Emerging Implant Technologies‘ (EIT) Cellular Titanium is an example of one of those extraordinary materials. The porous titanium was specially designed to integrate with the body as much as possible, and its structure engineered to facilitate bone growth. Its structure mimics that of trabecular bone, also known as cancellous or spongy bone, which makes up the inner layer of bones. According to EIT, Cellular Titanium features 80% porosity and a diamond pore size of ~ 650 μm, making it similar enough to the structure of cancellous bone that bone grafting is not necessary; the body’s existing bone naturally incorporates the implants.
3D printed from biocompatible titanium alloy TiAl6V4, Cellular Titanium’s combination of solid and cellular implant architecture actually encourages the growth of natural trabecular and cortical (the outside of the bone) bone. The material is hydrophilic, designed for maximum blood contact and leading to accelerated protein and mesenchymal cell attachment and bone cell differentiation. The implants have been used in procedures including:
- Anterior Lumbar Interbody Fusion (ALIF)
- Transforaminal Lumbar Interbody Fusion (TLIF)
- Posterior Lumbar Interbody Fusion (PLIF)
- Cervical operations
“This is a major milestone for EIT,” said Guntmar Eisen, Co-Founder and CEO of EIT. “We look forward to bringing our unique technologies to the United States and partnering with top tier surgeons and institutions to bring the best results to patients that are in need of these devices.”
EIT has only been around since 2014, but its technology has already made an impact across the world. It’s focused solely on implants for spinal alignment, and Cellular Titanium was designed to overcome a number of shortcomings that make conventional implant designs and materials problematic, such as non-fusion, biocompatibility issues, subsidence, migration and imaging distortion. The implants are 3D printed using Selective Laser Melting (SLM) technology and finished with proprietary post-processing methods.
Case studies and retrieval analysis have shown extensive bone intergrowth throughout the implants in both the cervical and lumbar spine within a short period of time. In addition, the design of the implants allows them to be imaged clearly on X-ray and MRi machines, unlike solid metal. All around, Cellular Titanium is an example of how 3D printing can create devices that are so finely tuned to the body that they become part of the body itself, rather than foreign objects.
You can learn more about Cellular Titanium below:
Discuss in the Cellular Titanium forum at 3DPB.com.
[Images: EIT]