Oregon Health & Science University research led by dentist, associate professor of biomedical engineering in the OHSU School of Medicine.
Tiny, 3D-printed bricks have been designed to heal broken bones—and could one day lead to lab-made organs for human transplant.
Inspired by Lego blocks, the small, hollow bricks serve as scaffolding onto which both hard and soft tissue can regrow better than today’s standard regeneration methods, according to new research published in Advanced Materials. Each brick is 1.5 millimeters cubed, or roughly the size of a small flea.
“Our patent-pending scaffolding is easy to use; it can be stacked together like Legos and placed in thousands of different configurations to match the complexity and size of almost any situation,” says Luiz Bertassoni, DDS, Ph.D., in a press release. Bertassoni led the technology’s development and is an associate professor in the Oregon Health & Science University (OHSU) School of Dentistry and an associate professor of biomedical engineering in the OHSU School of Medicine.
Bertassoni partnered with colleagues from OHSU, University of Oregon, New York University and Mahidol University in Thailand to develop and evaluate the technology.
When stacked together, the microcages are designed to repair broken bones better than today’s methods. Orthopaedic surgeons typically repair more complex bone fractures by implanting metal rods or plates to stabilize the bone and then inserting bio-compatible scaffolding materials packed with powders or pastes that promote healing.
A unique advantage of this new scaffolding system is that its hollow blocks can be filled with small amounts of gel containing various growth factors that are precisely placed closest to where they are needed. The study found growth factor-filled blocks placed near repaired rat bones led to about three times more blood vessel growth than conventional scaffolding material.
“The 3D-printed microcage technology improves healing by stimulating the right type of cells to grow in the right place, and at the right time,” says study co-author Ramesh Subbiah, Ph.D., a postdoctoral scholar in Bertassoni’s OHSU lab who specializes in growth factor delivery. “Different growth factors can be placed inside each block, enabling us to more precisely and quickly repair tissue.”
The small devices are modular and can be assembled to fit into almost any space. When piecing together block segments containing four layers of four-bricks-by-four bricks, the researchers estimate more than 29,000 different configurations can be created.
Bertassoni and colleagues also imagine their 3D-printed technology could be used to heal bones that have to be cut out for cancer treatment, for spinal fusion procedures and to build up weakened jaw bones ahead of a dental implant. And, by changing the composition of the technology’s 3D-printed materials, they envision it could also be used to build or repair soft tissues. With significantly more research, they hope the modular microcage approach could even be used to make organs for transplant.
Bertassoni and his team will further explore the microcages’ performance in bone repair. They plan to test the technology’s ability to repair more complex bone fractures in rats or larger animals.
This research was supported by National Institute of Dental and Craniofacial Research (grants R01DE026170, 3R01DE026170-03S1), National Center for Advancing Translational Sciences (grant UL1TR002369), Michigan-Pittsburgh-Wyss Resource Center’s Regenerative Medicine Resource Center and OHSU Fellowship for Diversity and Inclusion in Research.