Tiny Backpacks Created for Drug Delivery Assist in Cancer Diagnosis

Engineers have outfitted cells with tiny "backpacks" that could allow them to deliver chemotherapy agents, diagnose tumors, or become building blocks for tissue engineering.

Dr. Michael Rubner, director of the Massachusetts Institute of Technology's (MIT; Cambridge, MA, USA) Center for Materials Science and Engineering and senior author of a study on the work that was published online in the journal Nano Letters on November 5, 2008, reported that he believes this is the first time anyone has attached such a synthetic patch to a cell.

The polymer backpacks allow researchers to use cells to transport tiny cargoes and manipulate their movements using magnetic fields. Since each patch covers only a small area of the cell surface, it does not interfere with the cell's normal functions or prevent it from interacting with the external environment. "The goal is to perturb the cell as little as possible," said Dr. Robert Cohen, a professor of chemical engineering at MIT and an author of the study.

The researchers worked with B and T cells, two types of immune cells that can home to various tissues in the body, including infection sites, tumors, and lymphoid tissues--a characteristic that could be exploited to achieve targeted drug or vaccine delivery. "The idea is that we use cells as vectors to carry materials to tumors, infection sites or other tissue sites," said Dr. Darrell Irvine, an author of the study and MIT associate professor of materials science and engineering and biologic engineering.

Cellular backpacks carrying chemotherapy agents could target tumor cells, while cells equipped with patches carrying imaging agents could help identify tumors by binding to protein markers expressed by cancer cells.

Another possible application is in tissue engineering. Patches could be designed that allow researchers to align cells in a specific pattern, eliminating the need for a tissue scaffold. The polymer patch system consists of three layers, each with a different function, stacked onto a surface. The bottom layer tethers the polymer to the surface, the middle layer contains the payload, and the top layer serves as a "hook" that grabs and binds cells.

Once the layers are set up, cells enter the system and flow across the surface, getting stuck on the polymer hooks. The patch is then detached from the surface by simply lowering the temperature, and the cells float away, with backpacks attached. "The rest of the cell is untouched and able to interact with the environment," said Dr. Albert Swiston, lead author of the paper and a graduate student in materials science and engineering.

The researchers discovered that T cells with backpacks were able to perform their normal functions, including migrating across a surface, just as they would without anything attached. By loading the backpacks with magnetic nanoparticles, they can control the cells' movement with a magnetic field. Because the polymer synthesis and assembly occurs before the patches are attached to cells, there is plenty of opportunity to modify the process to improve the polymers' effectiveness and ensure they won't be toxic to cells, the according to the researchers.

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