Design and operation of the NES. (A) Cells are cultured on the NS membrane in a well plate geometry. (B) The delivery reagent is placed under the bottom of the reservoir. An electric field is applied between the platinum and ITO electrode to deliver exogenous molecules into cells. (C) Schematic of NES delivery mechanism. The molecules beneath the NS membrane are electrophoretically injected into cells of interest through the NS. The delivered concentration (Cin) is in quadratic relationship with voltage intensity that is applied to the cells (V) and is proportional to the concentration of exogenous molecules (Cex) and the delivery duration. (D) SEM image of the NS protruding from the membrane. Scale bar, 300 nm. Credit: Science Advances (2018). DOI: 10.1126/sciadv.aat8131

Researchers can design the perfect molecule to edit a gene, treat cancer or guide the development of a stem cell, but none of that will matter in the end if they can't get their molecules into the human cells they want to manipulate. The solution to that problem, described in a study published October 31 in Science Advances, could be miniscule nanostraws, tiny glass-like protrusions which poke equally tiny holes in cell walls to deliver their cargo.

A team led by Nicholas Melosh, an associate professor of materials science and engineering, first began testing nanostraws about five years ago using relatively tough cell lines derived from cancers, mouse and other sources. Now, Melosh and colleagues have shown the technique works in human cells as well, a result that could speed up medical and biological research and could one day improve gene therapy for diseases of the eyes, immune system or cancers.

"What you're seeing is a huge push for gene therapy and cancer immunotherapy," said Melosh, who is also a member of Stanford Bio-X, Stanford ChEM-H and the Wu Tsai Neurosciences Institute, but existing techniques are not up the challenge of delivering materials to all the relevant human cell types, especially . "They're really tough compared to almost all other cells that we've handled," he said.

Crossing the cell membrane

The idea of transporting chemicals across the cell membrane and into the cell itself is not new, but there are a number of problems with the methods scientists have until now relied on. In one common , called electroporation, researchers use an electric current to open up holes in cell walls through which molecules such as DNA or proteins can diffuse through, but the method is imprecise and can kill many of the cells researchers are trying to work with.

In another method, researchers use viruses to carry the molecule of interest across a cell wall, but the virus itself carries risks. While there are similar methods that replace viruses with more benign chemicals, they are less precise and effective.

That was the state of affairs until just five or six years ago, when Melosh and colleagues came up with a new way of getting molecules into cells, based on Melosh's expertise in nano materials. They would use electroporation, but do it in a vastly more precise way with nanostraws, which because of their relatively long, narrow profile help concentrate electric currents into a very small space.

At the time, they tested that technique on animal cells sitting atop a bed of nanostraws. When they turned on an electric current, the nanostraws opened tiny, regularly sized pores in the cell membrane—enough that molecules can get in, but not enough to do serious damage.

The electric current served another purpose as well. Rather than waiting for molecules to randomly float through the newly opened pores, the current drew molecules straight in to the cell, increasing the speed and precision of the process. The question at that time was whether the technique would be as effective on the kinds of clinicians would need to manipulate to treat diseases.

Faster, Safer, More Precise

In the new paper, Melosh and team showed that the answer was yes—they successfully delivered molecules into three human cell types as well as mouse brain cells, all of which had proved difficult to work with in the past.

What's more, the method was more precise, faster and safer than other methods. The nanostraw technique took just 20 seconds to deliver to cells, compared with days for some methods, and killed fewer than ten percent of cells, a vast improvement over standard electroporation.

Melosh and his lab are now working to test the nanostraw method in some of the hardest to work with cells around, . If they succeed, it could be a big step not just for scientists who want to modify cells for research purposes, but also for medical doctors looking to treat cancer with immunotherapy, which right now involves modifying a person's immune cells using viral methods. Nanostraws would not only avoid that hazard but could potentially speed up the immunotherapy process and reduce its cost, as well, Melosh said.

More information: "Universal intracellular biomolecule delivery with precise dosage control," Science Advances (2018). DOI: 10.1126/sciadv.aat8131 , advances.sciencemag.org/content/4/10/eaat8131

Journal information: Science Advances