Someday Soon We May Be Able ( Need) to 3D Print Replacement Hearts
The Ability and Need to 3D Print Replacement Hearts.
In the U.S. someone dies of heart disease every 43 seconds. That is to say that one in four Americans alive today will die of this disease. The causes for heart disease are known to be preventable with the proper exercise and diet but often the only answer for patients is too replace their heart or die.
Now advancements in 3D printing may someday lead to a world where people ( rich people?) simply have a new body part made and schedule replacement. No more worrying about lifestyle habits getting in the way of an enjoyable life. Anyways, here is the news below, you decide.
As of this month, over 4,000 Americans are on the waiting list to receive a heart transplant. With failing hearts, these patients have no other options; heart tissue, unlike other parts of the body, is unable to heal itself once it is damaged. Fortunately, recent work by a group at Carnegie Mellon could one day lead to a world in which transplants are no longer necessary to repair damaged organs.
Adam Feinberg, an associate professor of Materials Science and Engineering and Biomedical Engineering at Carnegie Mellon University, commented:
We’ve been able to take MRI images of coronary arteries and 3-D images of embryonic hearts and 3-D bioprint them with unprecedented resolution and quality out of very soft materials like collagens, alginates and fibrins.
Feinberg leads the Regenerative Biomaterials and Therapeutics Group, and the group’s study was published in the October 23 issue of the journal Science Advances. A demonstration of the technology can be viewed online.
“As excellently demonstrated by Professor Feinberg’s work in bioprinting, our CMU researchers continue to develop novel solutions like this for problems that can have a transformational effect on society,” said Jim Garrett, Dean of Carnegie Mellon’s College of Engineering.
We should expect to see 3-D bioprinting continue to grow as an important tool for a large number of medical applications.
Traditional 3-D printers build hard objects typically made of plastic or metal, and they work by depositing material onto a surface layer-by-layer to create the 3-D object. Printing each layer requires sturdy support from the layers below, so printing with soft materials like gels has been limited.
“3-D printing of various materials has been a common trend in tissue engineering in the last decade, but until now, no one had developed a method for assembling common tissue engineering gels like collagen or fibrin,” said TJ Hinton, a graduate student in biomedical engineering at Carnegie Mellon and lead author of the study.
“The challenge with soft materials — think about something like Jello that we eat — is that they collapse under their own weight when 3-D printed in air,” explained Feinberg.
So we developed a method of printing these soft materials inside a support bath material. Essentially, we print one gel inside of another gel, which allows us to accurately position the soft material as it’s being printed, layer-by-layer.
One of the major advances of this technique, termed FRESH, or “Freeform Reversible Embedding of Suspended Hydrogels,” is that the support gel can be easily melted away and removed by heating to body temperature, which does not damage the delicate biological molecules or living cells that were bioprinted. As a next step, the group is working towards incorporating real heart cells into these 3-D printed tissue structures, providing a scaffold to help form contractile muscle.
Bioprinting is a growing field, but to date, most 3-D bioprinters have cost over $100,000 and/or require specialized expertise to operate, limiting wider-spread adoption. Feinberg’s group, however, has been able to implement their technique on a range of consumer-level 3-D printers, which cost less than $1,000 by utilizing open-source hardware and software.
“Not only is the cost low, but by using open-source software, we have access to fine-tune the print parameters, optimize what we’re doing and maximize the quality of what we’re printing,” Feinberg said.
It has really enabled us to accelerate development of new materials and innovate in this space. And we are also contributing back by releasing our 3-D printer designs under an open-source license.
Credit: Carnegie Mellon University College of Engineering