Sound waves could activate chemo drugs

Researchers at Syracuse University have developed a method to activate chemotherapy drugs precisely where they’re needed using sound waves, sparing healthy cells.
The approach uses ultrasound waves to trigger a chemical transformation in a specially designed prodrug, releasing the active drug only in targeted areas like tumors.
The technology has the potential to minimize side effects and enhance treatment precision, making it a promising new path toward safer and more effective cancer treatment.
The researchers are now working to refine the process and make it translatable with existing ultrasound infrastructure, which could enable oncologists to use ultrasound equipment for both diagnosis and drug activation during treatment.
The potential impact of this technology extends far beyond the lab, with the goal of reducing the physical and emotional toll of chemotherapy, improving patient outcomes, and lowering healthcare costs.

Colorful sound waves on a black background.

Chemists are testing a new method of using sound waves to activate chemotherapy drugs precisely where they’re needed while sparing healthy cells.

Chemotherapy has long been a cornerstone of cancer treatment, but its effectiveness comes at a cost. The powerful drugs used to kill cancer cells often damage healthy tissues as well, leading to side effects ranging from nausea and fatigue to organ damage.

A team of researchers is working to change that.

Xiaoran Hu, assistant professor of chemistry at Syracuse University, has developed a method that could allow cancer-fighting drugs to be triggered precisely where they’re needed—inside tumors—while sparing the rest of the body.

Hu and his team, which includes researchers from the chemistry department, recently published their findings in the journal Chemical Science. Their paper explores how ultrasound waves can be used to activate chemotherapy drugs only in targeted areas, offering a new path toward safer, more effective cancer treatment.

“As an initial step toward developing a generally applicable platform, this approach holds promise for spatially controlled release of cytotoxic drugs in ultrasound-irradiated tissue regions, minimizing off-target side effects. To put it simply, if a handheld ultrasound instrument or tool at the bedside can be used to guide or activate drugs, many patients could benefit in the future,” says Hu.

At the heart of their research is the concept of a prodrug—a compound that remains inactive until it’s triggered to unmask its therapeutic effects. Traditionally, prodrugs are activated by internal conditions like low pH or specific enzymes found in tumors. However, these triggers can also be present in healthy tissues, leading to unintended side effects.

Hu’s team is taking a different approach. Instead of relying on internal triggers, they’re using ultrasound, a safe and non-invasive technology commonly used in medical imaging. Unlike light-based activation methods, which struggle to penetrate deep tissues, ultrasound can reach tumors located deep within the body and be precisely targeted.

The process begins with a specially designed prodrug that remains inactive as it circulates through the body. When ultrasound is applied to a specific area—such as a tumor site—it generates hydroxyl radicals, short-lived reactive species that trigger a chemical transformation in the prodrug. This transformation releases the active drug precisely where it’s needed, restoring its cancer-fighting power while minimizing toxicity to healthy cells.

“Ultrasound is a widely used imaging technology, but its chemical effects remain largely unexplored in biomedical contexts. Our team aims to harness ultrasound to drive beneficial chemical reactions in biology and medicine. The strategy in our newest publication allows for externally controlled release of drugs in ultrasound-irradiated regions,” says Hu. “It holds promise to minimize side effects while enhancing treatment precision.”

The implications for cancer care could be significant. Oncologists could use existing ultrasound equipment not only for diagnosis but also to activate chemotherapy drugs during treatment. This dual use could streamline care and improve outcomes.

“Ultrasound is already integral to oncology procedures, such as breast cancer diagnosis and interventions,” Hu notes. “Our platform leverages this trajectory and is potentially translatable with existing ultrasound infrastructure.”

While the technology is still in its early stages, Hu and his team are optimistic about its future. They’re now working to refine how the ultrasound activates the drugs, making the release process even more efficient. They’re also collaborating with other researchers to move this technology closer to potential use in patients.

The potential impact of Hu’s research extends far beyond the lab. By enabling more precise drug delivery, the technology could one day reduce the physical and emotional toll of chemotherapy, improve patient outcomes and lower health care costs.

Source: Syracuse University

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Q. What is the main challenge with traditional chemotherapy drugs?

A. Traditional chemotherapy drugs often damage healthy tissues, leading to side effects ranging from nausea and fatigue to organ damage.

Q. Who developed a new method of using sound waves to activate chemotherapy drugs precisely where they’re needed?

A. Xiaoran Hu, assistant professor of chemistry at Syracuse University, has developed this method.

Q. What is the concept behind the prodrug used in the research?

A. A prodrug is a compound that remains inactive until it’s triggered to unmask its therapeutic effects.

Q. How are ultrasound waves being used in the research?

A. Ultrasound waves are being used to generate hydroxyl radicals, which trigger a chemical transformation in the prodrug and release the active drug precisely where it’s needed.

Q. What is the benefit of using ultrasound instead of internal triggers for prodrugs?

A. Using ultrasound avoids the risk of unintended side effects that can occur when relying on internal triggers found in healthy tissues.

Q. How does the process work when ultrasound is applied to a specific area?

A. When ultrasound is applied, it generates hydroxyl radicals, which trigger a chemical transformation in the prodrug and release the active drug precisely where it’s needed.

Q. What are the implications for cancer care if this technology becomes available?

A. Oncologists could use existing ultrasound equipment not only for diagnosis but also to activate chemotherapy drugs during treatment, potentially streamlining care and improving outcomes.

Q. How does this technology compare to light-based activation methods?

A. Ultrasound can reach tumors located deep within the body and be precisely targeted, unlike light-based activation methods which struggle to penetrate deep tissues.

Q. What is the potential impact of this research on patient outcomes and healthcare costs?

A. The technology could one day reduce the physical and emotional toll of chemotherapy, improve patient outcomes, and lower healthcare costs.

Q. Is this technology still in its early stages?

A. Yes, the technology is still in its early stages, but researchers are optimistic about its future and working to refine it further.