By Heriot-Watt University
The process, developed at Heriot-Watt University, in partnership with Roslin Cellab, takes advantage of the fact that stem cells can now be grown in laboratory conditions from established cell lines, could also speed up and improve the process of drug testing by growing three-dimensional human tissues and structures for pharmaceuticals to be tested on.
A new valve-based technique
A range of human stem cell cultures can now be grown, generation after generation, in laboratory conditions.
Those cultures developed from cells from areas like bone marrow or skin are hardier but less flexible than those developed from embryonic material.
While 3D printing of the tougher cell cultures has been achieved before, the new valve-based technique developed by Dr Will Shu and his colleagues at Heriot-Watt’s Biomedical Microengineering group are the first to print the more delicate embryonic cell cultures, which have an ability to replicate indefinitely and differentiate into almost any cell type in the human body.
Dr. Shu said, “To the best of our knowledge, this is the first time that these cells have been 3D printed. The technique will allow us to create more accurate human tissue models which are essential to in vitro drug development and toxicity-testing. Since the majority of drug discovery is targeting human disease, it makes sense to use human tissues.
“In the longer term, we envisage the technology being further developed to create viable 3D organs for medical implantation from a patient’s own cells, eliminating the need for organ donation, immune suppression and the problem of transplant rejection.”
Dr Shu’s team are working with Roslin Cellab, a leading stem cell technology company. The company has a good track record of applying new technologies to human stem cell systems and will take the lead in developing 3D stem cell printing for commercial uses. Initially this will be in the areas of novel drug-testing products but in the longer term there is the goal of growing purpose-built replacement organs.
Valuable long-term implications
Jason King, business development manager of Roslin Cellab, said, “This world-first printing of human embryonic stem cell cultures is a continuation of our productive partnership with Heriot-Watt. Normally laboratory grown cells grow in 2D but some cell types have been printed in 3D. However, up to now, human stem cell cultures have been too sensitive to manipulate in this way.
“This is a scientific development which we hope and believe will have immensely valuable long-term implications for reliable, animal-free drug-testing and, in the longer term to provide organs for transplant on demand, without the need for donation and without the problems of immune suppression and potential organ rejection.”
About Heriot-Watt University
With a history dating back to 1821, Heriot-Watt University has established a reputation for world-class teaching and practical, leading-edge research, which has made Heriot-Watt University one of the top UK universities for business and industry.
Heriot-Watt is also Scotland’s most international university with an unsurpassed international in-country presence. The university delivers degree programmes to 11,800 students in 150 countries around the world, with a campus in Dubai, a new campus opening in Malaysia and boasting the largest international student cohort in Scotland.
Our sincere appreciation to Sue Campbell, Caroline Dempster and Heriot-Watt University for permission to publish content of this extraordinary AM fabrication technique.
Heriot-Watt University
Sue Campbell
Head of Communications
0131 451 3920
s.campbell@hw.ac.uk
Corporate Communications
External Affairs Directorate
Caroline Dempster
Press Officer
0131-451 3443
C.M.L.Dempster@hw.ac.uk
Heriot-Watt University
Edinburgh
EH14 4AS
www.hw.ac.uk
