When it comes to 3D bioprinting with stem cells the obvious endgame is the ability to produce complex living tissue, such as replacement organs or biological matter. The potential future applications would completely change the world in numerous ways that are difficult to even predict. Transplant organs grown from a patient’s own DNA would be only one of the many uses of complex 3D bioprinted tissue; animal testing could be rendered completely unnecessary, as would the slaughter of animals as a food source. And while we are probably decades away from being able to produce even the simplest of living tissues, researchers and scientists are inching ever closer.
Essentially, the test cell structures showed the potential of dividing and organizing themselves into complex, living tissue. While the tissue is typically only viable for a week, the fact that they were able to create stable groups of living cells for that length of time is remarkable. Other existing methods of growing stem cells were incapable of producing the types of cellular structures that the researchers were trying to grow, only the 3D printed method produced their desired results. A paper, titled ‘Three-dimensional bioprinting of embryonic stem cells directs highly uniform embryoid body formation,’ detailing the results of their 3D bioprinting process was just published in the medical journal Biofabrication. The paper’s authors included Liliang Ouyang, Rui Yao, Shuangshuang Mao, Xi Chen, Jie Na, and Wei Sun.
“It was really exciting to see that we could grow embryoid body in such a controlled manner. The grown embryoid body is uniform and homogenous, and serves as a much better starting point for further tissue growth. Two other common methods of printing these cells are either two-dimensional (in a petri dish) or via the ‘suspension’ method (where a ‘stalagmite’ of cells is built up by material being dropped via gravity.). However, these don’t show the same cell uniformity and homogenous proliferation. I think that we’ve produced a 3D microenvironment which is much more like that found in vivo for growing embryoid body, which explains the higher levels of cell proliferation,” explained the paper’s lead author, Wei Sun.
Bioprinting with stem cells, which are capable of turning into every cell type in the body, could potentially lead to the ability to build complex tissue structures and possibly even micro-organs. The team of researchers are also hopeful that their technique will be capable of producing an embryoid body quickly at high volumes. These quickly grown embryonic structures would allow other researchers the ability to perform tissue regeneration experiments or test the effects of drugs and chemicals on living tissue.
“Our next step is to find out more about how we can vary the size of the embryoid body by changing the printing and structural parameters, and how varying the embryoid body size leads to ‘manufacture’ of different cell types,” said another of the paper’s authors, Rui Yao.
The team is hoping to continue their research and expand the scope of their stem cell production process. First they want to learn how to alter the size and shape of the stem cells with simple adjustments to their bioprinting method. The next step would be studying exactly how those size changes would affect the cell’s development and differentiation, and if the grid pattern would produce the same results with the different sized cells. You can read the entire study online for free here.