Living Autologous Heart Valves Engineered From Human Prenatally Harvested Progenitors
Do¨rthe Schmidt, MD; Anita Mol, PhD; Christian Breymann, MD; Josef Achermann, PhD;
Bernhard Odermatt, MD; Matthias Go¨ssi, PhD; Stefan Neuenschwander, PhD; Rene´ Preˆtre, MD;
Michele Genoni, MD; Gregor Zund, MD; Simon P. Hoerstrup, MD, PhD
Congenital heart valve defects is a problem that is currently only treated with surgery such as heart valve replacements, using mainly synthetic materials. Such treatment has many adverse effects such as lack of growth over the patient's lifetime, risks of thrombosis, and lifetime anticoagulation drugs needed to cope with the transplant. The authors of this paper developed a new tissue engineered heart valve using autologous cells obtained from a typical CVS (chorionic villus sampling) during preganancy.
In this study, the authors obtained the umbilical cord blood-derived EC progenitor cells from a CVS aspiration. The cells were isolated from the sampled tissue via digestion by collagenase and centrifugation/pelleting. These isolated EC progenitors were then cultured, and a separate batch were cryopreserved for later use. The scaffold for the heart valve leaflets were made from PGA (polyglycolic acid) coated with poly-4-hydroxybutyric acid. The authors fabricated the scaffold into the proper shape of the heart valve leaflets, then seeded the cells (chorionic villi) onto the scaffolds and placed the device in a perfusion bioreactor.
Two conditions were then imposed: one with straining to provide cyclic mechanical stimulation, and one without. The device was then endothelialized (to prevent platelet adhesion) by seeding with differentiated EPCs previously obtained. Characterization of the device were assays of two main types: stainng for tissue composition and mechanical testing. H&E staining showed tissue organization of the tissue engineered device to be very similar to native neonatal valve leaflets. Other types of stains have shown the expected organization of collagen with collagen fibers on the periphery layer and GAG (glucosaminoglycans) in the center of the leaflets. The authors also took SEM images of the device before and after cell seeding to confirm the endothelialization of the leaflet and look at the surface morphology inside the engineered device.
Mechanical testing of the device on a tensile tester produced stress-strain curves that show the leaflets grown in the mechanically loaded bioreactor to be stiffer (higher Young's modulus), but not as pliable as the one's that were not strained. However, the authors only made some preliminary statements and did not offer any suggestions on how to balance strength and pliabilityas to find the most appropriate way to mechanically stimulate these leaflets to best match native tissue.
This research holds much promise it that it offers a cell source for future work on pediatric tissue engineering, especially cardiovascular tissue engineering. If developed, this methods offers a minimally invasive way to harvest progenitor cells that can be used in other applications. This paper also demonstrates many of the tissue engineering challenges discussed in lecture (staining, tissue characterization) as well as some of the techniques we've been exposed to in lab (cell culture, microscopy).
7 comments:
I imagine it would take a long while to harvest, culture, and actually formulate a working engineered heart valve. How does the surgeon know to take a preemptive procedure to create the valve in a timely manner? In other words, are there symptoms the doctor can observe in the womb that indicate the need for the procedure?
That's a great question. I suppose that will be one of the major drawbacks of this procedure, since the cells can only be harvested prenatally. One possibility is to detect for possible congenital heart defects (via Ultrasound, perhaps) and then to harvest the cells needed.
I’m very interested in the materials that were used in the experiment. PGA is quite the standard when it comes to tissue engineering scaffolds. However, I want to know why poly-4-hydroxybutyric acid was used as a coating. Did the authors provide any motivation as to why they chose that type of coating? I’m guessing that it has something to do with cell adhesion or cell proliferation onto the scaffold. Was there something in particular that was needed by the material to make the device a success?
I wonder what kind of mechanical loading was used for strained heart valve growth, and whether they decided to mimic the heart by using cyclic pulsatile flow. Further research into finding what kind of loading mechanism would produce the appropriate stiffness would be very interesting.
Great question, Emmanuel. The authors never explained why they coated the PLA with poly-4-hydroxybutyric acid. From the literature, it seems like poly-4-hydroxybutyric acid is a fast absorbing polymer that has been used in other pulmonary artery tissue engineered scaffolds. Maybe that's why it was chosen.
The author did in fact use cyclical tensile stretching, but they only discussed this in their conclusion. (They only showed data for the constant strain rate tests). Maybe they're saving it for another paper.
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