This website uses cookies primarily for visitor analytics. Certain pages will ask you to fill in contact details to receive additional information. On these pages you have the option of having the site log your details for future visits. Indicating you want the site to remember your details will place a cookie on your device. To view our full cookie policy, please click here. You can also view it at any time by going to our Contact Us page.

Swimming devices could deliver drugs inside the body

03 December 2015

A new method of guiding microscopic swimming devices has the potential to deliver drugs to a targeted location inside the body.

Photo: Ebbens group/University of Sheffield

Engineers at the University of Sheffield have discovered that tiny spherical bead-like devices can be guided by physical structures while swimming inside fluids. This opens up a wealth of future possibilities, such as using structures in the body to guide drug delivery, or cracks in rocks to direct environmental clean-up and exploration.

These devices, which are a similar size to cells and bacteria could be used to deliver drugs to a specific location inside the body or outside of the body to diagnose diseases in blood samples. Examples include finding proteins indicating cardiac problems or looking for circulating tumour cells that can indicate the spread of cancer.

When working with devices on a micron scale, it’s very challenging to produce motion from moving parts due to the properties of the fluid - it’s similar to humans trying to run through treacle. Previous research has focused on using external magnetic fields to guide the devices, but this requires constant observation so that the device can be guided manually.

The research conducted at Sheffield uses a new method, giving the devices a catalytic coating on one side, which creates a chemical reaction when fuel molecules are added, causing the device to move automatically on a pre-determined route, using natural structures as a guide.

“When you’re dealing with objects on such a small scale, we found that although our method of moving the devices using a coating and chemical reaction worked very effectively, it was difficult to control its direction, due to other molecules in the fluid jostling it," says the University of Sheffield's Dr Stephen Ebbens who led the research. “We’ve been working on ways to overcome this and control the movement of the devices along a path using physical structures to direct them. We are now working on applications for using these devices in the body, in the shorter term focusing on using them for medical diagnosis”

In addition to medical applications, these devices could be used in other fields, such as to locate indicators of contamination in environmental samples or to deliver neutralising chemicals to areas affected by oil spills, by using crevices in rocks as the structural guide.

This EPSRC funded research is reported in the journal, Nature Communications.


Print this page | E-mail this page