Scientists Create Artificial Bones From Wood

steve_thatguy writes "According to Discovery News, Italian scientists have made artificial bone from wood. Created by blasting wood blocks with heat until they are nearly pure carbon then coating them with calcium, the scientists say the material allows bones to heal faster and more securely. Unlike titanium, the wood-based artificial bones flex slightly much like real bone, and the porous nature of the wood allows for better bio-activity with surrounding tissue. Though human testing is still likely years away, the material is currently being used successfully in sheep and may have other industrial applications."

those poor chickens with boneless breasts

[goffster]

They now have hope

Re:those poor chickens with boneless breasts

[swanzilla]

how humerus

Re:those poor chickens with boneless breasts

[bughunter]

We chemistry nerds tend to party among ourselves. And we know all the best chemicals.

So yes, our parties are quite entertaining.

Plus, we like to blow shit up.

/hold my ethyl alcohol solution and watch this

Re:those poor chickens with boneless breasts

[thpr]

Purdue University http://www.youtube.com/watch?v=TBLr_XrooLs

Re:Bones out of wood?

that would be like me saying your brain is made of retard, when in fact, retard is just the end result

Move Over Lee Majors

[bradorsomething]

Gentlemen, we can rebuild him. We can make him stronger... faster... using the latest in prefabrication materials from Home Depot. He is... the Sixty-Five Dollar Man.

Re:Safer than Titaniam

[iroll]

My BS is Bioengineering (Materials), but I've been a physics teacher since I graduated, so I'm a little rusty. Take this with the requisite grain of salt =)

You're right, if you could just replace the whole femur, you'd eliminate the loading biocompatibility problems. The problem is that the femur as-a-whole is part of a complex and interconnected system, and would be many orders of magnitude more difficult to replace than the head alone. That tendons-and-cartilage problem is much, much harder than it sounds.

For starters, the top of the femur isn't connected to any muscles or ligaments, so we don't have to worry about reattaching them. Once the head of the femur is dislocated from the hip socket, the socket is replaced by a bioengineered version, and the top of the femur is cut off and replaced. The new ball/socket joint is reconnected, and the muscles naturally fold back around it.

Sounds simple, but this by itself is one of the most traumatic "routine" operations in the book. It's a massive, multi-hour undertaking, and requires a lot of blood and a lot of elbow grease. Removing the entire femur, while preserving all of the soft tissue around it, would be unimaginably difficult by comparison.

To replace the whole femur, all of the tendons and ligaments attached to the lower femur would have to be removed. Attaching them to a bioengineered substrate may be difficult or impossible. These aren't trivial connections, either. They're attached to the strongest muscles on your body, so they are subject to the most extreme forces in the body--hundreds if not thousands of PSI during heavy exertion (running, jumping, etc).

Titanium, in particular, would be a great candidate for a whole-bone replacement, if all it had to do was be a "mechanical" member. But getting the body to integrate with titanium--which you'd need, to keep those ligaments attached--is insidiously hard. One of the reasons why this new material is exciting is because the body integrates it much differently, by using it as a frame for normal growth (filling in the holes in the artificial bone with natural bone). Titanium is treated differently--the body effectively walls it off with a special type of soft tissue. It's "biocompatible" only in the sense that it doesn't provoke any kind of dangerous immune response; it is not a good substrate for normal tissue growth. Very, very few materials are, and most of them are highly engineered plastics with special protein coatings.

You also can't easily engineer a "half" replacement for the knee--knee replacements replace both sides of the joint. So, now you're chopping up the top of the tibia to provide a mate for your artificial femur. Which leads you right back to the same kind of problem.

Hip replacements used to be much worse than they are now; the mechanics have improved by leaps and bounds. They've gotten to the point where most people who need one (elderly, >60 yrs) will ONLY need one during their lives; it's younger athletes (Bo Jackson) and rheumatoid arthritis sufferers who have the bulk of their life ahead of them who are in danger of needing multiple rounds of replacement.