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How an ion pump could transform cancer treatment

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The recurrence of malignant brain tumours has long challenged health tech innovators aiming to improve cancer treatments and outcomes. But European researchers now believe an ion pump may offer a major step forward on this front.

They have shown in cells in culture that an ion pump can deliver drugs more accurately, which gives less severe adverse effects in chemotherapy.

The scientists in Sweden and Austria have used cells from glioblastoma, which is the most common and most aggressive type of cancer that can arise in the brain.

When a brain tumour is surgically removed, small parts of the tumour are often left behind, embedded between the brain cells.

Even high-precision surgery cannot remove these cells without damaging the surrounding healthy brain tissue.

This means that radiation treatment and chemotherapy are used to stop the recurrence of the tumour.

In Sweden, around 30 cytostatics are available to treat different types of cancer. These chemotherapy agents are most often given either intravenously or as a tablet.

But in order to reach the brain, they must first spread through the circulatory system and then pass through the blood-brain barrier.

The walls of the small blood vessels in the brain are much less permeable than blood vessels in the rest of the body, and can prevent many substances in the blood entering the brain. Thus, only a few drugs that work against cancer can pass through.

Scientists at Linköping University (Sweden) and at the Medical University of Graz (Austria) have now developed a method in which an implanted ion pump can be used to get around the blood-brain barrier and supply gemcitabine; an extremely effective chemotherapy agent that cannot normally pass the blood-brain barrier – directly into the brain with high precision.

Gemcitabine is currently used to treat cancers in the pancreas, bladder and breast, where it acts by disrupting the cell division process in rapidly growing tumours.

This means that gemcitabine does not affect brain cells, since these do not, in general, undergo cell division.

Daniel Simon, associate professor at the Laboratory of Organic Electronics at the Department of Science and Technology at Linköping University, says: “This is the first time an ion pump has been tested as a possible method to treat malignant brain tumours.

“We used cancer cells in the lab, and the results are extremely promising. However, it will probably take five to ten years before we see this new technology used in treatments for brain tumours.

Fellow researcher Linda Waldherr, of the Medical University of Graz, adds: “The traditional glioblastoma treatment currently used in the clinics harms both cancer and neuronal cells to the same extent.

“However, with the gemcitabine ion pump, we tackle only the cancerous cells, while neurons stay healthy. In addition, our experiments on cultured glioblastoma cells show that more cancer cells are killed when we use the ion pump than when we use manual treatment.

When the ion pump is to transport gemcitabine from an electrolyte reservoir into cells or a tumour, a low current is used to “pump” the positively charged drug through an ion transport channel.

The method is known as electrophoresis. The ion pump needs only a low current to pump the gemcitabine, which is an advantage since it avoids the risk that brain cells are activated and transmit unintended nerve signals.

The low current and voltage also mean that eventual therapeutic technology will not require large power supplies or batteries to operate.

Rainer Schindl, associate professor at the Medical University of Graz, describes other advantages.

“The pressure inside the brain is extremely sensitive, and using an ion pump to transport the drug instead of a fluid-driven device means that the pressure is not affected.

“Also, the dosage is controlled by electrical charging, which makes the supply of the chemotherapy agent extremely precise.

“The next step will be to use the ion pump to evaluate different chemotherapy agents that have previously given adverse effects that are too serious or that are unable to pass the blood-brain barrier.”

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  1. Pingback: Biomedical 'net' could help fight aggressive cancers like glioblastoma

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