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Print It: 3-D Bio-Printing Makes Better Regenerative Implants

The views expressed are those of the author and are not necessarily those of Scientific American.


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3-d bio-printing tissue scaffold cells

A 3-D printer; courtesy of Wikimedia Commons/Deezmaker

Desktop 3-D printers can already pump out a toy trinket, gear set or even parts to make another printer. Medical researchers are also taking advantage of this accelerating technology to expand their options for regenerative medicine. Brian Derby, of the School of Materials at the University of Manchester in England, details the advances and challenges of this growing field in a new review paper published online November 15 in Science.

Researchers have made great strides in coaxing cells to grow over artificial, porous scaffolds that can then be implanted in the body to replace hard tissue, such as bone. Three years ago, doctors were able to coax stem cells to grow over bone scaffolds, which regenerated bone to implant into the face of a teenage boy, who had a genetic defect that left him without cheekbones.

But now, instead of relying on poured molds, foam designs or donated biological materials, researchers can print custom scaffold structures with biocompatible, biodegradable polymers. “These methods have allowed us to develop very complex scaffolds which better mimic the conditions inside the body,” Derby said in a prepared statement.

Engineers can carefully control the minute, internal structures of these porous scaffolds to best promote cellular growth. And these new printing methods also allow quick and cheap experiments that test various one-off designs.

Advancing bio-printing technologies can also be used for the biological material itself. Like color printing, biomaterial printing can switch among different organic materials as well as produce gradients and blending. Inkjet printing is preferred for depositing cells themselves, and as a demonstration of this in the 1980s an unmodified HP desktop printer was used to print out collagen as well as tissuelike structures.

Printing, however, is tough on cells. Some studies have successfully kept more than 95 percent of cells intact through the process, but others have not done as well—losing more than half from damaged membranes.

The future of bio-printing may be the combination of these approaches—printing both highly specific scaffolds and cell structures. Recent research has shown that stem cell fate can be controlled by the surfaces onto which the cells are printed.

The promise of printing-based tissue regeneration would go a long way to improve rejection issues (because a patient’s own cells are used) and with regrowing tissue in places that have proved tough to re-create with other methods. “It is very difficult to transplant even a small patch of tissue to repair inside the nose or mouth,” Derby said. “Current practice, to transplant the patient’s skin to these areas, is regarded as unsatisfactory because the transplants do not possess mucous generating cells or salivary glands. We are working on techniques to print sheets of cells” that would more mimic the natural environment of these organs.

These techniques could also be used to study disease outside the human body. For example, if researchers can develop a structure that produces cancerous cell growth, they could test new drugs and treatments before starting human trails.

But before we have print-on-demand hearts, kidneys and eyes, we have a long way to go in learning about how to make more heterogeneous and solid structures as well as sustaining, healthy tissue networks. “Considering that our ability to fabricate and characterize simple, single-material scaffolds is relatively recent, the target of a printed tissue is highly ambitious,” Derby wrote. But these technologies will eventually create “new areas of research in tissue engineering and regenerative medicine.”

Katherine Harmon Courage About the Author: Katherine Harmon Courage is a freelance writer and contributing editor for Scientific American. Her book Octopus! The Most Mysterious Creature In the Sea is out now from Penguin/Current. Follow on Twitter @KHCourage.

The views expressed are those of the author and are not necessarily those of Scientific American.





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  1. 1. Truthseeker 3:38 am 11/22/2012

    I hope this can be exploited for other uses. Over a decade ago I had 2 intervertebral discs removed and 3 cervical vertebrae fused. At that time the only choice for material for the fusion was between cadaver bone and an autograft harvested from my illiac crest. Everyone with whom I communicated about the autograft indicated that the result was very painful. Any cadaver bone graft carries a minute chance for infection. Additionally the success rate with cadaver bone is slightly lower (a couple of percentage points) than for the autograft. If this technique could be used in spinal fusion, it would appear to have all the advantages of an autograft without any of the disadvantages. Plus the cost trade off of a second surgery versus printing/growing the graft should be favorable. Add in the reduced opportunity for nosocomial infection by eliminating the extra surgical procedure and this could be very useful.

    Imagine being able to harvest a patient’s stem cells, grow a new piece of bone and then implant it as needed.

    Now, if we could only trick those little devils into growing into a complete organ – say a heart or liver or whatever – then the only wait for a replacement organ would be for the time for it to be grown instead of waiting for a compatible donor to die!

    Link to this

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