Printing drugs can ease burden of multiple pills a day

Printing drugs can ease burden of multiple pills a day

A new technology can print pure, precisely customized doses of drugs.

The technology could enable on-site printing of custom-dosed medications at pharmacies, hospitals, and other locations.

The technique can print multiple medications into a single dose on a dissolvable strip, microneedle patch, or other dosing device.

The researchers say it could make life easier for patients who must now take multiple medications every day. The work could also accelerate drug development.

A new study showed that the pure printed medication can destroy cultured cancer cells in the lab as effectively as medication delivered by traditional means, which rely on chemical solvents to enable the cells to absorb the medication.

The researchers adapted a technology from electronics manufacturing called organic vapor-jet printing. One key advantage of the technique is that it can print a very fine crystalline structure over a large surface area.

This helps printed medications dissolve more easily, opening the door to a variety of potential new drugs that today are shelved because they don’t dissolve well when administered with conventional approaches, including pills and capsules.

“Pharma companies have libraries of millions of compounds to evaluate, and one of the first tests is solubility,” Shtein says.

“About half of new compounds fail this test and are ruled out. Organic vapor jet printing could make some of them more soluble, putting them back into the pipeline.”

“This technology offers up a new approach to accelerate the evaluation of new medicines.”

The process begins by heating the active pharmaceutical ingredient—usually a powder—and evaporating it to combine it with a stream of heated, inert gas like nitrogen.

The evaporated medication travels, along with the gas, through a nozzle pointed at a cooled surface. The medication then condenses, sticking to the cooled surface in a thin crystalline film.

The formation of the film can be tightly controlled by fine-tuning the printing process. The process requires no solvents, no additives, and no post-processing.

“Organic vapor jet printing may be useful for a variety of drug delivery applications for the safe and effective delivery of therapeutic agents to target tissues and organs,” says coauthor Geeta Mehta.

The tight control over solubility may also be useful later in the drug testing process, when potential new drugs are applied to cultured cells in a lab.

Today, most compounds must be dissolved in a chemical solvent before they’re applied to cells. The new technique could enable printed medications to dissolve easily in the water-based medium used to culture cells, without the need for a solvent.

While printing mass-market drugs is likely years away, Shtein believes that the drug characterization and testing applications may come to fruition more quickly—internally in pharmaceutical companies.

The team is exploring additional applications for the technology and plans to collaborate with experts in pharmaceutical compound design and manufacturing, as well as those working on treatments.

Eventually, they envision vapor jet printing being scaled to mass production, including roll-to-roll continuous manufacturing.

Their study appears in the journal Nature Communications.

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News source: University of Michigan. The content is edited for length and style purposes.
Figure legend: This image is for illustrative purposes only.