The placenta is absolutely essential for supporting the baby as it grows inside the mother. When it doesn’t function properly, it can result in serious problems
- Margherita Turco
Details of this new research are published in the journal Nature.
Many pregnancies fail because the embryo does not implant correctly into the lining of the womb (uterus) and fails to form a placental attachment to the mother. Yet, because of the complexities of studying this early period of our development, very little is understood about what is happening normally and what can go wrong. Animals are too dissimilar to humans to provide a good model of placental development and implantation.
“The placenta is absolutely essential for supporting the baby as it grows inside the mother,” says Dr Margherita Turco, the study’s first author, from the Departments of Pathology and Physiology, Development and Neuroscience at the University of Cambridge. “When it doesn’t function properly, it can result in serious problems, from pre-eclampsia to miscarriage, with immediate and lifelong consequences for both mother and child. But our knowledge of this important organ is very limited because of a lack of good experimental models.”
Efforts to grow human placental cells started over 30 years ago in the Pathology department where Professors Ashley Moffett and Charlie Loke were studying cellular events in the first few weeks of pregnancy. With their chief technician, Lucy Gardner, they found ways to isolate and characterise placental trophoblast cells. These techniques, combined with the organoid culture system, enabled the generation of miniature functional models of the early placenta – or ‘mini-placentas’.
In the past few years, a new field of research has blossomed that uses these organoids – often referred to as ‘mini-organs’ – enabling insights into human biology and disease. At the University of Cambridge, one of the world leaders in organoid research, scientists are using organoid cultures to grow everything from ‘mini-brains’ to ‘mini-livers’ to ‘mini-lungs’.
Image Credit: Image reproduced with the permission of SPD Swiss Precision Diagnostics GmbH (SPD)
Reproduced courtesy of the University of Cambridge