it's totally non-invasive treatment, it doesn't get looked at.

Randy
Signguy
3 million spins per second!?
How do they measure THAT?
ljaques
Cool stuff. How are they flushed from the human systems after they're done?
polylysines.com
It was a heartless thing to do. Such an action would invite retaliation.
Polylysine is non-toxic, environment-friendly.