Chuck, good question, but I suspect we'd have to ask a surgeon that specializes in this surgery to find actual lifetime info for a given implant (or access the sugeons-only info on the manufacturer's website). Aside from replacing degenerated bone that has been removed, as williamlweaver points out, the main function of the device is apparently to support new bone growth, no easy task. As the manufacturer's website does say, the other implants made of this material have been used successfully for several years.
I have to agree. Not only is the application itself very cool, but the development process itself is fascinating. I can almost see the future of active older adults careening down zip-lines and skydiving with impunity using their new tantalum-strengthed spines for support.
Warren, I certainly agree. Being a "baby-boomer" myself, I can't tell you the number of family, friends, etc I know that could benefit from this technology RIGHT NOW. One very important sentence Ann put in her write-up--"THE MATERIAL HAS A HISTORY OF SEVERAL YEARS OF CLINICAL SUCCESS AS AN IMPLANT", indicates it could be ready for "prime time". I don't know the regulatory processes necessary for approval but if the technology is there, considerable suffering could be lessened and possibly eliminated. This is anoter great example of how engneering contributes to our society and how significant problems can be solved when proper engineering is applied. Great article Ann.
Hi Chuck... I'm pretty sure the porous Tantalum substrate serves as a scaffold for new bone growth. Over time the metal implant becomes more natural bone than metal, providing the required mechanical and fatigue strength.
I do wonder about the performance of this material (especially in terms of elasticity) over time. Human backs do a lot of bending, twisting and compressing. This is an application where you can't afford to have plastic failure. Any idea how long this would last, Ann?
williamlweaver, I also found the manufacturing process fascinating, especially the use of vapor deposition processes, which I've encountered previously in electronics manufacturing contexts. I'm not sure if you intended this implication, but your comment sounds like you may be thinking of the possibility of extending the materials and/or processes described in the article to biocompatible materials in electronics. Is that an accurate guess?
warren, I had the same idea about "nano" regarding the material's ability to be incorporated in to the body. As the article states, the manufacturer has already used this material successfully for making implants and other products for hips, knees, and extremities, as well as in the cervical spine (in the neck). What's new here is the use for the lumbar spine (in the lower back), at least in the US.
Use polymer methods to create the substrate material. Use foaming methods to create the correct porosity and shape. Pyrolyze the polymer to create a carbon latice with the appropriate geometry and then use this latice as an engineered scaffold to assemble the tantalum via vapor deposition.
How freaking elegant is that!? =]
I agree my analogy to cermets is pretty loose. The resulting tantalum structure doesn't appear to get it's final mechanical properties as a polymer/metal composite.
I'm just wondering how soon this type of manufacturing process will be adopted for zeolite catalysts and other high-surface area materials like fuel cells. Maybe it already has... Great stuff!
Truchard will be presented the award at the 2014 Golden Mousetrap Awards ceremony during the co-located events Pacific Design & Manufacturing, MD&M West, WestPack, PLASTEC West, Electronics West, ATX West, and AeroCon.
In a bid to boost the viability of lithium-based electric car batteries, a team at Lawrence Berkeley National Laboratory has developed a chemistry that could possibly double an EV’s driving range while cutting its battery cost in half.
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