New 3-D Nanoprinting Strategy Opens Door to Revolution in Medicine, Robotics

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Engineers at the University of Maryland (UMD) have created the first 3D-printed fluid circuit element so tiny that 10 could rest on the width of a human hair. The diode ensures fluids move in only a single direction—a critical feature for products like implantable devices that release therapies directly into the body.

Image Caption: Sochol, along with graduate students Andrew Lamont and Abdullah Alsharhan, outlined their new strategy in a paper published today in the open-access journal Scientific Reports (Geometric Determinants of In-Situ Direct Laser Writing).

The microfluidic diode also represents the first use of a 3D nanoprinting strategy that breaks through previous cost and complexity barriers hindering advancements in areas from personalized medicine to drug delivery.

"Just as shrinking electric circuits revolutionized the field of electronics, the ability to dramatically reduce the size of 3D printed microfluidic circuitry sets the stage for a new era in fields like pharmaceutical screening, medical diagnostics, and microrobotics," said Ryan Sochol, an assistant professor in mechanical engineering and bioengineering at UMD's A. James Clark School of Engineering.

Engineers at the University of Maryland (UMD) have created the first 3D-printed fluid circuit element so tiny that 10 could rest on the width of a human hair. The diode ensures fluids move in only a single direction—a critical feature for products like implantable devices that release therapies directly into the body. (click on image to enlarge)

Scientists have in recent years tapped into the emerging technology of 3D nanoprinting to build medical devices and create "organ-on-a-chip" systems. But the complexity of pushing pharmaceuticals, nutrients, and other fluids into such small environments without leakage—and the costs of overcoming those complexities—made the technology impractical for most applications requiring precise fluid control.

Instead, researchers were limited to additive manufacturing technologies that print features significantly larger than the new UMD fluid diode.

"This really put a limit on how small your device could be," said Lamont, a bioengineering student who developed the approach and led the tests as part of his doctoral research. "After all, the microfluidic circuitry in your microrobot can't be larger than the robot itself."

What sets the Clark School team's strategy apart is its use of a process known as sol-gel, which allowed them to anchor their diode to the walls of a microscale channel printed with a common polymer. The diode's minute architecture was then printed directly inside of the channel—layer-by-layer, from the top of the channel down.

The result is a fully sealed, 3D microfluidic diode created at a fraction of the cost and in less time than previous approaches.

The strong seal they achieved, which will protect the circuit from contamination and ensure any fluid pushed through the diode isn't released at the wrong time or place, was further strengthened by a reshaping of the microchannel walls.

"Where previous methods required researchers to sacrifice time and cost to build similar components, our approach allows us to essentially have our cake and eat it too," Sochol said. "Now, researchers can 3D nanoprint complex fluidic systems faster, cheaper, and with less labor than ever before."